pulse crops and sustainability: a framework to evaluate ... introduction of pulses into crop ......
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CELEBRATETHEINTERNATIONALYEAROFPULSES2016|WWW.IYP2016.org|#LovePulses
OFFICIALUNSITE|HTTP://WWW.FAO.ORG/pulses-2016/
Pulse crops and sustainability: A framework to evaluate multiple benefitsPrepared by Gabrielle Kissinger, Lexeme Consulting 7 April 2016
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Table of Contents
EXECUTIVE SUMMARY ..................................................................................................... 3
1. INTRODUCTION ......................................................................................................... 11 1.1 PURPOSE ................................................................................................................. 11 1.2 PULSE PRODUCTION AND SUSTAINABILITY .................................................................. 12
2. METHODOLOGY ........................................................................................................ 22
3. CASE STUDIES ............................................................................................................ 22 3.1 SASKATCHEWAN ...................................................................................................... 22
3.1.1 Context ........................................................................................................... 23 3.1.2 Environmental ................................................................................................. 24 3.1.3 Social .............................................................................................................. 28 3.1.4 Economic ........................................................................................................ 29
3.2 SUB-SAHARAN AFRICA .............................................................................................. 33 3.2.1 Context ........................................................................................................... 33 3.2.2 Environmental ................................................................................................. 33 3.2.3 Social .............................................................................................................. 35 3.2.4 Economic ........................................................................................................ 39
4. A FRAMEWORK: EVALUATING MULTIPLE BENEFITS OF PULSE PRODUCTION ..... 45
5. APPLYING THE FRAMEWORK FOR DECISION SUPPORT ......................................... 53
6. REFERENCES .............................................................................................................. 60 ListofBoxes,FiguresandTablesBox1:EconomicchallengesforpulsesinIndiaBox2:Summaryofsystem1-LifeCycleandSocio-EconomicAnalysisofPulseCropProduction
andPulseGrainUseinWesternCanadaBox3:Summaryofsystem2-LifeCycleandSocio-EconomicAnalysisofPulseCropProduction
andPulseGrainUseinWesternCanadaFigure1:SummaryofpulsecropsustainabilityframeworkandapplicationstepsFigure2:HectaresseededwithpulsesbyvarietyinCanada(1981to2011)Figure3:ProjectedglobalfooddemandFigure4:AttributesofpulsecropsustainabilityatvariousscalesTable1:Economicreturnsoflentilsinrotations,basedondifferentsoilsinSaskatchewanTable2:Summaryofcriteriaandguidingquestionstoevaluatetheeconomic,socialand
environmentalbenefitsofpulseproductionTable3:ApplicationoftheframeworktofoodsectoractorsTable4:ApplicationoftheframeworktoproducersTable5:Applicationoftheframeworktogovernments
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AcknowledgementsSpecialappreciationgoestoDenisTremorinandChristineNegrafortheiroversightofthisproject,andthesupportoftheGlobalPulseConfederation,EmergingAg,PulseCanada,andtheInternationalYearofPulses’ProductivityandSustainabilityThematicCommittee.Thisreportgreatlybenefittedfromtheinsightsand/orpeerreviewprovidedbySteveBeebe,JeffreyEhlers,NoelEllis,JillFindeis,AllisonFletcher,ReynaldLemke,LisetteMascarenhas,MarkOlson,JohnMcDermott,RajeevVarshney,TomWarkentin,andIrvWidders.
Executive Summary Thepotentialofpulses—beans,peas,chickpeas,lentils,andotherpulses—tohelpaddressfutureglobalfoodsecurity,nutritionandenvironmentalsustainabilityneedshasbeenacknowledgedthroughtheUNdeclarationofthe2016InternationalYearofPulses.However,thefullsetofbenefitsthatpulsecropscanofferhasnotbeensystematicallycharacterized.Thispaperspecificallyseekstodevelopaframeworktoevaluatetheeconomic,socialandenvironmentalbenefitsandpotentialtrade-offsofpulseproductionindifferentgeographic,agro-ecologicalandeconomiccontexts.Theframeworkdefinesthesustainabilityelementstobeevaluatedinanygivencontext,giventhediversityacrosscroppingsystemsandgeographiccontextsofsuitablepulsegrowingareas.Theframeworkwillalsoprovideameanstoevaluatethepotentialsustainabilitycontributionsofpulsesshouldtheybebroughtintoacroppingsystem,orintegratedintocroprotations.Theprimaryaudienceforthiswhitepaperisthefoodindustry,butgovernmentpolicymakers,researchersandotherstakeholderswillfindutilityinitaswell.Themethodologyfordevelopingtheframeworkwastoderiveinsightsfromageneralgloballiteraturereviewandtwogeographiccasestudies—diversecontextsofproductioninSub-SaharanAfricaandSaskatchewan,Canada.Keyinsightsandfindingsfromtheliteratureandcasestudiesacrossthethreepillarsofsustainability—environmental,socialandeconomic—aresummarizedbelow.Pleaserefertothefullreportforcitationsandreferences.Environmental: Nitrogenfixation:Pulsecropshaveauniqueroletoplayintheglobalnitrogencycle,aslegumesandpulsefixatmosphericnitrogeninsoils.Theintroductionofpulsesintocroprotationsactivelyhelpsfixnitrogeninthesoil,thusreducingfertilizerrequirementsofthepulsecropitself,aswellasthefollowingcrop.Thenitrogenremaininginthesoilalsoincreasesthegrainyieldinsubsequentcrops.Howtomaximizetheenvironmental
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benefitsofpulsesaddedintocroprotationsisanever-evolvingscience,basedonmanyfactorsbestobservedatthecroppingsystemlevel.
• InSub-SaharanAfrica,alteringthetraditionalplantingmethodsofmaizeandbeanarefoundtoinfluencethenitrogenbalanceincroppingsystems.ResearchinCentralKenyaidentifiedthenitrogenbenefitsofcowpeaintercroppingwithmaizeandgroundnut.OtherresearchinthedrysavannahsofNigeriaandNigerfoundmodifiedstrip-croppingofcowpeaandsorghum,withtheadditionoflivestocktoboostmanurenutrients,preventedthenutrientlossescausedbytraditionalfarmingpractices.
• LifecycleassessmentfindingsinSaskatchewan,Canadaindicatethattheenvironmentalbenefitsofpulsecropsisstrong,primarilyduetotheirnitrogenfixationabilities,thereductioninnitrogenrequirementsofacerealcropsucceedingapulsecrop,andtheincreaseinquantityandnutritivequality(proteincontent)ofacerealcropfollowingapulsecrop.Theassessmentfoundthatevenwhenconsideringthepracticeofapplyingmoderateamountsofpesticidestothecrops,thisdidnotgeneratesufficientdifferencesinenvironmentaleffectstodiscounttheoverallpositiveenvironmentalresults.Relatedbenefitsofthereducedsyntheticnitrogenfertilizersrequirementsincroppingsystems,whenpulsesareaddedinrotations,includethereducedemissionsandenergyuseassociatedwiththeproduction,useanddisposaloffertilizers.
Conservationtillage:Changesintillagepracticeshavehadasignificanteffectonshiftingconventionalcereal-basedcroppingsystemstomorediversifiedcroprotationsthatutilizepulsesoroilseedsandthatresultinlesssoildisturbance.Whileincreaseduseofherbicideshasbeenutilizedtoaddressweedabundanceunderreducedorno-tillage,thisappearstobemoderatedafteraperiodoftransitiontoconservationtillage.
• Saskatchewan:Long-standingpatternsofmonoculturecerealcroppingresultedinpestanddiseaseoutbreaksanderosion,andfallowingledtoincreasedsoilsalinityandlossofsoilnitrogenandwater.Theconventionaltillagepracticesincerealmonocultureresultedinincreasedsoilerosion,despitethebenefitofincorporatingcropresiduesintothesoil.Thesefactorsspurredfarmerstoseekalternativecropstoincludeinrotations,usuallyreplacingsummerfallow.Thegreatestenvironmentalbenefitofaddingpulsecropsintocereal-fallowrotationswastheirnitrogenfixationcapability,whichreducedfertilizernitrogenrequirementsinthecurrentandsucceedingcrop,andimprovedthecapacityofthesoiltosupplynitrogen.
• Changesintillagerequiresadjustment,andfarmersinSaskatchewanimprovedtheirherbicideandmanagementpracticesovertime,leadingtoreducedratesinuse,andasignificantreductioninrepeatapplications.Erosionhasbeenfoundtoincreaseduringproductionoffieldpea,lentil,andchickpeaintheseareas,as
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theyoftenproducelesscropresiduethancerealcrops,andthecropresidueismoreeasilydisintegratedbytillagethancerealresidue.Therefore,farmersareadvisedtominimizepulsecroppingonhighlyerodiblesoilsandminimizeoreliminatetillage,particularlyinthefall.
• FewconservationtillageassessmentsareavailableforSub-SaharanAfrica.
Productivityimprovementsoverareaexpansion:Addingmorecrops,suchaspulses,intorotationscanincreasetheefficiencyofaproductionsystem,reducingtheneedtoexpandtheproductionareatoachieveoverallyieldincrease.
• FindingwaystoboostproductivityinSub-SaharanAfrica,inordertomeetexpectedfoodandfeeddemandwillbecrucial.Demandforpulses(mostlybeansandcowpeas)inSub-SaharanAfricaisexpectedtoincrease155%from2015to2050.Yet,mostSub-Saharanpulseproductionoccursinrainfedareas,withlowuseofinputsandrelativelylowyields.Ghana’sexampleofincreasingtheproductionandyieldsofcowpeaatagreaterproportionthanhectaresplanted,indicatesefficiencyinproduction.Thesetrendsareattributedtotheimprovementsinthesupply,distributionanduptakeofimprovedvarietiesandbetterqualityseed,moredemandbyurbanconsumersandbettermarkets,andboththeprofitabilityandexistenceofincentivesforfarmerstoadoptproductivityenhancingoptions.
• Thoughpulseproductionareahasincreased23%since2013inSaskatchewanandWesternCanada,theoverallharvestareahasslightlydecreasedoverthesameperiod.
• Integrationoflegumesintolivestockproductionsystemscanbehighlybeneficial,withincreasednitrogensupplyandincreasedmeatproduction.
Climatechangemitigationandadaptation:PulsesincroprotationscanhelplowerGHGemissionsduetolowerfertilizerrequirements,particularlygiventhelargeamountofenergyusedinfertilizerproduction.
• Upto70%ofthenon-renewableenergyusedinWesternCanadiancroppingsystemsisduetotheuseoffertilizers,particularlynitrogen.AddingpulsesintorotationscommonlylowersGHGemissions.ResearchinSwiftCurrent,SKassessingnetGHGemissionsfromfourcroppingsystems(fallow-flax-wheat,fallow-wheat-wheat,continuouswheat,andlentil-wheat),foundthelentil-wheatsystemtoclearlyoutperformtheothers.Thiswasduetothelowerratesofnitrogenfertilizerrequiredbythewheatcropinthislentil-wheatrotationandtheincreasednitrogenavailability,whichenhancedplantbiomassaccumulation.Resultsindicatedthatspringwheatgrownusingimprovedpracticesof(a)fertilizingcropsbasedonsoiltests,(b)reducingsummer-fallowfrequenciesand(c)rotatingcerealswithlentilcanattainanetGHGbalanceregardlessofwateravailability.
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• InSub-SaharanAfrica,climateadaptationismoreurgentthatmitigationmeasures.InmostoftheSub-Saharancountriesreviewed,projecteddeclinesinbeanproductionaresignificant,duetoexpectedchangesinrainfallpatternsandtemperature.TheIPCCestimatesthatcropfailureduetodroughtandwaterriskwillbethehighestinAfricaduetoclimatechangeimpacts.Thisindicatesthevulnerabilityofagricultureinthesecontexts,andneedforimprovedmanagementpractices,betteradaptabilityandstrengthofseedsystems,andtechnicalandinformationsupporttofarmersforimprovedpractices.
Social: Nutritionanddisease:Whilepercapitafoodconsumptionwillleveloffindevelopedcountries,significantincreasesindevelopingcountries,basedlargelyonincreasesinproteinintake,areexpectedto2024.Fairlyrecentchangesintheglobalhumandietfavouringmoreenergy-densefoodsrichintotalandsaturatedfatsareincreasingtheratesofobesity,diet-relateddiseasessuchasdiabetes,coronaryheartdiseaseandcancer.Helpingtobalancethattrend,pulsesandlegumesareanimportantcontributorofmicronutrient-richintake,alongwithfruitsandvegetables,ifconsumersmakehealthychoices.Pulseshavearoletoplayincombatingcardiovasculardisease,increasingguthealthandhealthynutrition.
• TheCanadianDiabetesAssociationClinicalPracticeGuidelinesrecommendthatalow-fatvegandiet(whichwouldincludepulsesandlegumes)improvesglycemiaandplasmalipidsmorethanconventionaldiets.Theroleofpulsesandlegumesindietarypatternsofpeoplewithdiabetescanbeimportanttoregulatebloodsugarlevelsandmoderatesymptoms,andisalsoimportantinthepreventionofcardiovasculardisease.
• InRwanda,whichhasthehighestpercapitalconsumptionofcommonbeansintheworld,large-scalehouseholdsurveyscarriedoutin2011indicatedthatalmost90%offarmhouseholdscultivatebeansaspartoftheircroppingsystem,andyet77%reportednotgrowingenoughbeansfortheirneeds.Otherhouseholdsurveyresearchindicatesthat,astheshareofimprovedbeanseedsplantedincreased,householddietarydiversityscoresincreased,showingaclearrelationshipbetweennutritionandimprovedseedvarietyadoption.InKenya,Ghana,EasternDRC,NigeriaandTanzania,between32–80%ofcowpeaand/orcommonbeancropsgoestowardsubsistenceproductionandconsumption,highlightingtheirimportanceforfoodsecurityandnutrition.
Nutritionandfoodsecurity:Grainlegumesaddedintothedietarefoundtocontributeimportantenergy,proteins,minerals,andBvitamins.Whenconsumedwithcereals,pulsescontributeproteins,mineralsandBvitamins,aswellastheessentialaminoacidlysine,whichincreasesthequalityofprotein.Whenaddedtorootandfruitstaples,theyraisetheproteincontent.Nitrogen-richandprotein-richplantfoodsarenecessaryto
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supplydietaryprotein.Neweffortsareinvestigatingtheincreasedproductionanduseofpulseproteinfractionsinmanufacturedfoodproducts.
• InRwanda,adoptionofimprovedpulsecropvarietiesappeartohaveagreaterimpactonfoodsecuritythanonbeanfarmincome.Adoptionofimprovedbeanvarietiesinfluencesfoodconsumptioninotherwaysthanjustthroughfarmprofitability.ToaddressnutritionaldeficienciesinRwandathathaveresultedinoneofthehighestratesofchildstuntingintheworld,qualityseedof‘highiron’(‘bio-fortified’)beanvarietiesisbeingdeveloped.
• Thehealthaspectsofincludingpulsesindietsisanimportantcontributorofthesocialbenefitsofpulses,asamicronutrient-richfoodsource,helpsreduceinflammationinthegut,andhasbeneficialeffectonserumcholesterollevels,thusreducingcardiovasculardiseaserisk.NorthAmericanandCanadianconsumptionofpulsesappearstobefarbelowtheoptimallevel.
Gender:Genderaspectofpulseproductionrelatesprimarilytowomen’sinvolvementinpulseproductioncommercially,tofeedfamilies,andtobenefitfromincomederivedfrompulsesales.
• AcrossAfricancountriesforwhichgenderresearchrelatedtopulseproductionexists,pulsecultivationbywomenoccursatvariousandmultiplestagesinthesupplychain.However,genderequityforwomenismoreapparentwhenwomencanmakedecisionsonquantitiessoldandthoseretainedforhouseholdconsumption.Genderdifferencesinaccesstoland,technologiesandotherstrategicresourcesplayalargerole.
Anecdotalevidencefrominterviewsconductedinthisresearchsuggeststhereareintertwinedsocialandeconomicbenefitsofaddingpulsestocroprotations,asmanySaskatchewanfarmersusingrotationsconsistingofcereal-falloworcereal-canolawouldhavegonebankruptwithoutdiversifyingintolentilsandotherpulsecrops.Thus,theadditionofpulseshelpedkeepfarmingcommunitiesintactandproductive.Economic: Reducedrelianceonfossilfuelsandlowerfuelcosts:Whereconservationtillagepracticeshavebeenadopted,pulsesandoilseedshavecommonlybeenintegratedintocroprotations.Reducedandalteredtillagepractices(commonlyincludingpulseandoilseedcrops)reducerelianceonfossilfuelsandloweroverallfuelbills.Farmersarelikelytoseethelong-termeconomicbenefits(andavoidedcosts)oflesssoil,airandwaterdegradationbyadoptingno-tillpracticesandincludinglegumesintheiroperations.
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• InSaskatchewan,whencomparedtoconventionaltillage,conservationtillageorno-tillagepracticesresultinconsistentyieldadvantages,lessincomevariabilityandsignificantresourcesavings.
Economicbenefitsofaddingpulsestocroprotations:Significantresearchanddevelopmenthasgoneintoimprovedpulseseedvarieties.Lessemphasishasbeenplacedonthetechnicalandfinancialsupporttohelpfarmersnavigatechangesinpracticesandtrade-offsassociatedwithaddingpulsecropsintorotations(ordifferentintercroppingmethodsinSub-SaharanAfrica).Furthermore,thoughinvestmentsinpulsecropbreedinghavebeenmadeinindifferentregions,theextentofinvestmentisstillrelativelysmallwhencomparedtothescaleofinvestmentsincorn,soybeanandwheat.Investmentinimprovedvarietieswillbekeytoimprovementsintheglobalpulseindustry.
• FindingsfromSub-SaharanAfricaindicatethateconomicimpactsofincludingpulsesinrotationsareinfluencedbyavarietyoffactors,particularlyfarmerperceptionandknowledge.Farmersaremorelikelytoadoptpulsesintheircroppingsystemswhentheyfindacroprotationsequencethatproduceshigherreturnoninvestmentoverthelongterm.Lowsalespricesofbeanscontributetolowadoptionratesofimprovedbeanvarieties,butotherresearchindicatesacomplexsetoffactors,includinglackofsupplysystemsandlackofmarketcoordination,limitedpost-harveststoragefacilities,highopportunitycostofland,competitionfromcropsthataremoreprofitable,andlimitedtechnicalandfinancialcapacityoffarmerstoorganizecooperatives.FindingsfromTanzaniaindicatethataccesstofinanceandcreditwasnotalimitingfactorinadoptingdisease-resistantpigeonpeaseed.Rather,informalseednetworks,on-farmvarietyselection,farmsizeandownershipofhouseholdtransportassetsplayedalargerroleinfarmersadoptingimprovedseed.
• InSaskatchewan,theeconomicbenefitsofaddinglentilandpeaintocroprotationshasbeensignificant,whilechickpeahasbeenlesssuccessfulthusfarduetodisease(ascochytablight),relativelylonggrowingseasonrequirement,andfluctuatingexportprices.Findingsindicatethatincludingoilseedandpulsecropsinrotationswithcerealgrainscontributedtohigherandmorestablenetfarmincomebetween1985-2002,inspiteofhigherinputcosts,acrossmostsoilzones.Whilethevolumeoflentilexportshasincreased67%between2009and2014,thevalueofthoseexportsincreased37%.Peaexportsshowadifferenttrendoverthesameperiod,withthevolumeofpeaexportsincreasing19%,whilethevalueoverthesametimeperiodincreased56%.Cropdiversityisahedgeagainstficklemarketsandchangesinprice.Farmersurveydatafrom2011indicatesthatpulseproducingfarmsgrowalargervarietyofcropsthanfarmsnotgrowingpulses(uptosevenormorefieldcroptypes).Estimatesfromthe2015SaskatchewanCropPlannerindicatethatlentilsmakeanimportantrelative
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contributiontothefinancialreturnsofrotationsindifferentsoiltypes;returnsfromlentilarebetween38%and60%dependingonsoilzone.
Investmentsinpulsecropresearch:Investmentsinpulsecropresearchhaveledtoimportantenvironmental,socialandeconomicimpactsinbothcasestudies:
• TheSaskatchewanPulseGrowersassociationinstitutesamandatory,non‑refundable1%levytofundprogramsthatdevelopthepulseindustry,providesresearchandcapacityforgeneticimprovement,agronomy,healthandnutrition,andprocessingandutilization.In2014/2015,thelevycontributed97%oftheCD$10.1milliontheorganizationinvestedinresearchanddevelopment,andanotherCD$2.8millioninmarketpromotion,mostofwhichwasfocusedondomesticlentilmarkets.
• For2012,theCGIARResearchProgramonGrainLegumesestimatesthatthenetpresentvalueofgrossbenefitsofitslegumeresearchandextensionwasUS$4.5billion,equivalenttoUS$535millionperyear,withsignificantfoodsecuritybenefitsandenvironmentalbenefitsthroughbiologicalnitrogenfixation(afertilizercostsavingofUS$418million).FiftypercentoftheeconomicimpactsaccrueinSouthandSouth-EastAsiaandSub-SaharanAfrica.
Exportversusdomesticmarkets:Trade-offsbetweensupplyingdomesticdemandandservingexportmarkets,orimportingpulses,hingeonavarietyoffactors,includingfoodsecurity,marketprices,post-harveststorageandprocessing,tariffsandimport/exportbarriers,marketefficiency,domesticfoodsecurity,andeffectivesectorpolicies.Forexample,Indiaaccountsfor26%ofglobalpulseproduction,yettheaverageproductivityofpulsesisbelowtheglobalaverage,andIndianproductionwillnotkeeppacewithdomesticdemand.GovernmentsubsidiesandpricecontrolsinIndia’sagriculturalsectorcreateddistortionsthataffecteddomesticproduction,andminimumsupportpricesforpulseshavenotdemonstratedthesameresultsasthoseforrice.Othercountrieshavehadsuccesspromotingexportcropsthatdonotcompetewithdomesticfoodproduction.Whitepeabeans(Navybeans)inEthiopiaandFrenchbeansinRwandaareexamplesofexportproductsthatdonotgenerallyreducedomesticconsumption,whichisascrucialforfoodsecurityasitisforrealizingeconomicbenefits.Addingpulsesintolivestockdietsalsohaseconomicbenefit,butappearsdependentonmarketpricingandlabouruseefficiencies.Pulse crop sustainability framework and application steps Groundedintheliteraturereviewandthetwocasestudies,thisreportproposesaframeworkforevaluatingthesustainabilityofpulsecropproductioninspecificcontexts.Applicationofthisframeworkissupportedbycriteriaandguidingquestions.
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Figure1providesadiagrammaticoverviewoftheframeworkelements.Section4ofthisreportidentifiesthecriteriaandattributes,foreachofthethreesustainabilitypillars,tobemeasuredorevaluatedinanygivenproductionsystem,recognizingthehighlydiversegeographic,agro-ecologicalandeconomiccontextsaroundtheworldthataresuitableforgrowingpulses.Thecriteriaandattributesoftheframeworkcanbeusedasacomplementtoaproductionstandardorproductcertificationschemethatgrowerscouldapplyattheproductionlevel.Eachcriterionorkeyelementcontainsasetofquestionstoguideevaluationofthesustainabilityofinterventions,includingcommonlyobservedtrade-offs.Section5ofthereportappliestheframeworktohypotheticalactionsthatcouldbetakebythefoodindustry,producers,andgovernmentstoincreasepulsecropproductionandconsumption.Thecriteriachosen,andquestionstopursueshouldbeadaptedtolocalcircumstancesortotheappropriatescale,andareintendedasastartingpoint,ratherthanacompletesetoffiltersfortestingthesustainabilityofcroppingchanges.Thesehypotheticalapplicationsprovideinitialguidanceonly,andpresentsomeoverarchingdecision-supportandquestionsforfurtherinvestigation(e.g.qualitativeandquantitativewaystotestperformanceusingkeyenvironmental,socialandeconomicindicators).Areal-worldapplicationoftheframeworkwouldrequireadaptationtotheuniqueproductioncircumstancesandinterventions.Figure 1: Summary of pulse crop sustainability framework and application steps
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1. Introduction Manyofthebenefitsofpulsesindiversifyingdietsandreplenishingsoilnutrientsarewelldocumentedandunderstood.Whathasreceivedlessattentionistheroleofpulsesincontributingtofuturefoodsecurityanddevelopmentgoals.Ourfoodsystemsfacethechallengeofneedingtoproduceenoughfoodtofeedatleast9billionpeopleby2050,withnearlyallthatadditionalfoodneededfordevelopingcountriesandduetopercapitaincreasesinmeatconsumption(FAO,2009;Foresight,2011).Butthatchallengemustbemetinthecontextofincreasingclimatechangeimpactsonfoodproduction;competitionforenergy,land,waterandmaterialresources;populationgrowthandmigration;povertyandfoodinsecurity;andecosystemdegradation.Climatechange,resourcedepletion,anddemographicshaveastrongimpactontheavailabilityandpriceofagriculturalcommodities(MSCI,2012).Growingurbanpopulationsareincreasinglypurchasingtheirfoodratherthangrowingit,withsubstantialproportionsofhouseholdexpendituregoingtowardsfood.InSouthAsiaandsub-SaharanAfrica,40–70%ofallhouseholdexpenditureisonfood(WorldBankandIMF,2013).Increasedurbanizationmeans96%ofthedevelopingworld’sadditional1.4billionpeopleby2030areexpectedtoliveinurbanareas.Further,theglobalmiddleclassispredictedtogrow172%between2010and2030,andwhileagribusinesseswillseektoservethisnewmiddleclassmarket,itwillbeatatimewhenresourcesarelikelytobescarcerandmoreprice-volatile(Kharas,2010).Thepotentialofpulses—beans,peas,chickpeas,lentils,andotherpulsecrops—tohelpaddressfutureglobalfoodsecurity,nutritionandenvironmentalsustainabilityneedshasbeenacknowledgedthroughtheUNdeclarationofthe2016InternationalYearofPulses.However,thefullsetofbenefitsthatpulsecropscanofferhasnotbeensystematicallycharacterized.Forbothlargeandsmallfarmers,pulsesrepresentimportanteconomicopportunitiestoboostincomeandreduceriskbydiversifingtheircropandincomestreamportfolio.Theenvironmentalbenefitsofaddingpulsestocroprotationsiswelldocumented,howeverthereislessdocumentationandevidenceofthesocialandeconomicbenefitsofpulseproduction.Pulsescouldhelpaddressfutureneedsforprotein,helpminimizesoildegradation,andsupportdiversificationinfoodproductionandconsumption.Thelivelihoodanddevelopmentimpactsofincreasedpulseproductionandconsumptionmustbebetterunderstoodbythefoodsector,bypulseproducers,andbygovernments,basedonempiricalevidenceandknownexamplesinbothdevelopedanddevelopingcountries.
1.1Purpose
Thispaperisproducedaspartofthe2016InternationalYearofPulses(IYP2016),whichbringanincreasingawarenessoftheroleofpulsesinfoodproductiontoarangeof
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stakeholders,includinggovernments,thefoodsector,farmersandproducers,researchorganizations,developmentagencies,investorsanddonors.ThisresearchispartofabroadereffortinIYP2016todeepenanunderstandingofthepotentialofpulsestocontributetosustainabilityandtomotivateactiontomaximizethesustainableproductionandconsumptionofpulses.Thispaperspecificallyseekstodevelopaframeworktoevaluatetheeconomic,socialandenvironmentalbenefitsofpulseproductionindifferentgeographic,agro-ecologicalandeconomiccontexts.Thus,theframeworkwilldefinetheelementsofsustainabilitytobemeasuredorevaluatedinanygivencontext,recognizingthehighlydiversegeographic,agro-ecologicalandeconomiccontextsaroundtheworldthataresuitableforgrowingpulses.Theframeworkwillalsoprovideameanstoevaluatethepotentialsustainabilitycontributionsofpulsesshouldtheybebroughtintoacroppingsystem,orasameanstooptimizecroprotations.Therationaleforproducingthiswhitepaperisto:
• Definetheelementsofpulsecropsustainabilitythatcanbeappliedindiversecontextsaroundtheworld(basedontheircontributiontocroppingsystemsatthelocalscaleaswellastheircontributiontoglobal-scalesustainabilitygoals).
• Helpbuildtheevidencebaseoftheenvironmental,socialandeconomicbenefitsofpulseproduction.
Theintendedprimaryaudienceforthiswhitepaperisthefoodindustry,andsecondaryaudienceisgovernmentpolicymakersandprivatefoundations.
1.2Pulseproductionandsustainability1.2.1EnvironmentalbenefitsNitrogenfixationNitrogenisthenutrientmostcommonlydeficientinsoilsaroundtheworld,andisthereforethemostcommonlyappliedplantnutrient,oftenintheformofsyntheticfertilizer.Legumecrops,includingpulses,haveauniqueroletoplayintheglobalnitrogencycle,astheyfixatmosphericnitrogeninsoils.Pulsescreateasymbioticassociationwithrhizobia,asoilbacteria,enablingpulsestofixatmosphericnitrogengas,whichcanmakethemself-sufficientinnitrogen,andenablethemtogrowinalmostanysoilwithoutfertilizerinputs.Humanimpactsontheglobalnitrogencyclefromrapidlyincreasingfertilizeruseandfossilfuelcombustionstartinginthe20thcenturyhavehadstrongnegativeeffects,suchaspollutionintowaterwaysandincreasedN2Oemissions.From1960to2000,nitrogenfertilizeruseincreasedbyroughly800%,withhalfofthatbeingutilizedforwheat,rice,andmaizeproduction(Canfieldetal,2010).Syntheticfertilizersprovidedclosetohalfofallthenutrientsreceivedbycropsgloballyduringthemid-1990s,demonstratingbothalargedependencyonsyntheticfertilizers,butalso
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inefficientmanagementofnitrogeninglobalagriculture(Smil,2002).TheIPCCestimatesthatnitrousoxideemissionscontainroughly300timestheglobalwarmingpotentialofcarbondioxide(CO2),andapplicationoffertilizerinagriculturalproductionisasignificantsourceofN2O.1Cerealcropssuchaswheat,riceandmaizetypicallyonlyutilize40%offertilizerapplied,leadingtosignificantwasteandenvironmentalimpactssuchaseutrophicationofcoastalwatersandcreationofhypoxiczones(Canfieldetal,2010).Asurveyofvariousfieldstudiesofnitrogenfertilizeruptakebyrice,cornandwheatshowstypicalnitrogenefficiencytobelessthan50%,withAsianriceaveragingaslittleas30%.Thestudyalsofoundnitrogenlossesalongthefoodchaintobesignificant,withsyntheticfertilizerscausingsignificantlymorenitrogenlossduetovolatilization,erosionandleachingintowater(Smil,2002).However,introductionofpulsesintocroprotationsactivelyhelpsfixnitrogeninthesoil,thusreducingthefertilizerrequirementsofthepulsecropitself,aswellasthefollowinggraincrop.Onelong-termstudy(2001–2013)onthenitrogenfixationofthepulsecropitselffoundfieldpea,lupinorfababeanderivedabout70%ofnitrogenrequirementsfromatmosphericnitrogen,whileanaverageof19kgofnitrogenwasfixedpertonneofpulseshootdrymatter.ThestudycoveredthegeographicrangeofsouthernandcentralNewSouthWales,MalleeandWimmerainVictoria,andthehigh-rainfallzoneofsouth-easternSouthAustralia(Peoplesetal,2015).Systematiccroprotationbasedonincorporatingpulses/legumesintomaize-basedsystemstoreducesyntheticfertilizeruse,andoptimizingthetimingandamountsoffertilizerappliedtocropsarerecognizedasthetwomostimportantinterventionstodecreasenitrogenapplication(Canfieldetal,2010).Biologicalnitrogenfixationisacrucialalternativesourceofnitrogen,andcanbeenhancedalongwithotherintegratednutrientmanagementstrategiessuchasanimalmanureandotherbiosolids,andrecyclingthenutrientscontainedincropresidues(Lal,2004).Thehigheravailablenitrogentosubsequentcerealcropsisgenerallyassumedtobenefityieldsofthosecerealcrops,howeverthisisnotaswelldocumentedasthenitrogenfixationbenefits.Findingsinsouth-easternAustraliaindicatestrongevidencethattheinclusionoflegumesincroppingsequencesresultsinhigheravailablesoilnitrogenforsubsequentcrops,withanadditional40to90kgN/hainthefirstyearand20to35kgN/haforthesecondyear,ascomparedtocontinuouscerealsequencesthatdonotincludepulses(Peoplesetal,2015).ApartfromtheeffectsofadditionalfixedNthatlegumecropsbringintosystems,therearealmostalwaysbeneficialyieldeffectsfromcroprotationswithlegumes.Thesepositiveeffectsonyieldareprobablyrelatedtodisruptionofthebuildupofdiseaseandpeststhatoccurswhenaparticularcropisgrownyearafteryear,althoughthisphenomenonisnotyetwellunderstood.IncreasesingrainyieldinsubsequentcerealcropshavebeendocumentedintheNorthernGreatPlainsofNorthAmerica,andwillbefurtherexploredintheSaskatchewancasestudyin
1Agricultureemissionsare19-29%ofallglobalGHGemissions.Nitrousoxideemissionsare39.3%oftotalagriculturalemissions(FAO,2015).
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section3.1.EvidenceinaMediterraneanenvironmentdemonstratedthatvetch,fababeanandchickpeaallresultedinsignificantyieldsurplusesandprovidednitrogencredittothesubsequentunfertilizedwheatcrop,thoughvetchoutperformedtheother(betterresearched)pulses(Dalias,2015).ExperiencesinAustraliashowincreasedyieldandproteincontentincerealandoilseedcropsthatareplantedfollowingpulsecrops.Thewidevariationsintheamountofnitrogenfixationthatpulsescanprovidedependsontheamountofbiomassproducedbythepulsecrop(oftenvaryingwithwater,soilqualityandnon-Nnutrientavailability),whethertheharvestremovesasignificantamountofthebiomass,andtheeffectivenessofthelegume-rhizobiumsymbiosisinfixingnitrogen.Plantingalegumeintosoilsalreadyhavingmoderatetohighlevelsofsoilnitrogencanalsodepressbiologicalnitrogenfixation.Nuancesanddifferencesinsuccessivecerealcropsmustbenoted.FindingsinAustraliacomparinglegumeandfertilizernitrogenindicatethatrecoveryoflegumenitrogenbyafollowingcerealcroptendstobelowerthantop-dressedfertilizer(adifferenceof20%betweenhighandlowranges),butisnottoodissimilarfromfertilizerappliedatsowing.Thisisduetoslowerreleaseofmineralnitrogenfromlegumeandpulsecropresiduesastheydecompose.However,lossesofnitrogenfromthesystemarefoundtobeusuallylowerfromlegumesourcesthanfromfertilizer,indicatingthecontributionoflegumestothemaintenanceofthelong-termorganicfertilityofsoils(Peoplesetal,2015).Thesuccessiveplantingofdifferentcropsonthesameplotofland,throughcroprotations,helpssoilfertility,thetransferofnutrientsfromonecroptothenext,andhelpstocontrolweeds,pestsanddiseases.Croprotationshavebeenpracticedbyfarmersforthousandsofyears,2yetmaximizingtheenvironmental,socialandeconomicbenefitsofcroprotationsisanever-evolvingsciencethatmustaddressmanyfactorsatthecroppingsystemlevel.Thereplenishmentofnitrogenthroughtheuseofgreenmanure,insequencewithcereals,isacommonformofcroprotation.TheSakatchewancasestudybelowexploresfurtherinsightsoncroprotation.Includingpulsesincroppingsystemshashighrelevanceforimprovingtheoveralluseefficiencyofavailablenitrogenatthefarmsystemlevelratherthanatjustthecroplevel.Ratherthanemphasizingindividualelementsofacroppingsystem,afocusonoverallgrowingconditions,thecropmix,andthesequenceofcroprotationsiscentraltoachievingbothsustainabilityandproductivityobjectives,suchasincreasingnitrogenfixationthroughimprovedrhizobia-hostplantsymbiosis(vanKesselandHartley,2000).ConservationtillageChangesintillagepracticeshavebeenanimportantpartofshiftsfromconventionalcroppingsystems,basedongrainproduction,tomorediversifiedcroprotationsutilizingpulsesoroilseeds.Conventionalplow-basedfarmingdevelopedlargelyasameansfor
2ThecentresoforiginofagricultureinSouthandEastAsia,theMiddleEast,Sub-SaharanAfrica,andMiddleandSouthAmericaallincludedthedomesticationofalegume.
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farmerstocontrolweedsinfield-cropsystems.Conventionaltillagepracticesleavesoilvulnerabletowaterandwinderosion,increasesagriculturalrunoff,degradessoilproductivityandreleasesGHGemissionsbothfromsoildisturbanceandfossilfueluse.ConventionaltillageintheUS,CanadaandAustralialedto“dustbowl”stormsduetowinderosion,andthelossofsoilandfarmlandspurredpolicymakersandfarmerstofindsolutions.No-till,ordirectseedingunderamulchlayerfromthepreviouscrop,isthemostimportanttechnologyinconservationagricultureandreversesthisprocessbyimplementingapackageofpractices,includinga)minimummechanicalsoildisturbance,b)permanentorganicsoilcover,c)diversificationofcropspeciesgrowninsequencesand/orassociations(FAO,2013).Importantly,implementingconservationtillagepracticeshasofteninvolvedintroductionofpulsesandoilseedsintograin-basedcroprotations3.Whileincreaseduseofherbicides,suchasglyphosate,havebeenutilizedtoaddressweedabundanceunderreducedorno-tillage,thisappearstobemoderatedafteraperiodoftransitiontoconservationtillage.VanKesselandHartley(2000)identifiedarangeofstudiesthatdemonstratethenitrogenfixationbenefitsofconservation-orno-tillage,withpulseandoilseedbeannodulationimprovingaftermultipleyearsofno-tillandnitrogenfixationratesincreasing(moderatedbychangesinrainfallpatterns)(VanKesselandHartley,2000).Formoreinsightonhowno-tillandconservationagriculturehasbeenadoptedinSaskatchewan,refertoSection3.ProductivityimprovementsoverareaexpansionAnimportantgoalinthesustainableuseoflandworldwideistoincreaseproductivityonavailablecroplands,whilerestrictingagriculturalexpansion,whichoftenoccursattheexpenseofforestsandwetlands.Ninebillionpeoplewillinhabittheplanetby2050.Toavoidcropexpansionandjustmeetprojected2050cropneedsbyincreasingproduction,itispredictedthatcropyieldswouldneedtoincreasebyanestimated32%morefrom2006to2050thantheydidfrom1962to2006duringtheheightofthe‘greenrevolution(Searchingeretal,2013).’However,reachingsuchincreasesinyieldsishighlyunlikely.Pulseshaveasignificantroletoplayin‘sustainableintensification,’yet,indevelopingcountries,productionincreaseshavecomeprimarilyfromexpansionofcroppingareas.Theyieldgrowthofpulsesbetween1980and2004indevelopedcountrieswas2%perannum,whileindevelopingcountries,itlanguishedatabout0.4%perannum(Nedumaranetal,2015).Ethiopia’sriseinchickpeaproductionoffersanexampleofproductivityimprovementsthatdidnotresultinareaexpansion(Ethiopia,2015b).Thislargeyieldgapbetweendevelopingcountriesanddevelopedcountriesisofconcern,andcannotbeaddressedbyimprovedpulsecropgeneticsalone,butratherrequiresarangeofinterventions,someofwhicharefurtherexploredintheAfricacase
3TheoilseedssoybeanandgroundnutarealsoN-fixinglegumes.Notethatsomeofthebrassicaceaelackrootsymbiosesandsowillhaveaverydifferentconsequencefromlegumesmostofwhichhavebothbacterialandfungalrootsymbionts.
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studyinSection3.2.Addingmorecropsintorotationscanincreasetheefficiencyinaproductionsystem,minimizingthepressureforcroplandexpansiontoachieveyieldimprovements.However,inmanycontexts,regulationstorestrictexpansion,orencourageexpansionondegradedlands,arenecessarytosendtherightsignalstoproducers.ReducedgreenhousegasemissionsTheroleofpulsecropsinmitigatinggreenhousegasemissionsinagricultureproductioncanbesignificant,andthisisexploredfurtherintheSaskatchewancasestudybelow.TheprimaryreasonforthebenefitsfrompulsesinloweringGHGemissionsisduetolowerfertilizerrequirements,particularlygiventhelargeamountofenergyusedinfertilizerproduction.Upto70%ofthenon-renewableenergyusedinWesternCanadiancroppingsystemsisduetotheuseoffertilizers,particularlynitrogen,andtheinclusionofpulsesincroppingsystemsreducestheneedforfertilizerinputs.Pulsessupplytheirownnitrogenandcontributenitrogentosucceedingcrops(Lemkeetal,2007).ThisisexploredingreaterdetailinSection3.1.PulsesandlivestockfeeddiversificationIntegrationoflegumesintolivestockproductionsystemshasbeenshowntodelivermultiplebenefits,suchasincreasednitrogensupplywhilealsoincreasingmeatproduction.Globally,meatdemandisexpectedtoincreaseby200milliontonnesperannumby2050,withcorrespondingdemandforlivestockfeed(AlexandratosandBruinsma,2013).InthenorthernGreatPlainsoftheUSandCanada,fieldpeahasbeenpromotedasameanstoboostproteinandenergyincattlefeed.Fieldpeagrainhasbeenfoundtobehighlydigestibletocattle,butthestarchfermentationandruminalproteindegradationratesareslowerthanforothercommonfeeds.Fieldpeahasbeenshowntoincreasedrymatterintakebycowswhenincludedinthelivestockfeedration,andalsoproducesbenefitswhenusedasabindingagentforpelletingformulafeeds(Anderson,etal,2007).1.2.2SocialbenefitsNutritionWithoutaconcertedefforttoboosttheproductionofpulsesindevelopingcountries,consumptionofpulsesmaystagnateordecline,duetochangingconsumerpreferences,failuretopromoteproductionofpulses,andagreaterfocusonincreasingproductionandself-sufficiencyincereals(AlexandratosandBruinsma,2012).Historically,whenobserveddeclinesinprotein-richpulseswerenotaccompaniedbyincreasesintheconsumptionoflivestockproducts,theresulthasbeendeteriorationintheoverallqualityofdiets,evenifpercapitadietaryenergyincreased(ibid).
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Pulseshavedeclinedinconsumptionlevelsgloballyandinparticularamongdevelopingcountries,perhapsbestillustratedbyChina’ssignificantdecreaseinconsumption,from30gpercapitaperdayin1963,toonly3gpercapitaby2003(Kearney,2010).Overthelastdecade,developingcountries,particularlyinlargeAsianeconomies,haveseensteadypopulationgrowth,risingpercapitaincomesandcontinuousurbanization,whichhasbeenaccompaniedbyincreasedproteinintakerelativetothetraditionalstarches.TheOECD/FAOAgriculturalOutlookto2024indicatesstagnantgrowthinfoodconsumptionindevelopedcountries,butsignificantincreasesindevelopingcountries,reflectingthisincreaseinproteinintakeindevelopingcountries.Atthegloballevel,totalcaloricintakeisexpectedtorise,butwithregionaldifferences.Cerealswillremainthemostconsumedagriculturalproduct,withconsumptionexpectedtoincreasebyalmost390Mtby2024,mostofwhichiscoarsegrains.Thelargestexpectedgrowthincoarsegainconsumptionwillcomefromdemandforfeed,accountingfor70%ofthegrowthinconsumption.Globalmeatconsumptionisexpectedtogrow1.4%peryear,resultinginadditionalconsumptionof51Mtofmeatby2024(OECD-FAO,2015).IndiaprovidesacounterpointtoChina,aspulsesthereprovideanincreasingsourceofprotein,nowaccountingforalmost13%ofoverallproteinintake(OECD-FAO,2014).Pulsesareanimportantcontributiontoavegetariandiet,giventheirproteincontent.Indiaisthelargestpulseproducerandconsumer,andthecountrygrowsthelargestvarietiesofpulsesintheworld,accountingforabout32%oftheareaand26%ofworldproduction.Indianpulsecropsincludechickpea,pigeonpea,urdbean,mungbean,lentilandfieldpea,andproductionreachedarecordlevelof18.4Mtin2012-13,upfrom15Mtin2007-08.Pulsecropyieldshaveincreasedfrom0.63t/hain2007-08to0.79t/hain2012-13,andannualyieldgrowthisexpectedtooutpacegrowthinproductionarea,indicatingbetterproductionefficiency.However,theaverageproductivityofpulsesinIndiastillremainsbelowtheglobalaverage.ItisexpectedthatIndianproductionwillnotkeeppacewithdemandandimportsareanticipatedtogrowto5.1Mtby2023(OECD-FAO,2014).Fairlyrecentchangesintheglobalhumandietfavouringmoreenergy-densefoodsrichintotalandsaturatedfatsareincreasingratesofobesity,diet-relateddiseasessuchasdiabetes,coronaryheartdiseaseandcancer.Publichealthandnutritioneffortsseekingtopromotehealthierandmoresustainablefoodproductionandconsumption,mustensureasufficientsupplyofstaplesandofmicronutrient-richfoodswithoutencouragingexcessiveconsumptionofenergy-dense,nutrient-poorfoods.Pulsesandlegumesareanimportantcontributorofmicronutrient-richintake,alongwithfruitsandvegetables(Kearney,2010).Eighty-fourpercentoftheproteinincommonbeanisreadilyabsorbedafterconsumption,and94%oftheproteinfromcowpeaisavailable.Pulseshavearoletoplayincombatingcardiovasculardiseaseandincreasinghealthynutrition.Worldwide,cardiovasculardiseasesarenowtheleadingcauseofdeath,andintheUnitedStates,isattributedto1/3ofalldeaths.Whilethereisincreasingawarenessofthisrisk,andtheroleofbalanceddietstodecreasetherisk,lessthan1/3
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ofAmericansconsumesthe3cupsoflegumesrecommendedperweekbytheDietaryGuidelinesforAmericans(Bazzanoetal,2011).Ameta-analysisoftenrandomizedcontrolledtrialsfrom5countriessoughttoquantifytheimpactthatconsumptionofnon-soylegumes(navy,pinto,kidney,garbanzoandlimabeansandpeassuchassplitgreenpeasorlentils)hasontotalcholesterol,high-densitylipoprotein(HDL),low-densitylipoprotein(LDL),verylow-densitylipoprotein(VLDL),andtriglycerides.Findingsindicatethenon-soylegumediethadasignificantbeneficialeffectonserumcholesterollevels,thusreducingcardiovasculardiseaserisk.BothtotalandLDLcholesteroldecreased,whileHDLcholesteroldidnotchangesignificantly,whennon-soylegumesweresupplemented.Further,findingsindicatethatthenon-soylegumedietallowedforhigherintakesofdietarytotalandsolublefiber(whichlowersriskofcoronaryheartdisease)andcontainedphytosterols,acomponentofplantcellmembranes,whichreducesbloodcholesterollevels(ibid).Theanti-inflammatoryeffectsofbeansandtheircontributiontotheintestinalmicrobiomeinthegutisincreasinglybeingunderstood,particularlyinamongchildreninMalawiwherefindingsindicatecowpeaandcommonbeancanreduceenvironmentalentericdysfunction(Manary,2015).NitrogenandproteininglobaldietsMoredietaryproteinwillbeneededtoeliminatedisparitiesindietsbetweendevelopedanddevelopingeconomies.However,thenitrogenbudgetinglobalfoodandfeeddemonstratestheimportanceofnitrogen-richandprotein-richplantfoods.About70%ofnitrogeninharvestedfoodcropsbecomeavailable(afterprocessingandlosses)forhumanconsumption,whereasmeatanddairyproductionuselargeamountsofnitrogen.Nearly7kgoffeednitrogenisneededtoproduce1kgofediblenitrogeninmeat,eggs,anddairyproducts.Thus,findingsolutionstomoreefficientproductionofanimalfoodsanddampingtheprojectedupwardtrendlineofanimalbasedfoodsiscrucialtosupplyadequatenutritiontotheworld’sgrowingpopulationwithoutanymassiveincreasesofnitrogeninputs(Smil,2002).InCanada,theUS,andEurope,researchers,ingredientcompaniesandfoodmanufacturersareinvestigatingincreasedproductionanduseofpulseproteinfractionsinmanufacturedfoodproducts,inordertoboostthenutritionalqualityoffoods,anddietaryfibreandstarch,whichcanbeusedforfoodfortificationandtextureenhancement.Intheseprocesses,partsarederivedfromthewholeseed,suchasasplitseed,hullorfibre,downtoisolatedstarchandproteinfactions.Theseproductsarepromotedasplant-based,sustainable,non-geneticallymodifiedandgluten-free.4CompaniessuchasIngredion,AGTFoods,Burcon,Cosucra,andNutri-Peaandothersarecreatingfractionproducts,andfindingwaystoincorporatethemintomanufacturedfoodproducts.Researchersnotethatwetfractionationuseslargeamountsofwaterandenergy,andthefunctionalityoftheproteiniscompromisedduringprocessing.Dry4MarkOlsen,AlbertaDeptofAgricultureandForestry,verbalcommunication.
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fractionationisfoundtobemorewaterandenergyefficient,andretainsfunctionalityofthepulseprotein(SchutyserandvanderGoot,2015).Effortstomanufacturemeat-likeproteinproductsisimproving,witharecentsoy-basedmeatanalogueproductbeingproduced,withathicknessof30mm(Krintirasetal,2016).Effortsareunderwaytofurtheridentifyhowpeaproteinandothervegetablefiberscanbeusedforthispurpose.BalancinglivestockproductionandfoodsecuritythroughpulsesLivestockproductionbenefitswithoutfoodsecurityconflictsaredemonstratedviatheintegrationofherbaceouslegumesintothemaizeanduplandricesystemsinWestTimor,Indonesia.Aftersixyearsofparticipatoryresearch,findingsindicatesignificantbenefitsforlocalfarmers.Farmersusuallyrelyonlow-qualitynativeforages,sometimessupplemented,tofeedtheirlivestock.Highrainfalllevelsinthemonsoonseasonandclimatevariabilityprovidesrisksthatoftenresultinfeeddemandsoutstrippingsupplyandlowratesofproduction,withupto60%oftheweightgainedbylivestockduringthewetseasonlostduringthelatedryandearlywetseasons.Herbaceouslegumeswereaddedeitherinannualrotationwithacerealorafterwet-seasoncerealproductionhasbeencompleted,whenlandistraditionallyleftfallow.Ascowpea,peanut,andmungbeanarealreadyoccasionallyintercroppedwithmaizeinthewetseason,researcherschosetopromoteherbaceouslegumesasagreenmanureorinrotation,solegumeswouldnotfurthercompetewiththecerealcropsfornutrientsandtherebyproducelessforage.Researchoutcomesindicatethata)itispossibletoaddanadditionalcropintoatraditionalfarmingsystemwithoutaffectingexistingfoodsecurity,b)thatfeedingforagelegumestocattleduringthelatedryorearlywetseasonresultedinincreasesinlivestockweight,andc)thatnitrogenprovidedbylegumesimprovedmaizeproductioninsubsequentcrops.Criticaltothesuccessofintegratingherbaceouslegumesintoanannualcropcyclewastherecognitionthatwaterremaininginthesoilasthemainwet-seasoncerealcropmaturesisaresourcethatcanbeavailableforthesubsequentdry-seasonproductionofherbaceouslegumes,whichisaperiodinwhichfoodcropsarenottraditionallygrown(Nuliketal,2013).GenderGenderaspectsofpulseproductionareparticularlyimportantincontextswherewomencanbeinvolvedinvariousstagesofproductionandthroughoutthevaluechain.ThisisfurtherexploredintheAfricacasestudy,insection3.2.NorelevantfindingsrelatedtogenderwereidentifiedintheSaskatchewancasestudy.1.2.3EconomicbenefitsFarmersingrainandoilseedproductionhavefoundeconomicbenefitsfromlowerinputcostsandincreasedprofitsbyincludingapulsecropintheirrotation.Thesebenefits
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accruemainlythroughenhancingtheefficiencyofnitrogenfertilizeruse,reducingtillageand,insomecasesreducingpesticideuse.Reducedandalteredtillagepracticesreducerelianceonfossilfuelsandlowersoverallfuelbills.No-tillsystemswithpulsesprovideabasisforsustainableagriculturalintensification,includingintegratedcropapproaches.Itisestimatedthatfarmerssavebetween30-40%oftime,labourandfossilfuelsusingno-till,comparedtoconventionaltillage(FAO,2001;Lorenzatti,2006).InArgentina,areviewoffarmerpracticesfoundthatwithoneliteroffuelitispossibletoproduce50kgofgrainunderconventionaltillage,whereasunderno-tillitispossibletoyield123kgofgrain(Lorenzatti,2006).Betternitrogenmanagementrequireslessfertilizerinputs.Therearevariations,ofcourse,intheeconomicreturnsexperiencedindifferentgeographiesandfarm-types,andtheseareexploredfurtherinthecasestudies.Farmerslikelyalsoseethelong-termeconomicbenefits(andavoidedcosts)oflesssoil,airandwaterdegradationbyadoptingno-tillpracticesandincludinglegumesintheiroperations.InSaskatchewan,Canada,includingoilseedandpulsecropsinrotationswithcerealgrainscontributedtohigherandmorestablenetfarmincome,inspiteofhigherinputcosts,acrossmostsoiltypes.ThecasestudyinSection3.1summarizeskeyfindingsregardingthesignificantbenefitstofarmersandtheprovincialeconomy.SignificantfindingsexistandhighpotentialforfurthereconomicbenefitsalsoexistsinAfrica,andthisisfurtherexploredinSection3.2.Beyondthecasestudygeographies,relevantinsightsshouldbenoted,particularlyrelatedtoIndia,whichisthelargestconsumerofpulsesglobally.Indiasoughttoincreasepulseproductionby2milliontonnesbytheendoftheEleventhFiveYearDevelopmentPlan(2011-12),throughimplementationoftheNationalFoodSecurityMissionforPulseCrops(NFSM).OnestudyassessingtheimpactoftheNFSM,basedoninterviewswithfarmersovertwodistrictsinthestateofMaharashtra,identifiedsignificanteconomicreturnsatthefarm-levelfromtheprogramme’simprovedtechnologies(improvedpulseseed,integratednutrientmanagementandintegratedpestmanagementpractices,resourceconservationtechnologies,andcapacitybuildingoffarmers).Farmersinadistrictparticipatingintheprogrammesawdoublethenetreturnsfrompulsescropcultivationin2008-09overthepreviousyearascomparedtothenon-NFSMdistrict.Further,theprofitfrompulsesexceedednetprofitmarginsofallothercropscultivatedinthedistrict,despitethisoccurringinrainfedconditions(Shah,2011).However,economicgainsfrompulseproductioncouldbefargreaterinIndia,andimporttariffs,minimumpricesupports,andgovernmentsupporthaslargelyunderservedtheneedsofIndiaproducingenoughpulsestomeetdomesticdemandanddiversifyfarmincomes(RefertoBox1).
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AddingpulsestorotationsineconomicallydeprivedareasinIndiacouldbringmuchneedednourishmentandincometomillionsofpoorsmalllandholderssolelydependentonagriculturefortheirlivelihoods.About12millionhectaresthatareunderriceproductionduringtherainyseasoninIndiaremainfallowinthesubsequentpost-rainy(rabi)season.Effortstointroducepulses(primarilychickpea)intheserabiconditionscouldhavesignificanteconomicandpovertyalleviationbenefits(Joshietal,2002).Yetchallengesremain.TherehasbeenaprogressivedeclineinpercapitaavailabilityofpulsesinIndia,fallingfrom69gramsin1961to32gramsin2005.Therequirementwasestimatedtobe21.3milliontonnesby2012.TheEconomicSurvey2012-2013reportstheestimatedproductionofpulsesin2011-2012as17.09milliontonnes,indicatingawidegapindemandandsupply(Swaminathan,2013).Investmentsinpulsecropresearchisshowntohavesignificanteconomicbenefit.TheCGIARResearchProgramonGrainLegumes,aglobalalliancecoordinatingeffortsacrossfourCGIARcenters,estimatedin2012thatthenetpresentvalueofgrossbenefitsofitslegumeresearchandextensionisestimatedatUS$4.5billion,equivalenttoUS$535millionperyear.BasedonproposedactivitiestobeundertakenbythisCGIARprogram,between2014─2020,legumeresearchwasalsoprojectedtocontributetofoodsecuritythroughincreasedavailabilityoffood(over8milliontons),nutritionsecurityfrommore
Box 1: Economic challenges for pulses in India
Indiaisthelargestconsumerofpulses,butgovernmentsubsidiesandpricecontrolsintheagriculturalsectorcreateddistortionsthataffecteddomesticproduction.Governmentsubsidiesforfertilizerandwaterpromotedgrainsandoilseedsratherthanthemixofsupportnecessarytopromotepulses.Protectionistpoliciesinthe1970sand1980swerereversedinthe1990s,whengovernmentreformssoughttoremoveimportrestrictionsandlowertariffsonagriculturalproducts.However,withtheexceptionofBasmatiriceanddurumwheat,externaltradeinallmajorcropswasregulated,andimportsofmostcropsoccurredonlythroughgovernmentagencies.Pulsesweretreateddifferently,withimporttariffsonpulsesreducedgraduallyandabolishedby1996.Thehopethatdomesticpulsemarketliberalizationwouldincreaseimportsdidnotmaterialize.Rather,theshareoftotalpulseimportsintotalmerchandisetradedeclinedaftermarketliberalization(Agbola,2004).
Further,inIndia,minimumsupportpriceshavebeenestablishedasoneofthepolicyinstrumentsusedtoimprovetheeconomicviabilityoffarming,stablizecommodityprices,andenhancefoodsecuritybydiversificationintooilseeds,pulses,livestockandfish.However,minimumsupportpricesforpulseshavenotdemonstratedthesameresultsasthoseforrice.Pricesforpulseswereincreasedbetween2008-09,ataratehigherthanthatforfoodgrains,butthatdidnottranslateintolargerareasplantedunderpulses,andthisisattributedtotherisksassociatedwithpulsecultivation.Incomparison,paddycultivationdoesnotcarrysuchrisks,andfarmersareassuredofprocurementbygovernmentagencies,whereasthisisnotthecaseforpulses(OECD-FAO,2014).
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availabilityofprotein,andenvironmentalbenefitsthroughbiologicalnitrogenfixation(afertilizercostsavingofUS$418million).TheCGIARestimatedthatover50%oftheprojectedeconomicbenefitsoflegumeresearchandextensionwouldaccrueinSouthandSouth-EastAsiaandSub-SaharanAfrica,wheremostoftheworld’spoorestcommunitiesarelocated(CGIAR,2012).Addingpulsesintolivestockdietsalsohaseconomicbenefit,butappearsdependentonmarketpricingandlabouruseefficiencies.FindingsinWesternChinaindicatethatlivestockforagesystemintensificationbyincorporatingaforagecropintograin-croppingsystemsincreasedaverageprofitswithoutincreasingdownsideriskssuchasnegativeprofit,cropfailure,orlivestockmortality.Foragevetchwastheleguminouspulsecrop,butforageoatsandgrainsoybeanwerealsoincorporated.Incontrast,replacingagraincropwithaforagecropingrain-croppingsystemshadanegativeeffectonprofits,downsiderisk,andlabour-useefficiency.Trade-offsbetweenlabour-useefficiencyandprofitwereobservedasforageintensificationincreasedlabourdemands,howevertheseeffectswerecontextspecific(Komareketal,2014).FindingsinWesternCanada,basedonalifecycleassessmentoftwoswinediets—oneusingsoybeanmealinawheat-basedfeed,andtheothersubstitutingthesoybeanportionwithdrypea—indicatesthedrypeadiettobeasubstantialeconomicimprovementoverthesoybeanmealdiet.Therateofreturnonassetsforaswinefarmsubstitutingthesoybeanportionoffeedwithdrypeainswinedietswas4.4%,animprovementof3.6%overthe0.9%estimatedwhentheswinefarmwasusingthesoybeandiet.Onlywhenhogpriceswerelowerandfeedcostsincreasedwerethebenefitsofincorporatingdrypeainthedietnotapparent(McWilliametal,2011).
2. Methodology Thisresearchwasguidedbyaneutralinvestigationapproachtounderstandingthekeyfeaturesofpulsecropproductionassociatedwiththethreepillarsofsustainability.Attentionwasgiventosocio-economicdevelopmentandenvironmentalbenefits,acrossbothdevelopedanddevelopingcountries,andrangingfromsmallholderfarmstolarge-scaleagricultureproductionsystems.Abroadliteraturereviewwasconducted,andinterviewsconductedwithpulseresearchersandmembersoftheIYPProductivityandSustainabilityCommittee.Insightsfromtheliteraturereview,twoin-depthcasestudies–Saskatchewan,CanadaandpulseproducingregionsofSub-SaharanAfrica—andinterviewsguidedtheformationofthesustainabilityframeworkbytheauthor.
3. Case studies
3.1 Saskatchewan
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Saskatchewancovers651,900km2andcontains44%ofCanada'scultivatedfarmland.AccordingtotheSaskatchewanPulseGrowersassociation,theprovinceproducedmorethan95%ofCanada’slentilandchickpeacrop,andnearlytwothirdsofitspeacrop,80%ofwhichisexported.Canadaistheworld’slargestexporterofpulses,supplying33%oftheworldtradeinpulses,mostlyinsalestoIndia,China,Turkey,Bangladesh,andtheUnitedStates.Thishasbeenafairlyrecentdevelopmentoverthelasttwentyyears,withhectaresseededtopulsesincreasing1,000%,from193,000hain1981to2.1millionhaby2011(refertoFigure1).
3.1.1ContextPulsecropsgrowninSaskatchewanincludechickpeas,drybeans,drypeasandlentils.TheSaskatchewanPulseGrowers,createdaftergrowersin1983chosetoinstituteamandatory,non‑refundable1%levytofundprogramsthatwoulddevelopthepulseindustry,providesresearchandcapacityforgeneticimprovement,agronomy,healthandnutrition,andprocessingandutilization.Thelevyisappliedtogrosssalesatthefirstpointofsaleordistribution.TheSaskatchewanPulseGrowersallocatesabout60%ofitsannualbudgetintoresearchanddevelopment,benefitting15,000Saskatchewanpulsegrowers.In2014/2015,thelevycontributed97%oftheCD$10.1milliontheorganizationinvestedinresearchanddevelopment,andanother$2.8millioninmarketpromotion,mostofwhichwasfocusedondomesticlentilmarkets(SaskatchewanPulseGrowers,2015).Forthe2015-16cropyear,acrossCanada,productionofpulsesandspecialtycropsisestimatedat6.3Mt,5%lowerthan2014,asloweraverageyieldsmorethanoffsetthehigherareaseeded.Drypeaproductiondecreasedinthe2015-16periodby16%,to3.2Mtduetoloweryieldsandlowerharvestedarea,particularlyinSaskatchewan.Yellowandgreenpeatypesareexpectedtoaccountforabout2.5Mtand0.7Mt,withtheremainderbeingothervarieties.Supplyhasdecreasedbyonly12%,to3.7Mt,duetolargecarry-instocks.Exportsareforecastat2.95Mt,withIndia,BangladeshandChinaremainingCanada'stopthreemarketsfordrypea.Yieldsperhectarehavedecreasedoverlastthreegrowingseasons.Incontrast,lentilproductionincreasedby19%tonearly2.4Mt,asloweryieldspartlyoffsetrecordharvestedareaandlowerabandonment;thelargestgainsweremadeinredlentilproduction.Pricesareatrecordlevels,andIndia,TurkeyandEgyptarethetopexportmarketsforlentil.Productionof
Figure 2: Hectares seeded with pulses by variety in Canada (1981 to 2011)
Source:Bekkering,2014,basedonStatisticsCanada,CensusofAgriculture,1981to2011
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drybeansfellby10%acrossCanada,thoughtheUSandtheEU-27willremainthemainexportmarkets.Thoughchickpeaproductionfellby31%to90kilotonnes,duetolowerareaandyieldestimates,carry-instockshelpoffsetthesupplydecrease,andexportsareexpectedtoincrease,withtheUSandPakistanbeingthelargestbuyers(AgricultureandAgri-FoodCanada,2015).
3.1.2EnvironmentalCereal-fallowrotationshavebeenthepredominantcroppingsysteminthesemiaridCanadianPrairies,howeverpatternsofmonoculturecerealcroppingresultedinpestanddiseaseoutbreaksanderosion,whichspurredfarmerstoseekalternatecropstoincludeinrotation.Fallowinghasresultedinincreasedsoilsalinityandlossofsoilnitrogenandwater.Pulsecropswereintroducedtoreplacesummerfallowinthepastfewdecades.Conventionaltillagehasledtoincreasedsoilerosion,despitethebenefitofincorporatingcropresiduesintothesoil.TheintroductionofpulsesintotheSaskatchewangraincroprotationswasfoundtohaveanumberofenvironmentalbenefitsbeyonderosioncontrol.Pulsesaremoredroughttolerantandefficientinwaterusethanmostgraincrops,andthereforecouldwithstandsummercroppinginthedrierBrownandDarkBrownsoilzones(Cutforthetal,2009).Farmerssoughtmorediversifiedandintensivecroppingsystems,increasinglyabandoningthepracticeofsummerfallow,andpreferringtocropthroughfourseasons.Thus,pulsecropswereaddedintopredominantlycerealandoilseedrotations,andmostoftenreplaceacerealcrop,suchaswheat,ratherthanreplaceanoilseedcrop,suchascanola.No-tillseedingpracticeseliminatestheneedtoplowbyplacingseeddirectlyintoundisturbedstubbleorsod.Thegreatestenvironmentalbenefitofaddingpulsecropsintocereal-fallowrotationswastheirnitrogenfixationcapability,whichreducedfertilizernitrogenrequirementsinthecurrentandsucceedingcrop,andcapacityofthesoiltosupplynitrogen.Thisovercamealimitationinconservationtillagesystemswhereminimalsoildisturbanceslowedcyclingorreleaseofnitrogenfromcropresidues(Brandt,2010).Achallengeinshiftingfromconventionaltillagetoconservationtillagepracticesisinmanagingweeds.ThepriceandabundanceofherbicidessuchasglyphosatehadamajorroletoplayinfarmeradoptionofconservationtillageinAustralian,LatinAmericanandNorthAmericanregionsthathaveexperienceddramaticchangesinfarmeruptakeofconservationtillagepractices.FarmersinSaskatchewanfacedweedcontrolchallengesfromdiversifiedrotationsastheherbicidetreatmentsforpulseandoilseedcropsweregenerallylesseffectivethanforcereals.Overtime,farmersimprovedtheirherbicideandmanagementpractices,leadingtoreducedratesinuse,andasignificantreductioninrepeatapplications(Brandt,2010).
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Pulsecroppinginrotationwithcerealswithouteffectivetillageandcropresiduemanagementpresentserosionproblems,particularlyontheBrownandDarkBrownsoilsofSaskatchewan,inareaswherestrongwindsarecommon.Erosionhasbeenfoundtoincreaseduringproductionoffieldpea,lentil,andchickpeaintheseareas,astheyoftenproducelesscropresiduethancerealcrops,andthecropresidueismoreeasilydisintegratedbytillagethancerealresidue.Farmersareadvisedtominimizepulsecroppingonhighlyerodiblesoils;minimizeoreliminatetillage,particularlyinthefall,whilealsoapplyinglow-disturbancedirectseedingwhenpossible;maximizecarryoverofcropresiduefromoneyeartothenext;slowtractorspeeds;andavoidharvestingpulsestrawforfeedonlandpronetoerosion(McConkeyandPanchuk,2000).BasedonfarmersurveysacrossCanada,theproportionoffarmswithpulsesreportingno-tillseedingpracticesincreasedfrom6.7%usingno-tilland24.4%usingconservationtillagein1991to56.4%usingno-tilland24.6%usingconservationtillagein2011.Conventionaltillagehasdroppedinusefrom69%in1991to19%by2011,acrossCanada(StatisticsCanada,2011).Thiscoincidedwiththeincreaseinpulseproductionoverthesametimeperiod.Alifecycleandsocio-economicanalysisofpulsecropproductionandpulsegrainuseinWesternCanadaprovidesimportantinsights.Thegoaloftheresearchwastodeterminethedifferenceinenvironmentalandsocio-economiceffectsofincludingpulsecropsinrotationaswellasusingpulsecropsforhumanconsumption(system#1inBox2below),andasswinefeed(systems#2inBox3below).Environmentalbenefitswerefoundtobestrong,primarilyduetothenitrogenfixationabilitiesofpulsecrops,thereductioninnitrogenrequirementsofacerealcropsucceedingapulsecrop,andtheincreaseinquantityandnutritivequality(proteincontent)ofacerealcropfollowingapulsecrop.Evenwhenconsideringthepracticeofapplyingpesticidestothecrops,thisdidnotgeneratesufficientdifferencesinenvironmentaleffectstodiscounttheoverallpositiveenvironmentalresults(McWilliametal,2011).GreenhousegasemissionreductionThegreenhousegasemissionreductionbenefitsofaddingpulsesintorotationswithgrainisattributedtoarangeofinterventions,notjusttheaddednitrogenfixationcapacityofpulses.Researchwasconductedonawheatrotationsystem,utilizingthe25-year(1985–2009)fieldstudyconductedinSwiftCurrent,SaskatchewanbytheAgricultureandAgri-FoodCanadaResearchCentre.Findingsindicatethatanimprovedfarmingsystem,basedonfertilizingcropsbasedonsoiltests,reducingsummerfallowfrequenciesandrotatingcerealswithpulses(lentil,inthiscase)lowersthewheatcarbonfootprintconsiderably(anaverageof256kgCO2eqha-1peryear).Amongthefourcroppingsystemstested,whichincludedfallow-flax-wheat,fallow-wheat-wheat,continuouswheat,andlentil-wheat,thelentil-wheatsystemclearlyoutperformedtheothers.Thiswasduetothelowerratesofnitrogenfertilizerrequiredbythewheatcrop
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inthislentil-wheatrotation,andtheincreasednitrogenavailability,whichenhancedplantbiomassaccumulation.Resultsindicatethatspringwheatgrownusingthissuiteofimprovedfarmingpracticescanattainanetcarbonbalanceregardlessofwateravailability(Ganetal,2014).Researchshowsthatcroprotationscontainingapulsecrophaveloweroverallgreenhousegasemissionsthanthosethatdonotincludeapulsecrop.Thisisbecauseupto70%ofthenon-renewableenergyusedinWesternCanadiancroppingsystemsisduetotheuseoffertilizers,particularlynitrogen.Pulsessupplytheirownnitrogen,reducingtheneedforaddednitrogenfertilizer.Researchonnitrousoxideemissionsspecificallyislimited,butshowsthatemissionstendtobelowerforpulsecropscomparedtofertilizedcerealcrops.Indicationsarethatthemoreoftenapulsecropisgrowninrotation,themoregreenhousegasemissionsarereduced.One17-yearstudyatSwiftCurrent,Saskatchewan,indicatesareductioninGHGemissionsof31%annuallywhenlentilswereincludedinrotationwithspringwheat.AsimilarstudyatIndianHead,Saskatchewanshowedan18%reductioninyearlyGHGemissionswhenpeaswereincludedinrotationwithspringwheat,winterwheat,andflax.Thesitewiththe
Box 2: Summary of system 1- Life Cycle and Socio-Economic Analysis of Pulse Crop Production and Pulse Grain Use in Western Canada System#1.Pulseincroprotations:Oilseed/cerealrotation:canola,wheataftercanola,wheatLentilrotation:canola,wheataftercanola,lentil,wheatDrypearotation:canola,wheataftercanola,drypea,wheat
Keyfindingsinthelentilanddrypearotationsmodeled,comparedtotheoilseed-cerealrotations:
HumanHealth:Reductionsinhumanhealthimpactsarenotedrelatedtoreducedcarcinogens,non-carcinogens,respiratoryinorganics,ionizingradiation,ozonelayerdepletionandrespiratoryorganics.Humanhealtheffectsarerelatedtotheamountsofinputsrequiredforproduction,hencedecreasedinputsequatestolessuseoffertilizers,fewerfieldoperationssuchasharvestingequipment,andlesstoxicemissionsreleasedtotheair.
Ecosystemquality:Reductionsineffectsonthequalityoftheecosystemsuchasaquaticecotoxicity,terrestrialecotoxicity,terrestrialacidification/nutrification,landoccupation,aquaticacidificationandaquaticeutrophicationduetofertilizeruseandmechanizedharvestingwerenoted,basedonreductionsintheamountofappliedchemicalsandfertilizers,whilewheatyieldsincreased.
GHGemissions:ReductionsofGHGemissionsby25%inthedrypearotationand22%inthelentilrotationarenoted,whilenon-renewableenergywasdecreased25%inthedrypearotationand21%inthelentilrotation.GHGemissionreductionsareattributedto
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greatestmagnitudedifferenceincludedapulsecroponceeverytwoyears,whereasattheotherlocationsapulsecropwasincludedonlyonceeveryfouryears(Lemkeetal,2007).AsimilarstudyatIndianHead,Saskatchewanshowedan18%reductioninyearlygreenhousegasemissionswhenpeaswereincludedinrotationwithspringwheat,winterwheat,andflax(Lemkeetal,2007).Usingacarbonfootprintmethodofanalysis,areviewofavailableliteraturefoundthatdurumwheatprecededbyanitrogen-fixingpulsecropemittedtotalgreenhousegasesof673kgCO2eq,whichis24%lowerthanifthecropwasprecededbyacerealcrop.Inthissameanalysis,itwasdeterminedthatcanolaandwheathadsignificantlygreatercarbonfootprintthanpulsecrops(suchaschickpea,drypea,lentil)(Ganetal,2011).Incontrolledcircumstances,biologicalnitrogenfixationbylentilandpeawasdeterminednottobeadirectsourceofnitrogenemissions(Zhongetal,2009).Alifecycleanalysisfoundthatbyreducingtherequirementforsyntheticnitrogenfertilizers,pulsecropsinherentlyreducetheemissionsandenergyuseassociatedwiththeproduction,useanddisposaloffertilizers(McWilliametal,2011).
Box 3: Summary of system 2- Life Cycle and Socio-Economic Analysis of Pulse Crop Production and Pulse Grain Use in Western Canada
System#2.PulsesforSwineFeed:Replacingtheimported(fromtheUS)soybeanmealinswinefeedwithdrypea
Starterswinedietsexaminedinthestudyhada15%rateofdrypeainclusion,whereasthemorematuregrowerandfinisherswinedietscontained42.5%and30%inclusionratesofdrypeainthefeedmix.Feedproductionaccountedforthemajorityoftheenvironmentaleffectsassociatedwithswineproductioninallimpactcategories(50-100%).However,themajorityoftheGHGemissionsfromswineproductionwereassociatedwithanimalhusbandry(53-55%),notfeed.Additionalenvironmentalbenefitswouldoccurifwheatgrownafterapulsecropwasincludedintheswinediets.
Humanhealth:Findingsindicatethatreplacingsoybeanmealwithdrypearesultedinamarkeddecrease(-30%)inlifecyclerespiratoryorganics,althoughotherimpactcategorieswerecomparable.
Ecosystemquality:Findingsindicatecomparableeffectsonecosystemqualityinthecategoriesofaquaticecotoxicity,terrestrialecotoxicityandlandoccupation.However,thesoybeanmealdiethadgreaterterrestrialacidification/nutrification(17%),aquaticacidification(13%)impacts,whilethedrypeadiethadgreateraquaticeutrophication(63%)impacts.Decreasedfertilizerrequirementsinthedrypeadietresultedinaquaticandterrestrialacidification.
GHGemissions:ThetwoproductionsystemshadsimilarGHGemissions.Thedrypeadietdecreasednon-renewableenergyuseby11%,basedlargelyonthereductionofwheatinthediet.
Source:MacWilliametal,2011.
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3.1.3SocialThesocialbenefitsofpulseproductioninSaskatchewanarenotwelldocumented,howeveranecdotalevidencesuggeststheshifttono-till,reductioninsummerfallow,andintroductionofnewcropssuchascanolainthe1970sandmorerecentlypulses,hasprovidedthemeanstokeepfarmersonthefarm,andkeepruralcommunitiesrelativelyintact.Atitspeakin1936,Saskatchewanhad142,000farms,by2011thatnumberhaddroppedtojustover37,000(Bitner,2010;StatisticsCanada,2011).Farmsizehasincreasedovertheyears,andSaskatchewanhasthelargestaveragefarmsizeinCanada,at1,668acres(675ha),andfarmsizesareincreasingatahigherratethaninotherregionsofCanada.Theaverageageoffarmoperatorsintheprovinceis54.2,whichisfairlyconsistentwiththenationalaverage.However,theruralpopulationisdecreasing,downto33%ofthepopulation,comparedto50%in1966and84%in1901(StatisticsCanada,2011).AnecdotalevidencefrominterviewssuggeststhatmanySaskatchewanfarmersgrowingcereal-fallowandcereal-canolawouldhavegonebankruptwithoutdiversifyingintolentilsandotherpulseproducts.Chickpeawaspursuedasapulsediversificationcrop,buttheascochytablightandlonggrowingseasonrequirementshavediminishedplantingsofthispulse.Thenextsectionprovidesmoreinsightintotheeconomicbenefits,asrecenteconomicreturnsfrompulseproductionshowsignificantbenefitstofarmersandtheprovincialeconomy,andthishasripplesocialeffectswithinruralcommunities.Thehealthaspectsofincludingpulsesindietsisanimportantindicatorofthesocialbenefitsofpulses,althoughNorthAmericanandCanadianconsumptionofpulsesappearstobefarbelowtheoptimallevel.Theroleofpulsesandlegumesindietarypatternsofpeoplewithdiabetescanbeimportanttoregulatebloodsugarlevelsandmoderatesymptoms.TheCanadianDiabetesAssociationClinicalPracticeGuidelinesrecommendthatalow-fatvegandiet(whichwouldincludepulseandlegumes)improvesglycemiaandplasmalipidsmorethantheconventionaldiets.Researchtestingdiabetespatientresponsetoacalorie-restrictedvegetariandietversusaconventionaldietdemonstratedasignificantdecreaseindiabetesmedicationuseinthevegetariancomparedtothoseonaconventionaldiet(a38%difference).Similarly,a“Mediterraneandiet”whichispredominantlyaplant-baseddiet(includingfruits,vegetables,legumes,nuts,seeds,cereals,wholegrains,amoderate-to-highconsumptionofoliveoil,andlowconsumptionoffishandmeat)isconfirmedtoimproveglycemiccontrolandcardiovascularriskfactors,includingsystolicbloodpressure.ThemetabolicadvantagesofaMediterraneandietimproveprimarypreventionofcardiovasculardiseaseinpeoplewithtype2diabetes(Dworatzeketal,2013).TheSaskatchewanPulseGrowersandPulseCanadaaresupportingresearchontheglycemicresponseofpulseflourandfractioningredients,inordertobetterunderstandhealthbenefitsandinformfuturedevelopmentofpulseingredientsandfoodproductmatrices(SaskatchewanPulseGrowers,2015).
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3.1.4EconomicGrainproducersinSaskatchewanexperiencedaconvergenceoffactorsthatcontributedtotheuptakeofpulseproduction.Theenvironmentalaspectssuchasreducederosionandnitrogenfixationbenefitstothecurrentandsubsequentcrops,andsocialreasonssuchastheabilityoffarmerstostayintheagriculturesector,aredescribedabove.Buttheeconomicreasonsfordiversifyingintopulsecropsweresignificant.OneinfluencewasCanada’scommitmentin1994tocutgrainexportsubsidiesby21%involumeandby36%indollartermsoveraperiodofyearsaspartofitsagreementtotheGlobalAgreementinTradeandTariffs,andalsothe15%cutinsubsidiestograinundertheWesternGrainTransportationAct(DakersandFréchette,2001).Thishadadirecteffectongrainpricesandexportmarketdynamics.AnotherfactorwasthattheeconomicbenefitsofaddingpulsesincroppingsystemsinSaskatchewanwererecognizedovertime,asfarmersincreasinglyeliminatedsummerfallowperiods.Along-termcroprotationexperiment,firstestablishedin1967onBrownsoilsinSwiftCurrent,Saskatchewan,andrunninguptothe2002season,evaluatedtheeconomicperformanceofconventionaltillagemanagementpracticesinthissemiaridregion.Researchinvestigatedthemostoptimalcroppingfrequency,valueofapplyingnitrogenandphosphorousfertilizeratsoiltestrates,andtheadvantageofreplacingmonoculturewheatwithpulseoroilseedcropsgrowninmixedrotations.Findingsindicatedthatunderthemorefavorablegrowingconditionsbetween1985–2002(ascomparedtothepreviousstudycoveringthe1967–1984period),areaproducerscouldmaximizeeconomicreturnsbychoosingawheat-lentil(withnitrogenandphosphorousapplication)rotation,andeliminatingsummerfallowfromthecroppingsystem.Netreturnsfromthenextoptimummixesoffallow-wheatandcontinuouswheatrotationswere44%lessthanforthewheat-lentilrotation.Researchersfoundthatonlyifproducerswerehighlyriskaverse,didnotsubscribetoall-riskcropinsurance,orifthepriceforwheatwashighorpriceforlentillow,wouldthemonocroppedwheatsystemsbepreferredtowheat-lentil(Zentneretal,2007).Similarly,evidencefromareviewofempiricalstudiespriorto2002suggestedthatincludingoilseedandpulsecropsinrotationswithcerealgrainscontributedtohigherandmorestablenetfarmincome,inspiteofhigherinputcosts,acrossmostsoiltypes(Zentneretal,2002).Recenteconomicreturnsfrompulseproductionshowsignificantbenefitstofarmersandtheprovincialeconomy.Saskatchewan’sagri-foodexportsalesin2014wereCD$13.9billion,CD$2.7billionofwhichwerelentilsandpeas.Whilethevolumeoflentilexportshasincreased67%between2009and2014,thevalueofthoseexportsincreased37%.Peaexportsshowadifferenttrendoverthesameperiod,withthevolumeofpeaexportsincreasing19%,whilethevalueoverthesametimeperiodincreased56%(Saskatchewan,2015).Thecroptypesthatareputinrotationcanbeastrongdeterminantoneconomicreturns.McWilliametalreferenceonestudyintheBlacksoilzone,thenetreturnfor
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drypeaafterbarleywas39%lowerthanthatforwheatafterdrypea.Whereasinanotherstudy,alegume-basedrotationofwinterwheatandvetchwasfoundtoproducea16%higherreturnoveracontinuouswinterbarleyrotation.However,McWilliametalcautionagainstsuchresults,particularlyforthenetreturns,asthemarketpricehasmoresignificanteffectthancosts,intermsofnetreturns,andmarketpricingcanbequitevariable.McWilliametalnotethatmanystudiesonincludingdrypeaorlentilinagrainorgrain-oilseedrotationsobservethecostsofproductionincreasing,butthatincreasedcostsareoffsetbyincreasedreturns,leadingtohighernetreturnstoproducers(McWilliametal,2011).Cropdiversityisahedgeagainstficklemarketsandchangesinprice.Farmersurveysin2011indicatethatfarmsgrowingpulsesproducealargervarietyofcropsthanfarmsnotgrowingpulses.Twenty-sixpercentofallpulse-producingfarmsreportfourfieldcroptypes,andoneintenfarmsgrowingpulsesgrowsevenormorefieldcroptypes,indicatingsignificanton-farmdiversity(Bekkering,2012).Anotheraspecttodiversificationincroptypesandpricingthatislikelysignificant:diversifyingthecroppingmixwithcropsthatdonothavecorrelatedpriceshelpsspreadmarketrisk.LentilhasthelowestcorrelationeffectsofcropscommonlyputinrotationinSaskatchewan.Byincludinglentilinrotationwithothercrops(refertothevaluesinTable1below)farmlevelrisksarereduced,asthepricesofthesecommoditiesarenotasstronglycorrelatedasgrainssuchaswheatandbarley.Drypeaalsohaslowercorrelationeffects,butnottothesamedegreeaslentil,andthereforemaynotofferthesameriskreductionaslentil(McWilliametal,2011).Lentilsinrotationaddconsiderablevaluetoeconomicreturnsincroppingsystemsovermultipleyears.TheSaskatchewanCropPlannerisavailabletofarmerstohelpestimatethepotentialincomeandcostsofproductionfordifferentcropsinthevarioussoilzonesintheprovince.ThePlannerfactorsincropprices,yields,inputssuchasfertilizer,othervariableandfixedcostssuchasmachineryandlabourcosts,landinvestmentcosts,andcropinsurancepremiums.Estimatesfromthe2015SaskatchewanCropPlannerindicatethatlentilsmakeanimportantrelativecontributiontothefinancialreturnsofrotationsindifferentsoiltypesfoundintheProvince(refertoTable1).Intheblacksoilzone,returnsovervariableexpensesfromlentilare38%oftotalreturnsfrombothrotationsover4years.TheBrownsoilzoneshowshighestreturns,withreturnsovervariableexpensesfromlentilexceeding60%oftotalreturnsfrombothrotationsover4years.ReturnsfromlentilovertotalrotationexpensesonaperacrebasisarealmostCD$100,comparedtodeficitsformostwheat,barley,oatandcorncrops,andmarginallybetterreturnsforredlentil,edibleyellow,ediblegreenpeas,soybeanandcanola(Saskatchewan,2015).TheserangesarelargelycorroboratedbythefindingsofMcWilliamsetal,whichappliedapartialequilibriumsimulationmodelbasedon2006pricestoassesstheeconomicdesirabilityofpulsecropsinrotations.Findingsindicatethatdrypeaandlentilrotationsarebettereconomicchoicesthantheoilseed-cerealrotation.Includingpulsesinrotationisfoundtobepositiveexceptwhenpulsepricesarelowandgrainandoilseedpricesarehigh(McWilliamsetal,2011).
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Averagetotalexpensesforpulsecropsareroughlythesameasotherstubblecrops,withvariablecostsforpulsecropsbeingCD$180/acre,comparedtoCD$185/acreforallothercropsconsidered(tencropsincluded,rangingfromwheat,barley,oats,corn,soybean,flaxandcanola).Otherexpenses,includingmachinery,buildings,landaresimilarlycomparable,withpulsecrops(includinglargegreenlentil,redlentil,edibleyellow,ediblegreenpeas)costingCD$115/acrecomparedtoCD$116/acreforthetenothermajorcrops.Whenaddinglabourandmanagementintoproductioncosts,pulsesareslightlymoreeconomical,bringingtotalcoststoanaverageofCD$296/acreforpulsecrops,comparedtoanaverageof$302/acreforothercrops(Saskatchewan,2015).Areviewofempiricalstudiesfoundconsistentyieldadvantages,lessincomevariabilityandresourcesavingsinconservationtillageorno-tillagepracticeswhenincludingoilseedandpulsecropsintherotationwithcerealgrains,comparedtoconventionaltillage,andthereforetobehighlyprofitableintheBlackandGraysoilzonesoftheCanadianPrairies,duetosubstitutingherbicidesformoremechanizedtillage.IntheBrownsoilzoneandpartsoftheDarkBrownsoilzone,theshort-termeconomicbenefitsofusingconservationtillagepracticesaremoremarginalandlessprofitablethancomparableconventionaltillagepractices(Zentneretal,2002).
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Table 1: Economic returns of lentils in rotations, based on different soils in Saskatchewan
BlackSoilZone Rotation 1 Rotation 2
Crop
ReturnoverTotalExpenses
($/ac)
ReturnoverVariable
Expenses($/ac) Crop
ReturnoverTotalExpenses
($/ac)
ReturnoverVariable
Expenses($/ac)Year1
Oats(onstubble) -27.60 87.79
SpringWheat(onstubble) 3.26 118.65
Year2
SpringWheat(onstubble) 3.26 118.65
LargeGreenLentil(on
stubble)96.35 211.74
Year3
LargeGreenLentil(on
stubble)96.35 211.74
CPSWheat(onstubble) -14.96 100.43
Year4
Canola(onstubble) 10.15 125.54
Canola(onstubble) 10.15 125.54
DarkBrownSoilZone
Rotation 1 Rotation 2
Crop
ReturnoverTotalExpenses
($/ac)
ReturnoverVariable
Expenses($/ac) Crop
ReturnoverTotalExpenses
($/ac)
ReturnoverVariable
Expenses($/ac)Year1
Chemfallow
SpringWheat(onstubble) 0.67 107.83
Year2
SpringWheat(onfallow) -67.96 104.03
LargeGreenLentil(on
stubble)199.12 306.28
Year3
LargeGreenLentil(on
stubble)199.12 306.28
Durum(onstubble) -6.02 101.14
Year4
Durum(onstubble) -6.02 101.14
Canola(onstubble) 18.43 125.59
BrownSoilZone
Rotation 1 Rotation 2
Crop
ReturnoverTotalExpenses
($/ac)
ReturnoverVariable
Expenses($/ac) Crop
ReturnoverTotalExpenses
($/ac)
ReturnoverVariable
Expenses($/ac)Year1
Chemfallow
SpringWheat(onstubble) -31.87 60.93
Year2
SpringWheat(onfallow) -63.65 83.21
LargeGreenLentil(onstubble)
184.33 277.13
Year3
LargeGreenLentil(onstubble)
184.33 277.13Durum
(onstubble) -19.18 73.62
Year4
Durum(onstubble) -19.18 73.62
Canola(onstubble) -25.42 67.38
Source:CropPlanningGuide,SaskatchewanMinistryofAgriculture,2015.
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3.2 Sub-Saharan Africa
3.2.1ContextFooddemandisexpectedtoincreasedramaticallyinSub-SaharanAfrica.Around40%oftheglobaltotalpopulationgrowthbetween2010and2050willtakeplaceinsub-SaharanAfrica,withitspopulationprojectedtomorethandoublefrom814millionpeoplein2010to1.7billionby2050(Hilderinketal,2012).Thecorrespondingfooddemandsbythisgrowingpopulationisstriking(refertofigure2).YetindicationsarethatAfricawillnotproduceenoughstaplefoodssuchascerealtofeeditspopulation.Thelargesttradedeficitsgloballyin2023willoccurinAfricaandAsia,andindicationsarethatAfricanfoodproduction,particularlyofstaplessuchascereals,willnotkeeppacewithdemand(OECD/FAO,2014).DemandforpulsesinSub-SaharanAfricaareexpectedtoincreasefrom14.6millionMTin2015to22.7millionMTin2030and37.3millionMTby2050,withthemajoritybeingbeansandcowpeas(Robinson,etal,forthcoming).ThevastmajorityofpulsesaregrowninrainfedareasinSub-SaharanAfrica,with19.5millionhaofproductionbeinginrainfedconditionsin2015comparedtoonly339,000hairrigated,andthatratioislargelypredictedtoendureoutto2030and2050(ibid).
3.2.2EnvironmentalTheenvironmentalbenefitsofpulseproductioninAfricaarenotdocumentedtothesamedegreeasinSaskatchewan.Mostpulseproductionoccursinrainfedareas(97%oftotalcroplandisrainfed),withlowuseofinputsandrelativelylowyields.InEthiopia,whilepulsescovered12.4%ofthegraincropareain2014-15,theirrelianceonfertilizersisalmostnegligible.Onprivatesmallholdings,cerealcropsdemanded89%ofinorganicfertilizersapplied,whilefarmersonlyappliedroughly4%ofinorganicfertilizerstopulsecrops(Ethiopia,2015b).InGhana,smallholderscultivatingpulsesusebasictechnologieswithoutmechanization,mostlyuserecycledseedandapplyinsufficientfertilizersandagrochemicals.Inaddition,therearesignificantbioticyield-reducingpestsanddiseases,especiallyinthecaseofcowpea.NotethatinGhana,allfertilizersusedinthecountryareimported,mostlybyYaraanddistributedbyWienco.Usehasincreasedbyover500%since2000,accordingtoGhana’sMinistryofFoodandAgriculture,CropsServicesDirectorate(Rusikeetal,2013).
Figure 3: Projected global food demand
Source:Hilderink,etal,2012.
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Similarly,ineasternDRC,allfertilizers,agrochemicalsandinoculantsareimported.Seedqualityispoor,despitedecadesofhigher-qualityseedproduction,distributionandassistancewithfarmerstoimproveuptake,withthecivilwarexertingsignificantnegativeeffect.Farmeraccesstocertifiedseedofimprovedvarietiesremainslowduetothelackofformalseedmultiplicationandmarketingsystems.Yieldsofcommonbeanhavefluctuatedoverthepastdecadewithnoupwardtrend(Rusikeetal,2013).Inthefuture,improvedmanagementpracticessuchasoptimalcroprotationsusingpulsecrops,couldbeanimportantmeanstopromoteappropriateapplicationandjudicioususeofsyntheticfertilizers,boostsoilfertilityandyieldsofsubsequentcrops.ThechallengeisforAfricanpulseproductiontonotonlymakehugegainsinrealized(on-farm)yields,buttoalsoadapttoachangingclimate,withincreasedwaterandtemperaturestress.Improvedaccesstoimprovedseedandagro-chemicalsandcomplementaryfarmpracticesareneededtocloseyieldgaps.Governmentpoliciesareneededtoreduceproductioncosts(e.g.throughsupportforsmall-scalemechanization),lowerproductionrisk(e.g.cropinsurance)andstabilizemarkets(e.g.commodityexchanges,pricesupports).TheAfricaAdaptationGapReportfindsthatwarmingprojectionsundermediumscenariosindicatethatextensiveareasofAfricawillexceed2°Cbythelasttwodecadesofthiscenturyrelativetothelate20thcenturymeanannualtemperature.Underahighwarmingscenario(over4°C),thatthresholdwouldbecrossedbymid-centuryacrossmuchofAfricaandreachbetween3°Cand6°Cbytheendofthecentury.Inthe2ºCwarmingscenario,allcropyieldsacrosssub-SaharanAfricawilldecreaseby10%bythe2050s,butiftemperaturesexceed3ºC,allpresent-daycroppingareasformaize,milletandsorghumwillbeunsuitableforthosecrops(UNEP,2015).Itisunclearhowfutureclimatestresswillimpactdiseaseoutbreaks.Fusariumwilt,afungalsoil-bornediseasethatinfestsallpigeonpeagrowingareasineastandsouthernAfrica,requireseitherimprovedseedvarietiesofseedsresistanttothisdisease,oruseofextendedrotationsorexpensivechemicals(Shiferawetal,2008).TheIntergovernmentalPanelonClimateChangeestimatesthatthenegativeimpactsofclimatechangeoncropyieldswillbemorecommonthanpositiveones,withchangesincropyieldsduetoclimatechange,withthebulkofyieldchangesexceeding5–25%after2030(IPCC,2014).DroughtmortalityandwaterriskwillbethehighestinAfricaduetoclimatechangeimpacts,andAfricancountriesareincreasinglyrecognizingtheneedtoaddressagriculturaladaptationpressures,andpromoteclimate-smartagriculture.InasimulationofhowSub-SaharanAfricanagriculturewouldadjusttoa5ºCincreaseuptheyear2090,projectionsindicate24%declinesinthemeanaverageyieldsformaizeanda71%declineinbeanproduction,indicatinghowvulnerableAfricanagricultureistosignificantchangesinrainfallpatternsandtemperature(Thorntonetal,2011).ChangesinmanagementpracticesandimprovingtheadaptabilityandstrengthofseedsystemswillbecrucialtobuildresilienceandadaptationinAfricanagriculturalsystems.
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InAfrica,climateandenvironmentbenefitscanderivefrommultipleusesofpulsecrops.InTanzania,pigeonpeabiomasscanbeusedforfeedinglivestockorassourceoffirewood,therebyreducingfirewoodcollectionneedscarriedbywomenandchildrenandreducingdeforestationandlossofbiodiversity(Shiferawetal,2008).Alteringthetraditionalplantingmethodsofmaizeandbeanscaninfluencethenitrogenbalanceincroppingsystems.AstudyinCentralKenyawhichassessedtheeffectofsmallholdersshiftingfromasingleone-by-onerowsystemofalternatingmaizeandlegumes,toamodifiedtwo-by-tworowstaggeredarrangementfoundnitrogenbalanceswerenegativeinthemaize/beanandgroundnutscenarios,butneutralwithcowpeaastheintercrop,indicatingthenitrogenbenefitsofcowpeaintercropping(Mucheru-Muna,2010).Interventionsinthedrysavannah’sofNigeriaandNigeralsofoundmodifiedstrip-croppingofcowpeaandsorghum,withtheadditionoflivestocktoboostmanurenutrients,preventedthenutrientlossescausedbytheregion’straditionalfarmingsystems,andincreasedfarmerincomes(GatsbyCharitableFoundation,2014).Asustainabilitychallengeinglobalagriculturalproductionishowtoincreaseefficiencyonexistingagriculturallands,ratherthanextensivepracticeswhichpushproductionintoforestsandwetlands.InGhana,productionandyieldsofcowpeahaveincreasedwithgreaterproportionthanhectaresplanted,indicatingincreasedefficiencyinproduction.Thesetrendsarebeingdrivenbythedevelopment,release,availabilityandadoptionofqualityseedofimprovedvarieties;availabilityofmarketsandincreasingmarketdemandbyurbanconsumers;increasedprices,profitabilityandincentivesforfarmerstoadoptproductivityenhancingoptions,especiallytogrowandprotecttheircropsfrominsectpestattack.TheGhanaGrainsDevelopmentProjecthadconsiderableimpactoverthe1980sand1990s,helpingtoimproveyieldsthroughbettervarieties(19weredeveloped),agronomic,grainstorageandseedproductiontechnologies,betterseeddistribution,andextensionservices(Rusikeetal,2013).Giventhecurrentlowratesoffertilizeruse,climatechangemitigationcanbemaximizedwithsustainableintensification(e.g.,betterproductivityandreducingdeforestationpressure)andimprovedsoilcondition(e.g.,carbonsequestration).Improvementsinseedsandagronomicmanagementarefoundationaltocapturingtheseopportunities.
3.2.3SocialThesocialdimensionsofpulseproductioninAfricaincludesfoodsecurityandlivelihoods,householdbenefits,diversifieddietsandnutrition,andgenderaspects.NutritionandfoodsecurityNutritioniscloselylinkedtoincomeinSub-SaharanAfrica,andinmanyruralareas,alargeportionoffamilyincomecanbedirectedtowardsfood.Foodsecurity,livelihoods,householdbenefitsandnutritionareoftenquiteinterlinked.InSub-SaharanAfricathe
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cowpeaisthemostconsumedpulse,followedbychickpeaandpigeonpea,onapercapitabasis,butthereareregionalvariations.Rwandahasthehighestpercapitaconsumptionofcommonbeansintheworld,alongwithBurundi,UgandaandEasternDemocraticRepublicofCongo(Rusikeetal,2013).InRwanda,beansprovide32%ofcaloricintakeand65%ofproteinintakeintheaveragediet,whileproteinfromanimalsourcesonlyaccountsfor4%(Asare-Marfoetal,2011).Rwandansconsumeroughly29kgofbeansperyear,morethandoublethatofneighboringUganda(SPIA,2014).Otherdataindicatesthat80%ofthepopulationconsumesbeansdaily,makingRwandaoneofthehighestbeanconsumersintheworld(Bertietal,2011).Resultsfromalarge-scalehouseholdsurvey5in2011indicatesthat87.9%offarmhouseholdsinRwandacultivatebeansaspartoftheircroppingsystem,andyetofthe708householdssurveyed,77%reportednotgrowingenoughbeansfortheirneeds,andoftenranoutafewmonthsafterharvest(ibid).Otherhouseholdsurveyresearchindicatesthatastheshareofimprovedbeanseedsplantedincreased,householddietarydiversityscoresincreased,showingaclearrelationshipbetweennutritionandimprovedseedadoption(LarochelleandAlwang,2014).InEthiopia,pulsesareculturallyessentialtothediet,basedonreligiouspracticesoffasting,whichdependonalternativesourcesofproteinwhenalmosthalfthepopulationdoesnotconsumemeat.Aschickpeahasanaverageof22%protein,theyareamoresustainablealternativetomeat.Thus,USAID/FeedtheFutureandPepsiCoareworkingwiththeUnitedNationsWorldFoodProgramme(WFP)onapilotprograminEthiopiatoimprovetheproductionofchickpeasbybuildingthecapacityoflocalfarmers,establishingdripirrigationsystems,andsupportinglocalmillers,processors,andpackers.CalledEnterpriseEthioPEA,thiseffortsupportstheEthiopiangovernment'sagriculturesectordevelopmentplansandaimstodramaticallyincreasechickpeaproductionbyimprovingyields,productionandavailability.WhileEthiopiaisAfrica'slargestproducerofchickpeas,thereremainshighpotentialtoincreaseyieldsandimprovequality.Theprojectintendstoenablenearly10,000Ethiopianfarmerstoseeatwo-foldincreaseinchickpeayieldwithimprovedpracticesandirrigation,andtodevelopalocallysourced,nutrient-rich,ready-to-usesupplementaryfoodtoaddressmalnutrition.TheprojectalsoseekstoscaleupandstrengthentheEthiopianchickpeasupplychain,forbothdomesticandexportmarkets.InTanzania,nutritionalaspectsofdrylandlegumessuchaspigeonpea,chickpea,andgroundnut,arenotedfortheircontributiontohelpovercomenutritionaldeficienciesduetodietslackingproteinsandoils,particularlyamongpoorfamiliesunabletoaffordmoreexpensiveanimal-basedfoods.Pigeonpeasprovideavitalsourceofproteinforpoorfamiliesandprovidecashformarginalfarmersinsemi-aridTanzania(Shiferawetal,2008).
5708householdsinRwanda’sNorthernandSouthernProvinces,and743womenand674children.
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InKenya,theshareofsubsistenceproductionandconsumptionrangesfrom60-70%forbeansandcowpeas,ascomparedtoonly20%forcommercialgrainlegumessuchassoybean.InKenya,cowpeaisimportantforfoodsecuritybothasamajorleafvegetable(itcontainsmoremineralsandnutrientsthanmostothervegetables)andasagrain,andissoldinbothformstourbanmarkets.Similarly,inGhana,cowpeaisvaluedforfoodsecurityandacashcrop,with32%ofcowpeaproducedforsubsistenceproductionandconsumption.Thecowpeadrygrainisadailystapleforthemajorityofthepopulationandthegreenleavesofcowpeaareeatenasvegetables.Thedriedhaulmsareusedaslivestockfeed.InEasternDRC,commonbeanisthesecondmostimportantstaplefoodaftercassava,and50-80%ofcommonbeanproductioniscultivatedbysmallholders,usuallyintercroppedwithcassavaandmaize.InRwanda,commonbeanisthefirstmajorcropprioritizedon35%ofplots,andisthemostimportantlegumeforhouseholdconsumptionandforearningcashincome.Infact,itisoneofthemostimportantcashcropsformanyruralhouseholds.InNigeria,56%ofcowpeaproducedissubsistenceproductionandconsumption(Rusikeetal,2013).FoodsecurityanddiversityGrainlegumesaddedintothedietarefoundtocontributeimportantenergy,proteins,minerals,andBvitamins.Whenconsumedwithcereals,pulsescontributeproteins,mineralsandBvitamins,aswellastheessentialaminoacidlysine,whichincreasesthequalityofprotein.Whenaddedtorootandfruitstaples,theyraisetheproteincontent.Whenenergyandproteinarebothdeficient,leguminousoilseedscanplayanimportantroleinimprovingdiets.Legumeleavesarealsoimportant,astheyprovidesourcesofB-caroteneandvitaminC,aswellasmorefolicacid,calciumandirontoameal(deJager,2013).Thediversityintypesofproductionsystemswillinfluenceyieldratesorfarmeradoptionoftechnologies,suchasimprovedvarietiesorrotations.InRwanda,intercroppingreducesproductivity,whereasinUganda,nostatisticallysignificantyieldimpactisseenwithintercropping.InUganda,beansarefrequentlygrownwithbananas,whereasinRwanda,beansaremorelikelytobeintercroppedwithcropssuchasmaize,tomatoes,eggplants,andpeas(Larochelleetal,2014).Despitethevariationinwhetherfarmersfullyadoptedoronlypartiallyadoptedimprovedbeanvarieties,roughly22%ofRwandanhouseholdswouldbefoodinsecureintheabsenceofimprovedbeanscomparedtoonly13%afteradoptingimprovedvarieties(LarochelleandAlwang,2014).Theresearchfindingsindicatethattheimpactofimprovedseedvarietiesonfoodsecurityarebelievedbemorepronouncedthanthoseonbeanfarmincome.Thisisbecauseadoptionofimprovedvarietiesinfluencesfoodconsumptioninotherwaysthanjustthroughfarmprofitability.Authorsnotethat,frequently,improvedvarietieshaveshorterproductioncycles,whichcanfreeuplabourandallowhouseholdmemberstobeengagedinadditionalincome-generatingactivities.
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Further,higherproductivitycanalsoallowhouseholdstofocusonothercrops,increasingdiversityinagriculturalproductionfoodconsumption(ibid).Researchapplyingeconometricapproachestoestimateprofitabilityatthehouseholdlevelandatthemarketlevel,accountingforthedifferencefromthecounterfactual,wasusedtoestimatetheimpactofimprovedbeanvarietiesreleasedsince1998onfoodsecurityinRwandaandUganda.Researchfindingsarethatfoodinsecuritywouldhavebeen16%higherinRwandawithouttheintroductionofimprovedbeanvarieties.Foodinsecuritywouldhavebeenanegligible2%higherinUganda(Larochelleetal,2014).Improvementsinbeanvarietiesonbothcountrieshaveoccurredthroughgeneticenhancementsorseedselectionprocesses.TheInternationalCenterforTropicalAgriculture(CIAT),ResearchAgricultureBureau(RAB)inRwandaandUgandaNationalAgriculturalResearchOrganization(NARO)haveworkedtocreate46improvedvarietiesinRwandaandasignificantnumberinUganda.InRwanda,CIAT-improvedvarietiesaccountedfor15%oftheareaplantedtobeansby2003(LarochelleandAlwang,2014).Povertywouldhavebeenabout0.4%and0.1%higherinRwandaandUgandarespectively,intheabsenceofvarietalimprovementstothisvitalsubsistencecrop(SPIA,2014).InUganda,theadoptionofimprovedbeanvarietiesbytheNationalAgriculturalResearchOrganization(NARO)andpartnersovertenyearswasfoundtobelessthan15%ofhouseholds,primarilyduetolimitedaccesstoseedofimprovedvarieties(Kalyebara,2005).Incontrast,Kenyahasseenmuchhigherratesoffarmeradoptionofimprovedseed,with80-90%ofthefarmersgrowingcommonbeaninKenyausingimprovedvarietiesdevelopedundertheGrainLegumeProjectimplementedinthe1980s(Rusikeetal,2013).Bio-fortifiedseedandfoodsecurityBio-fortifiedseedhasbeenlargelypromotedinRwandatoimprovenutritionandyields.Bio-fortificationinvolveseitherbreedingcropstoincreasetheirnutritionalvalue,whichcaninvolvegeneticengineering,orthroughconventionalselectivebreeding.Thebio-fortifiedbeanseedsdevelopedinRwandaarenon-GMOproducts,asthevarietieswereselectedfromnaturalvariationinthebeancollections.Asaresultoffoodinsecurity,householdsarealsovulnerabletomalnutrition,resultinginRwanda’sveryhighrate(43%)ofstuntingamongchildrenundertheageoffive.AcornerstoneofRwanda’sAgricultureSectorStrategicPlan(PSTAIII)isinterventionstoimprovenutritionandhouseholdvulnerability,andoneofthesixstrategicprioritiesisaprogrammetosupportbio-fortifiedfood,focusingonbeansfortifiediniron,vitaminArichmaize,orangesweetpotato,andfortifiedcassavaandrice.Theproductionandconsumptionofbio-fortifiedseedsistobeexpanded(Rwanda,2013).ThePSTAIIIseekstoincreaseproductionofbeansfrom452,828MTin2013to749,381MTby2017-2018.ThePSTAIIIalsoidentifiestheneedtomaintainaNationalStrategicFoodReserve,prioritizingmaizeandbean.
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FivedistrictsofRwanda’sSouthernProvincethatwerestruckwithcassavabrownstreakwereprioritizedbythegovernmentforinterventionsbyHarvestPlusandpartnerstodeliver165,000metrictonesofqualityseedof‘highiron’beanvarietiestothesefarmers.By2014,about800,000ofRwanda’stwomillionbeanfarmerswereusingironenrichedbiofortifiedbeanvarieties,whichalsohavehigheryieldsthanlocalvarieties(HarvestPlus,2014).RwandanAfro-popstarsreleasedasonginlate2014,withsupportfromHarvestPlus,toextolthevirtuesofplantingandeatingiron-fortifiedbeans,fornutritionalhealth(See:https://www.youtube.com/watch?v=fo6449Rd3I0).GenderGenderaspectsofpulseproductionrelatesprimarilytowomen’sinvolvementinpulseproductioncommercially,tofeedfamilies,andtobenefitfromincomederivedfrompulsesales.InKenya,cowpeaisgrownprimarilybywomen.WhilewomendonottakepartinthevaluechainbeyondproductioninKenyaandRwanda,inGhanacowpeasarecultivatedbybothmenandwomen,butdominatedbywomeninpost-harvestprocessingandmarketing.CommonbeanisgrownbymostfarmersthroughoutRwanda,althoughtraditionallycommonbeaniscultivatedbywomen.InNigeria,cowpeaiscultivatedbywomenandmen,andgenderequityforwomenismoreapparentwhenwomencanmakedecisionsonquantitiessoldandthoseretainedforhouseholdconsumption(Rusikeetal,2013).AgenderframeworkdevelopedforpulsegrowingdistrictsofEthiopiaindicatesfivegender-relatedpillarsforimprovingpulseproductivity/managementandnutrition,includingknowledge,skillsandtrainingacquisition,participationinproductionanddecision-making,accesstoandcontroloverresources,andpolicydevelopment.Researchersidentifiedtheimportanceofconsideringgenderdifferencesinaccesstoland,technologiesandotherstrategicresourcesinpulsecropproductivity/managementandrelatedinterventions(Henryetal,2016).
3.2.4EconomicAgricultureistheeconomicmainstayofSub-Saharancountries,employingabout60%oftheworkforceandprovidinganaverageof30%oftheregion’sgrossdomesticproduct.EconomicbenefitsofaddingpulsesintorotationTheeconomicimpactsofincludingpulsesinrotationsareinfluencedbyavarietyoffactors,includingfarmerperceptionandknowledge.InUganda,theeconomicbenefitsofproducingpulsesisfoundtobeovershadowedbyfarmerperceptionsofmarketabilityofcertainproducts,unfamiliaritywithpulses,concernoverhighlabourcoststoproducepulses,orotherreasons.FindingsfromEasternUgandaindicatethatdespitepigeonpeaandmucuna(VelvetBean)beingprofitablewhengrowningoodsoilsandgroundnuthavingthepooresteconomicperformanceofcropsgrowninrotationwithmillet,farmerevaluationsindicatedastrongerpreferenceforgrowinggroundnut,whiletherewas
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disinterestingrowingpigeonpeaandmucuna.Thisisthoughttobeduetounfamiliarityofpigeonpeaasafoodormarketcropandconcernsoverhigherlabourcostsingrowingmucuna,whichisoftengrownasagreenmanure/covercrop(Ebanyatetal,2010).InCentralKenya,theimportanceofimprovedmethodsofintercroppinghadsignificanteffectsoneconomicperformanceofbothgrainandlegumecrops.OnestudyoversevengrowingseasonsinCentralKenyawithsmallholdersassessedtheeffectofshiftingfromasingleone-by-onerows,alternatingmaizeandlegumes,toamodifiedtwo-by-tworowstaggeredarrangement.Legumeproductionwasalreadyoccurringinthissystem,sofarmerswerealreadyfamiliarwiththecrops.Thismodifiedintercroppingarrangementdidnotincreasetheamountoflegumeplanted,butdidshifttheintercroppingpatternswithmaize,commonbeans,cowpeaandgroundnut.Findingswerethatsmallholdersproducingmaizewereabletoincreasenetprofitabilityby40%onfertilesoilsbyapplyingthemodifiedstaggeredarrangementwithbeans.Onthelessfertilesoils,groundnutandcowpeawerebetteradapted,andthestaggeredarrangementsystemincreasednetbenefitby12–37%(Mucheru-Muna,2010).FarmersurveyresultsinEthiopiaindicatethatsmallholdersgrowvariouscropsfortheirownconsumptionand/oreconomicbenefits,andpulsescontributesignificantlyforthe7.9millionfarmersproducingthem,mostofwhomaresmallholders.Fababean,chickpeas,fieldpeas,andredharicotbeanscomprisethelargestproduction,andwhiteharicotbeanandlentilisalsogrown.Fababeanaccountsforthelargestproduction,at8.3millionquintals,whilechickpeaisthenextmostproducedpulse,at4.6millionquintals.PulsesgrowninEthiopia’s2014-15Meherseasoncovered12.41%ofthegraincroparea(Ethiopia,2015a).InNigeria,farmersrankcowpeaveryhighforcashfarmincomesandallocateitasignificantproportionoftheircultivatedarea.Farmerssellcowpeatobuystaplecereals,butalsoconsumecowpeathemselves.Inaddition,farmersrearinglivestockusecowpeahaulmsashaytofeedanimals.CowpeaprocessingisalsodominatedbyhouseholdenterprisesandSMEs,contributingtohouseholdincome(Rusikeetal,2013)Findingacroprotationsequencethatproducesthehighestreturnoninvestmentcanbeanimportantindicatorofwhetherfarmerpracticeschangetoincludepulsesoverthelongterm.InBenin,betterlaborproductivitywasmaximizedwhenlegumeswereintercroppedwithtraditionalsmallholderyamproductionoccurringinshiftingcultivationsystems.Thus,netrevenueandreturnoninvestmentwereachievedinyam-basedsystemswithlegumes,withsignificantreturnsoninvestment(Malikietal,2012).Whilemaize/cowpea,sorghum/cowpea,andmaize/sorghum/cowpeacropcombinationshadthehighestgrossmarginsperhectareinthefadamasofSouthernGuineaSavanna,NigerState,Nigeria,thereturnoninvestmentwasfoundtobehighestwithspinach,okraandsorghum/cowpea(Lawaletal,2010).
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EconomicbenefitsfromimprovedseedTheeconomicimpactsofCGIAR-supportedimprovedbeanvarietiesinRwandaandUgandawasassessedthroughtheCGIAR-supportedproject‘DiffusionandImpactofImprovedCropVarietiesinSub-SaharanAfrica’(DIIVA).Economicimpactswereestimatedbasedonthechangeinfarmprofitamongadopterscomparedtonon-adoptersforimprovedversustraditionalvarieties,takingintoaccountadditionalrevenuesandproductioncosts,includingseedsandincreasedlaborrequirements.FindingsestimatethatRwandanhouseholdswhichplantedimprovedvarietiesincreasedtheirproductionby42kg/yr,therebyincreasinghouseholdrevenuebyUS$74.Similarly,Ugandanhouseholdssawproductionincreasesof40kg/yrtherebyincreasinghouseholdrevenuebyUS$63(SPIA,2014).Theaverageyieldgainoverlocalvarietiesfromadoptingimprovedbeanvarietieswasfoundto53%inRwandaand60%inUganda(ibid).LarochelleandAlwangreferencea2003studythatfoundtheRwandanyieldgainsoverlocalvarietiestobe900kg/ha,whichisalsoattributedtotheshiftfrombushtoclimbingbeansintheNorthernregionofRwanda.EstimatesidentifiedthiscontributedanannualadditionalvalueofUS$8.7milliontotheeconomy,fromtheadditionalproductionof28,888tons(LarochelleandAlwang,2014).AnotheranalysisinUganda,completedadecadeearlier,estimatingthenetpresentvalueoftotalbenefitstoUgandafrompublicinvestmentsinbeanresearchanddevelopmentestimatedittobeUS$19milliondollarsperyear,withaninternalrateofreturnontheinvestmentof41%(Kalyebara,2005).Insemi-aridTanzania,averageestimatedyieldgainsfromgrowingfusarium-resistantpigeonpeavarietieswasabout67%,withfarm-levelbenefitsresultingin80%highernetincomeperhacomparedtousingnon-diseaseresistantseeds(Shiferawetal,2008).Theaveragemarketedsurplusofadoptingfarmersin2003wasabout716kg/yr,whilethosegrowinglocalvarietiessoldonly349kgofpigeonpeas.Thisincreaseinyieldandreductioninvariablecostswasalsofoundtobenefitthegovernmentthroughincreasedtaxrevenuesreceivedfromproducersandconsumers,basedonatotaleconomicsurplusofUS$6.1million,withaninternalrateofreturnof32.2%.Pigeonpeaaccountedforabout50%ofthecashincomesofthesamplefarmersduringtheyear,demonstratingthekeyroleofthiscropassourceofcash.Adoptionofnewvarietiesmayalsogenerateothernon-quantifiedbenefits,thoughthesewerenotquantifiedbytheresearchers(ibid).TheCGIARestimatedthepovertyimpactsofimprovedvarietiesinRwandaandUgandain2011byaggregatinghouseholdleveldatatothemarketlevelandestimatingthedifferencesbetweenthecounterfactualandactualincomedistributions.Whilethemagnitudeofpovertyimpactsfromimprovedvarietieswerefoundtoberelativelysmall(between0.4and0.1%),thestudyfoundthatsomehouseholdsinbothcountrieswereabletoescapepovertybyadoptingimprovedbeanvarieties(Larochelleetal,2014).Itisnotedthatthemethodsusedtoestimatepovertyimpactsarelimited,asonlythegrowingyearof2011wasconsidered,andadistinctionwasmadeinwhichreleasedatestoinclude,suchthatthemeasuredadoptionratedroppedbyhalf,thusreducingpotentialimpactsofcropvarietaltechnology(ibid).
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TheMalawiSeedIndustryDevelopmentProject,focusedonprovidinghigh-qualitygroundnut,pigeonpeaandbeanseeds,wascarriedoutwiththeInternationalCropsResearchInstitutefortheSemi-AridTropics(ICRISAT)andMalawigovernment,withsupportfromIrishAid,todiversifypredominantlymaizeandtobacco-basedproductionsystemsandaddressfoodinsecurityfeltbyfarmersandboostfarmincome.Since2008,directengagementalongtheseedvaluechainhassoughttodevelopthecapacityoflocalseedcompaniesandseedsavingbyfarmers,improvethepolicyenvironmentfortheseedtradeandcommercialdistributionnetworkforimprovedseeds,andengagewithfarmerassociationsthatreachsmallholdersandcontractfarmers.ThesuccessoftheprojectinboostinglegumeproductionandtherebyimprovingfoodsecurityandfarmincomehasresultedinlegumesnowbeingakeyfeatureoftheNationalExportStrategyandMalawi’sPresidentialInitiativeonPovertyandHungerReduction,whichhasaspecialcomponentonlegumes(Sichalatal,2013).Theresultsdirectlyreachedatleast2.2millionhouseholdsinprovidinglegumeseed.Theprojectedimpactofseedprovisionincludescoverageof128,000haofland,representingroughly33%ofcroppedareaundergroundnutandpigeonpeainMalawi.ResultsalsoincludedestimatedrevenueincreasesofUS$54millionfromseedandgrainsalesintothecasheconomy,andUS$30millionworthofgrainfromlegumesconsumedon-farm,accordingtoagovernmentspokesperson(ICRISAT,2014).Public-privatepartnershipshavebeeninstrumentaltolinkmarketdevelopmentandpolicycoherenceforimprovedseeduptake.ICRISAT’sMalawiSeedIndustryDevelopmentProjectcreatedapartnershipwiththeMalawiGovernment’sFarmInputsSubsidyProgramme(FISP),topromotecropdiversificationandincreaseuseofcertifiedseedamongfarmers.Duringthe2010-2011farmseason,theFISPprovidedsmallholderfarmerswithvouchersfor2kgofcertifiedimprovedlegumeseedsfromparticipatingmerchants,andreached395,000farmersafterfouryears(Sichaletal,2013).From2000,Nigeriahasexperiencedincreasedplantedareaandproductivityofcowpeaduetoimprovedseedvarieties,distributionofinsecticides,storagesystemsincludingthePurdueImprovedCowpeaStorage(PICS)bags,andstrongmarketsandprices.Effortstopromoteimprovedandnewvarieties,andseveralrelateddevelopmentprojectsfocusingonimprovedcrop-livestockintegration,includingPurdue,BMZ,AGRAandGatsbyprojects,hadsuccess.However,cowpeaproductionstilldoesnotmeetdemand,andNigeriaimportscowpeaduringsignificanttimesoftheyear(Rusikeetal,2013).TheAllianceforaGreenRevolutioninAfrica(AGRA),andtheAllianceforCommodityTradeinEasternandSouthernAfrica(ACTESA),arefacilitatingpositivechangesintheregulatoryregimesofindividualcountriesandregions.ThisworkenablesglobalinitiativesseekingsustainedandinclusiveagriculturalgrowththroughbetteralignmentbetweengovernmentandprivatesectorinterestsliketheNewAllianceforFoodSecurityandNutritionandGrowAfricatobesuccessful.Further,ACTESAhasbeenworkingtodevelopseedsectorpolicythatisharmonizedacrosstheregion.
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BarrierstotechnologyandimprovedseeduptakeAnecdotalevidenceinRwandapointstothevalueofprovidingfarmersinRwandawithlowcostmicrobialinoculantstoboostnitrogenfixation.OneAcreFund,workingwithwithN2Africa,foundthisinterventioncutfertilizerusebyfarmersinhalfwhilemaintainingyields(whichwouldcarrysignificantenvironmentalbenefitsaswell).TheinoculantsonlycostamodestUSD$1perfarmerandresultedinadoublingoffarmerprofitsandreducedrelianceonchemicalfertilizer.OneAcreFundisbuildingonthisRwandanexampletoexpandthisprogrambothwithinRwandaandinothercountriesinEastAfrica(Guerena,2015).ObservationsfromtheCGIARDIIVAprojectpointstoevidencefromUgandathatshowedthatpoorerbean-producinghouseholdsarelesslikelytoadoptthenewbeanvarieties,whichtheCGIARsuggestscouldbeovercomethatifpoorerproducerscangainaccesstobetterbeantechnologies.ThisassertionmaybebasedontheexperienceinRwandaofmoreavailableagriculturalextensionservicesinmostregionsofthecountry,whichfavorsthespreadofnewvarieties(SPIA,2014).However,LarochelleetalalsonotethatlowsalespricesofbeansinRwandaalsoattenuatethepovertyimpactoftechnologyandimprovedbeanvarietyadoption(Larochelleetal,2014).FurtherconstraintsonRwandanbeanproductionincludethelackofsupplysystemsandlackofcoordinationinthemarkets(suchasmarketinformationforfarmersandlackofstandardmeasures),limitedpost-harveststoragefacilities,thehighopportunitycostofland,competitionfromcropsthataremoreprofitable,andthelimitedtechnicalandfinancialcapacityoffarmerstoorganizecooperatives(Rusikeetal,2013).Despitethesignificanteconomicbenefitofincreasedincomefromfusarium-resistantpigeonpeavarietiesgrowninsemi-aridTanzania(incomeincreasesof80%),manyfarmersinthegrowingareasdidnotadoptthedisease-resistantvarietiesmainlyduetoinadequatelocalsupplyofseedandaccesstoagronomicinformation.Asseedrequirementsforpigeonpeaaresmallandfarmersreportedbeingabletobuytherequiredseed,accesstofinanceandcreditwasnotalimitingfactorinpursuingdisease-resistantpigeonpeaseed.Findingsindicatedthatparticipationininformalseednetworks,on-farmvarietyselection,farmsizeandownershipofhouseholdtransportassetsincreasedthelikelihoodoffarmerstopursueimprovedseed(Shiferawetal,2008).ExportdimensionsInMalawi,MozambiqueandZimbabwe,cowpeavaluechainsaredominatedbyasubsistenceproductionandconsumptionpathway.InGhana,excessdemandforcowpea,groundnutandsoybeaninGhanadrivescrossbordertradeflowsalongexportcorridorsfromfoodshedsinTogo(Northernpart),BurkinaFaso(PouytengaandBobo-Dioulasso),Benin,NigerandCoteD’Ivoire(Korhogo).Becausemostofthecowpeasenteringcommercialtradearedirectlyconsumedbyhouseholdsasafoodstaple,thebulkofcowpeasaremovedfromthesurplusproducingareastoconsumptioncentersby
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tradersviatruck.Thereisnoformalindustrialprocessingofcowpeaandlargetradersdonotbuycowpeaunlesstheyareprocuringforlargescaleprocessorswhentheygetcontractstosupplycowpea-maizeblendedflourtotheWorldFoodProgram‘PurchaseforProgress’whichdistributesitthroughschoolandrefugeefeedingprograms(Rusikeetal,2013).UgandahasbeenaconsistentnetexporterofdrybeanstoeasternandsouthernAfrica,andyetadoptedratesofimprovedseedislowerthaninRwanda.Incontrast,Rwandahasonlyrecentlyenteredthebeanexportmarketin2005,andcontinuestoimportdrybeansasneededtomeetdomesticdemand,fluctuatingbetweenbeinganetimporterandanetexporterofbeans(Larochelleetal,2014).TanzaniaisoneofthemajorgrowersandexportersofpigeonpeaineasternAfrica,exporting30,000–40,000tons/yeartoIndia(Shiferawetal,2008).Promotingexportcropsthatdonotcompetewithdomesticfoodproductionisascrucialforfoodsecurityasitisforrealizingeconomicbenefits.Rwanda’sPSTAIIIprioritizesFrenchbeanforimprovedproductionforexportmarkets(Rwanda,2013),whichmaybestrategicallybeneficial,asproductionofFrenchbeanislesslikelytocompetewithfoodcropsfordomesticuse,andalsomaycommandhigherprices.HoweverRwandamayneedtoimportmorepreferredpulsecropstomeetdomesticdemand.FarmersinRwandaarenotedforhavinghigherunitproductioncostscomparedtogrowersinDRCandUganda,makingRwandancowpeauncompetitivepricewisewithgrowersinneighboringcountries(Rusikeetal,2013).Rwandamayneedtokeepdomesticcowpeaproductionservingdomesticdemand,orenticefarmerstomoveintoexportcropsthatcanbesoldatmarginswellaboveRwanda’simportneeds.Therisk,however,isdecreasedfoodsecurityifmarketdynamicsorpriceschange.Afour-yearprojectseekingtocreatenewbusinessmodelsforsustainabletraderelationshipsinwhitepeabeanproductioninEthiopiademonstratedthefeasibilityofbuildingproductionandeconomicreturnsforanexportcrop,withoutimpactinglocalfoodproduction.WhitepeabeansarenotwidelyconsumedlocallyinEthiopia,astheyarenotpartofthetraditionaldiet.Beanproductionisashort-durationcrop,well-suitedtothelowrainfallconditionsintheregions,andprovidesmuch-neededcashduringtheleanertimeoftheyear,betweenSeptemberandMarch.Farmersreceivedtrainingonimprovedpractices,includinguseofimprovedseed,plantingrowsatspecificdensities,timelyweeding,harvestingandin-fielddrying,threshingoncanvasandnotontheground,andcleaningseed.Farmerswerealsoabletoaccessmicro-financeforbuyingimprovedseed,withpaybackprovisionsattheendofthegrowingseason.Resultswerestrong:farmingfamiliesearnedabouttwiceasmuchsellingwhitepeabeansforexportthantheywouldhaveobtainedfromsorghum,thesecondmostcommonlygrowncropintheregion.Atotalof4,746familyfarms(and24,000familymembers)increasedtheirprofitbyUS$164-$227perhousehold,andmorethandoubledyields.Theincomefrombeansrepresentedasignificantportionofhouseholdincome(15–20%)andprovidedfamilieswithameansofbuyingcheaperfoodinthelocalmarket.Theirincomefrom
45
beansincreasedfromUS$160to$230onanaveragehalf-hectareplot.Bytheendofthefouryears,theprojectsupplied15,000farmerswithimprovedseed,productivityincreasedfrom0.7MT/hato1.4MT/ha,diseasepressureswerereduced,andeffortswithUKretailersforsupplychaindevelopmentandexportmarketaccesswerematured.However,theimpactandoutcomesofthesupplychainandmarketaccessinterventionsoftheprojectwereweakenedbydrought,personnelchangeswithintheUKpurchasingcompany,economicrecession,andchangestotheEthiopianbeansupplychainwiththecreationofanewcommodityexchange,whichblockeddirecttradingrelationships(Ferrisetal,2012).
4. A framework: evaluating multiple benefits of pulse production Theframeworkbelowisintendedtodefinetheelementsofsustainabilitytobemeasuredorevaluatedinanygivencontext,giventhediversitybetweencroppingareasandgeographiccontextsofsuitablepulsegrowingareas.Itisalsointendedtoprovideameanstoevaluatethepotentialsustainabilitycontributionsofpulsesshouldtheybebroughtintoacroppingsystem,orasameanstoincreasecroprotations.Thedevelopmentoftheframeworkisbasedontheliteraturereviewandtwocasestudiesinthisreport.Itisnotintendedtoreplaceaproductionstandardorproductcertificationscheme6thatproducerscouldapplyattheproductionlevel,butwouldcertainlycomplementandaddtosuchperformancemeasures.Eachcriterionorkeyelementcontainsasetofquestionstoguideevaluationofthesustainabilityofinterventions,includingcommontrade-offsthathavebeenobserved.Thequestionsshouldbeadaptedtolocalcircumstancesortotheappropriatescale,andareintendedasastartingpoint,ratherthanacompletesetoffilterstotestinterventionsagainst.Thisframeworkseekstoidentifythescalesatwhichsustainabilityattributesofapulsecrop,oraddingpulsesintorotations,canbeunderstoodandevaluated.Theenvironmental,socialandeconomicbenefits(andrisksortrade-offs)ofpulseproductionoccuratvariousscales(refertoFigure3).Ofcourse,sustainabilityattributescanoccuratmultiplescales,suchasincreasedincomebenefittingfarmersandregional/nationaleconomies,ornitrogenfixationincreasingcerealcropyieldsandreducingafarmer’srelianceonfertilizerwhichalsocarriesglobalbenefitsthroughreducedN2Oemissions.Effortstoincreasepulseproductionwillbewellservedifaccompaniedbymeasurestoevaluateenvironmental,socialandeconomicbenefitsatallrelevantscales.
6ExamplesincludetheSAN’sSustainableAgricultureStandard,GLOBALG.A.P.andothers.
47
Table 2: Summary of criteria and guiding questions to evaluate the economic, social and environmental benefits of pulse production
Environment Criterion or key
attribute Question to guide evaluation of impact/benefit Sources/case study elements + Trade-offs
Ability of pulse crop to offset fertilizer
needs within cropping system
• Choiceofthepulsecrop–basedonnitrogenfixation
rates,marketdemand,farmerfamiliarity,etc.
• Doesthecropsequenceintherotationensure
maximumtransferofnitrogentosubsequentcrop?
• Afterpulsesareaddedtotherotation,cantimingand
amountsoffertilizerbefurtheroptimized?
• Othernutrientmanagementstrategiesinplace?
• Arerhizobiuminnoculantssufficienttoensure
maximumnodulation?
• Canthetreatmentofcropresiduesbeoptimizedfor
nitrogenbenefits?
• Choiceofpulsecrophaseconomicandsocial
dimensions
• Theglobaleffectsofoveruseofsynthetic
fertilizersisofhighconcern(Canfieldetal,2010)
• Nitrogenforsubsequentfieldcropwell
documentedinSaskatchewanandsouth-eastern
Australia
Ability of pulse crop to offset or reduce
herbicide and pesticide use
• Canmanagementpracticesbemoderatedtooptimize
useofherbicides(notingthatatransitionperiodmay
benecessary)?
• Shiftsintillagerequirestransitiontime,herbicide
usemayincreasebeforethendecreasingover
time(hasbeenobservedinSaskatchewan(Brandt,
2010))
Diversify the cropping sequence
• Willtheadditionofapulsecropminimize
competitionwithothercropsformoistureand
nutrients?
• Diversifyingcroppingsequencescanbemaximized
todeliversocialandeconomicoutcomes,beyond
environmentalones.
48
• Doestheadditionofthepulsecropresultina
reductionoftillageandsoildisturbance?
Productivity improvements rather than area expansion
• Canyieldincreasesberealizedwithoutspatial
expansion,intheshort-andlong-term?
• Ethiopia’sriseinchickpeaproduction(Ethiopia,
2015b)
• Ghanacowpeaproduction(Rusikeetal,2013).
Applications to improve livestock
pasture
• Aretherelivestockfeedapplicationstoimprove
pasture?
• Howtomaximizenitrogenbenefitstosoil?
• Willitimprovenutritionalvalueforlivestock?
• Balancinglivestockproductionandfoodsecurity
throughpulses:Nuliketal(2013);Anderson,etal
(2007)
Ability of pulse crop to reduce GHG
emissions
• Reducedtillage(soilcarbonemissions)
• Reducedfertilizeruse(reducedenergyinputand
reducedN2Oemissions)andincreasedyields
• Canalteredrotationsorintercroppingsequencesand
timingmaximizenitrogenbenefits?
• Ifpulsefractionsarebeingconsideredin
manufacturedfoods,doesthepulsefractionensure
lowerGHGemissions?
• Indicationsarethatthemoreoftenapulsecropis
growninrotation,themoreGHGemissionsare
reduced(Lemkeetal,2007).
• Notethatpeaproteinfractionproductionwas
modeledtohavea60%decreaseinGHG
emissionsanda52%decreaseinnon-renewable
energywhencomparedtosoyproteinisolate
production.However,peastarchdoesnotcarry
suchbenefits;ratherGHGemissionsincrease.
Reduced non-renewable energy
use
• Reducedtillagerequireslessmechanizedequipment
useandfuel
• LCAanalysis:McWilliametal(2011)
• NotethattheLCAanalysisidentifiesdrypea
ethanoltonotbecomparabletowheatethanol,
souseinbiofuelsislimited
Water use efficiency and management
• Canthepulsecroptakeadvantageofresidual
moistureandnotcompetewithfoodcropsforwater
andnutrients?
• Nuliketal(2013):growingpulsesforforageinthe
shoulderseason,whenlandisfallowed
Improved soil management
• Minimizedpulsecroppingonhighlyerodiblesoils;
minimizeoreliminatetillage
• Isdependentonascertaininglocalconditions;
pulseshavebeenshowntoperformwellinpoor
soils,andcanimprovesoilsifmanagedwell
49
Social Criterion or key
attribute Question to guide evaluation of impact/benefit Sources/case study elements + Trade-off’s
Food security • Whatfurtherpracticeandyieldsimprovementsbe
madewithexistingpulsevarieties?
• Cantheintroductionofpulsesintocroppingsystems
benefitexistingfoodcrops?
• Ifintroducingapulsecropforexport,howtoensureit
doesnotnegativelyimpactlocalfoodsecurity?
• Howcanvaluechainsbesupportedanddeveloped
forasolidbalancebetweenimprovedmarketaccess
andincreasedon-farmpulseconsumption?
• InRwanda,householddietarydiversityscores
increasedasimprovedseedratesincreased
(LarochelleandAlwang,2014).
• Malawi(ICRISAT,2014)
The addition of pulses in the diet
boosts nutrition
• Pulsesprovidegreatestbenefittodietswhen
combinedwithotherfoods.Howtoeducate
consumersonthebestcombinations?
• Howtopromotepulsesasatastyandsustainable
alternativetomeat?
• deJager,(2013);Rusikeetal(2013)
• Pulsesregulatesbloodsugarlevels,improves
glycemiaandplasmalipids.Wheneatenwith
cereals,addsproteins,mineralsandBvitamins,
andessentialaminoacidlysine.Legumeleaves
canalsobeeaten.
The addition of pulses in the diet
reduces likelihood of disease
• Whatarethebestways(media,targets,message)to
promoteawarenessofthehealthbenefitsofpulses?
• Dworatzeketal(2013)andCanadianDiabetes
Association
• Reducesbloodcholesterollevelsand
cardiovasculardiseaserisk,lowersbloodpressure
Protein content of a cereal crop increases
• Whatarethespecificconditionsthatcanmaximize
theboostingofproteincontentofthesubsequent
(likelycereal)crop?
• Saskatchewanlife-cycleanalysis(McWilliametal,
2011)
50
following a pulse crop
• Thisfactorisnotindependentfromwatersupply
inthecaseofSaskatchewanlentiladdedto
rotations(Ganetal,2014)
Multiple uses of crop residues
• Cancropresiduesbeusedforalternativeuses,
withoutdecreasingnecessarybiomasstorestoresoils
andmaintainnitrogenbalance?
• Shiferawetal(2008)
Reducing pressures of increased meat
production
• Howtopromoteconsumerawarenessofhealthy
alternativestomeat,andincreaseuseoffractions?
• Addingpulsestolivestockdietsimprovespastures
andqualityoflivestock
• ImprovedforageandpastureintheUSGreat
Plains(Anderson,etal,2007)andIndonesia(Nulik
etal,2013)
Boosting nutritional content of
manufactured foods
• Canpulsefactionsbeeffectivelyincorporatedinto
processedfoods?
• Howcanthefoodindustrydevelopmarketlegume
productsgiventhehigherrawinputpricesoflegumes
vscereals?
• Importanttoensurepulseproductionforfractions
andexportmarketsdoesnotrisklocalfood
security
Increase global and regional production
of crops with climate adaptation capability
• Howcanaddingpulsesintorotationsnotcompete
withothercropsforwaterandnutrients,while
maximizingclimateadaptability?
• Canlocally-adaptedpulsevarietiesandvarietiesbred
foradaptabilitybepromoted?
Women’s role in production,
processing and sales
• Womenhaveameaningfulroleinthevaluechain,as
wellasmanagingprofitstofeedfamiliesand/or
supportincome-generatingactivities.Howcantheir
engagementbesupportedandpromoted?
• Insomecountries,women’sroleinpulsevalue
chainsdirectlyimpactsfoodsecurity,household
incomeandlivelihooddimensions
51
Getting the enabling environment right for
pulses
• Howtocreatetheresearch,technicalandextension
supporttoimproveproductionpractices?
• Howtopromotepartnershipstolinkfarmerstoviable
marketsandpromotetrade,withoutriskingfood
securityorincreasingdependencyonimports?
• Public-Private-Partnershipstomakethepolicyand
privatesectorconnection
• Arepulsesprioritizedinagriculturesectorplans?How
canbenefitsfrompulsesbeunderstoodbypolicy
makers?
• RwandaprioritizespulsesinAgsectorplan
• DespiteitssignificancetotheIndiandiet,
productionsupport,marketpricecontrolsand
importtariffshavenotbeenmaximizedfor
environmentalandsocietalbenefits
• Harmonizedseedsectorpolicy:Alliancefora
GreenRevolutioninAfrica(AGRA)+Alliancefor
CommodityTradeinEasternandSouthernAfrica
(ACTESA)
Economic Criterion or key
attribute Question to guide evaluation of impact/benefit Sources/case study elements + Trade-off’s
Lower fuel costs • Howcanuseofmechanizedequipmentbedecreased
orminimized?
• Argentinano-till(Lorenzatti,2006)
• Saskatchewan(McWilliametal,2011)
Labour productivity • Whatisthemostefficientwaytointroducepulses
intotheexistingrotationcycle,tomaximizelabour
use?
• Howcanchangesinlabourrequirementsmaximize
benefitstofarmers(e.g.timetocultivateothercrops,
providingreliablesourcesofincome)
• Argentina(Lorenzatti,2006)
• Rwanda(LarochelleandAlwang,2014).
• Benin(Malikietal,2012).
Increased income from added rotation
+ financial
• Howtoacropmixandrotationsequencewiththe
highestreturnoninvestment?
• Inregionswherepulsesareunfamiliarorknownrisks
arehigh,howcanfarmersreceiveassistance
(improvedpractices,improvedseed,low-interest
• Increasedinputcostsoffsetbyincreasedprofits
(Zenteretal,2002;McWilliametal,2011)
• FarmersdoubledincomeinIndiafromimproved
managementpractices(Shah,2011)
52
contribution of pulse crop
loanstooffsetrisk)toincreaselikelihoodof
incorporatingpulsesintotheirrotations?
• Variabilityinmarketpricingandpulsecroptype
canstronglyinfluenceprofitability(McWilliamet
al,2011)
• Pulsesincreaseincomeexceptwhenpulseprices
arelowandgrainandoilseedpricesarehigh(ibid)
Increased income from higher yield on
subsequent crop
• Howtodecreaseriskofnutrientcompetitionor
suppression,andmaximizethenitrogenbenefitsfrom
thepulsecroptothesubsequentcrop?
• GrainsinAustralia,USandCanada;yamsinGhana
• Therearedifferencesinyieldpossibilities
dependingonwhetherpulsesareintercroppedor
addedtorotations
Lower costs due to conservation tillage
or no-tillage practices
• Ifchangesintillagefrequency,lowerfueland/or
labourcostsarepresent.
• Herbicidesusemayincreaseasmechanizedtillage
isreduced.
• Maydependonsoiltypesandlocalizedconditions
Avoided costs of less soil, air and water
degradation
• Howcanlong-termbenefitsofpulseproductionbe
bestunderstoodineconomicterms?Avoidedcostsof
soilandecosystemdegradationcanbesignificant.
• Hardtoestimatethese.
• Life-cycleanalyseshelpframescopeandscale
(McWilliametal,2011)
Investments in crop research have high
rates of return
• Howcanresearchofimprovedpracticesandseed
bestbedisseminatedformaximumpublicandprivate
benefit?
• 1%levyonSaskatchewanpulsesalesand
investmentsmadebySaskatchewanPulse
Growers
• CGIAR(SPIA,2014)
Livestock forage system
intensification
• Howcanlivestockforagesystemintensificationoccur
withleastdownsiderisk?
• Dependentonmarketpricingandlabouruse
efficiencies
53
5. Applying the framework for decision support Theframeworkdefineselementsofsustainabilitythatcanguideevaluationoftheeconomic,socialandenvironmentalbenefitsand/ortrade-offsofpulseproduction,oraddingpulsesintocroprotations.Inordertobetterunderstandhowtheframeworkcanbeapplied,thissectiondefinesitsapplicationwithinthecontextofhypotheticaldecisioncases.Thesearereal-worlddecisionpointsthatthefoodsector,pulseproducers,orgovernments,arelikelytoengageinthepulseproductioncontext.Thesehypotheticalactionsteps(columns1and2inTable3)areadaptedfromNegra’s(2015)distillationofkeymessagesfromthescientificliteratureofrelevancetokeyaudiencegroups,whichisacomplementaryknowledgeproducttothisone,alsocommissionedundertheauspicesoftheInternationalYearofPulses.Thisapplicationoftheframeworktothehypotheticalactionstepsbelowisintendedasinitialguidanceonly,andpresentssomeoverarchingdecision-supportandquestionsforfurtherinvestigationrelatedtoqualitativeandquantitativeanswerstotestperformancealongkeyenvironmental,socialandeconomicindicators.Thesemustbedesignedtosuittheuniquecircumstancesinwhateverproductionregionisbeingevaluated,andsuitedtowhatevermanagementobjectivesmightalreadybeinplace(e.g.adherencetoaproductionstandard,adherencetonationallaws,etc.).Again,theframeworkisnotintendedtoreplaceaproductionstandardorproductcertificationscheme,butwilladddimensionsthatareuniquetothepulseproductioncontext.Theoverviewofframeworkelementsthatapplytoeachactionareainthetablesbelowarenotacomprehensivelistingofallthatwouldapply,butratherindicativeofthegeneralareastocover.Thisapplicationhelpsdefinehowsustainabilityattributesmustbetestedatthethreescales—productionlevel,regionallevelandgloballevel.Thisisintendedasarudimentarystartingpoint,andapplyingthisinrealcontextswouldrequireamuchfineranddetailedassessment,withdecision-supportguidanceforallcriteria/attributesnecessaryformeasuringperformanceagainst,andhowthosecriteria/attributesshouldapplyineachofthethreescales.Effectiveevaluationofperformanceandhowtobalancetrade-offscanonlybemadethroughmoredetailedassessment.
54
Table3:Applicationoftheframeworktofoodsectoractors(pulsemanufacturers,suppliersandtraders)
Potentialaction
Examplesofsub-
activities
Frameworkelementsthatapply
Scalestomeasureperformanceorimpact
Increa
seuseofp
ulsesinprod
uctlines
§ Boostcustomerdemandthroughawarenessraisinganddiversificationinproductlines
§ Increasetheuseofpulseflourblendedintomanufacturedfoods(fractions)
§ Increasemanufacturers’understandingofhowtousepulses.
Ø Environmental:Allenvironmentalcriteriaandattributesintheframeworkshouldbeevaluatedtoidentifywhichonesarerelevant,andatwhatlevelsinthesupplychaintheycanbetrackedorinfluenced(sourcingdirectlyfromaregionwillincreaselikelihoodofinfluencingproducersdirectly)
Ø Social:Same–almostallframeworkcriteriaandattributesshouldapply.Workwithsuppliersandproducerstoobtainperformancemeasures.
Ø Economic:Same–almostallframeworkcriteriaandattributesshouldapply.Workwithsuppliersandproducerstoobtainperformancemeasures.
Ø Production:Dopracticesintheproducingregionminimizeenvironmentalandsocialcosts,whilepromotingenvironmental(e.g.goodnutrientmanagementstrategies)andsocialbenefits(e.g.foodsecurity)?Isaproductionstandardinplaceorbestpracticesbeingapplied?
Ø Regional:Whatelementsofregionalvalueneedcanbeaccountedfor,suchaswateruseefficiencyandmanagement?Arefoodsecuritybenefitsandeconomictrade-offsminimizedattheregionalscale?
Ø Global:Doestheactionpromoteuseofnitrogen-richandprotein-richplantfoods,whiledisplacingordiversifyingfromnitrogen-depletingandprotein-richanimalfoods?Netreductioninnon-renewableenergyuseandGHGemissionsattheproductionlevel,andemissionsminimizedthroughoutthesupplychain?
55
Potentialaction
Examplesofsub-
activities
Frameworkelementsthatapply
Scalestomeasureperformanceorimpact
Sourcesu
staina
blyprod
uced
,highqu
ality
,traceab
lepulses § (company-level)
Developsustainablesourcingcriteria.
§ Buildmonitoringintobusinessoperations(e.g.,HACCP)
§ (sector-level)Agreeoncrediblesustainabilityindicators/standardsandverificationmechanismsthroughplatformsforcooperativemarketaction.
Ø Environmental:Docroprotationsmaximizenitrogenandnutrientmanagementoptionsformaximumyieldandmaximumlong-termsoilhealth?Areproductionstandardsorbestmanagementpracticesinplace?Whatcriteriainadditiontothestandardshouldbemeasured(e.g.fueluse,diversificationofthecroppingsequence,integrationoflivestock,etc.)?
Ø Social:Ifaproductionstandardisinplace,whatsocialcriteriaapply?Whatadditionalsocialcriteriacanbeattained(e.g.measuresfornutritionandfoodsecurity,genderequityinthesupplychain,consumerawarenessoftherangeofsustainabilitybenefits,etc.)
Ø Economic:Islabourproductivitymaximized,farmerincomeincreased,fuelandassociatedcostsdecreased?
Ø Production:Istheprovenanceknownandtraceabilityclear?Canenvironmental,socialandeconomicbenefitsbemeasuredattheproductionscale?Areeconomicbenefitsmaximizedattheproducerlevelfrombestmanagementpractices(technicalassistanceprovidedandpremiumspaidtofarmers)
Ø Regional:Canenvironmental,socialandeconomicbenefitsandtrade-offsbemeasuredinthesupplychain?Arewateruseefficiencyandmanagement,andnutrientmanagementoptimized?Adequateinvestmentsmadeinpost-harveststorageandmarketefficiency?
Ø Global:Increasedconsumerawarenessoftheenvironmentalandsocialbenefitsofpulseconsumption,includingcertifiedproducts?Netreductioninnon-renewableenergyuseandGHGemissions?Increasedplant-basedproteinavailability?
56
Table4:Applicationoftheframeworktopulseproducers(bothsmallandlarge-scale)
Potentialaction
Examplesofsub-
activities
Frameworkelementsthatapply
Scalestomeasureperformanceorimpact
Integratepu
lsesintofarm
ingsystem
s
§ Identify,acquire,anduseappropriatepulsevarieties,productionpractices,andmechanicaloptionstooptimizesystemproductivity.
Ø Environmental:Canthecropsequenceintherotationensuremaximumtransferofnitrogentosubsequentcrops?Howcanthetreatmentofcropresiduesbeoptimizedfornitrogenbenefits?Canyieldincreasesberealizedwithoutspatialexpansion?Canthepulsecroptakeadvantageofresidualmoistureandnotcompetewithfoodcropsforwaterandnutrients?
Ø Social:Wouldpulsescontributetoincreasedfoodsecurity?Howtobestpromotetheproteincontributionsofthepulsecroptothesubsequentcerealcrop?Howtooptimizecropresidueuse(trade-off:useforlivestockmaymeanlessreturntosoils)?Howcangenderbenefitsbemaximized(womenhavemeaningfulroleinsupplychainandmanagementofprofits)?
Ø Economic:Howcanchangesinproductioncostsbeunderstood(pulseproductionmaycarryhighercosts,butthenetreturnoninvestmentaftertheharvestissoldmaybehigherthanforcerealcrops)?Isthereincreasedincomefromintroductionofthepulsecropinrotation?Howcanlabourproductivitybemaximized?Cantheriskofnutrientcompetitionorsuppressionbetweencropsbeminimized,inordertomaximizethenitrogenbenefitsfromthepulsecroptothesubsequentcrop?
Ø Production:Canherbicideandfertilizerusebeoptimizedandoverallusedecreased?
Ø Regional:Arethesocialandeconomicimpactsofaddingpulseswellunderstood,andpositivebenefitsmaximized?Efficientwateruseandmanagement?Canlocally-adaptedpulsevarietiesandvarietiesbredforadaptabilitybepromoted?
Ø Global:Doestheincreaseinpulseproductionprovidemoreplant-basedproteinandimprovednetnitrogenmanagement?Netreductioninnon-renewableenergyuseandGHGemissions?
57
Potentialaction
Examplesofsub-
activities
Frameworkelementsthatapply
Scalestomeasureperformanceorimpact
Adop
tand
repo
rtonsustaina
bleprod
uctio
npractic
es/certification •Learnandapply
recommendedpracticestooptimizefarmsystemandlandscapesustainability.
•Understandbuyers’reportingexpectations;buildmonitoringintofarmoperations.
•Helptodevelopsustainabilitystandardsandfeasiblereportingprocesses;advocateforpricepremiumsorpreferredmarketaccessforverifiedsustainableproducts.
Ø Environmental:Areproductionstandardsandcertificationinplace?Somecertificationsystemspromotetheincreaseduseoffallowareas,whereasincreasingpulsecropsinrotationsusuallymeanslessfallow;arethesetrade-offsqualitativelyunderstood,andwilltherebenetbenefitstosoilhealthbyintroducingpulses?Whatothernuancesofpulseproductionmaynotbebestevaluatedbythestandard(e.g.GHGemissions,tillageandcropsequencing)?Whataspectsofsustainabilitybeyondtheproductionunitshouldbebroughtintokeyperformanceindicators(KPIs)?
Ø Social:Doesthestandardincludeasocialcomponent?Basedontheframework,adoptthosethatfitthecontext.
Ø Economic:Somestandardsconsidereconomictrade-offs(suchaspesticideuseversuscroplossesorcostofmitigation).Whataretheeconomicattributesinthepulseframeworkthatthestandardomits?
Ø Production:Methodstooptimizefertilizerandnutrientmanagement,minimizationofherbicideuseandphasedapproachespeciallyiftillagepracticesarealtered.Socialaspectsaddressedincludingfairdistributionofprofits(insupplychain),gender,labouruseefficiency,decreaseddependenceonnon-renewablefuels(relatestotillage),optionsforlivestockintegrationandforestintensification.Canavoidedcostsduetolesssoil,airandwaterdegradationbequantified?
Ø Regional:Avoidedcostsduetolesssoil,airandwaterdegradationhaveregionalimplications.Isregionalfoodsecurityimproved?Wateruseefficiencyandnutrientmanagementwillhaveregionalimplications.
Ø Global:Improvedpracticesresultsinlonger-termsoilintegrity(aglobalresource)andimprovednitrogenbalance.
58
Table5:Applicationoftheframeworktogovernments(policymakersinpulseproducing(orsuitable)jurisdictions)
Potentialaction
Examplesofsub-
activities
Frameworkelementsthatapply
Scalestomeasureperformanceorimpact
Investin
R&Dan
dextensionservices
§ Fundresearchonproductivity,sustainability,andriskreduction.
§ Providetrainingandresourcestopromotesustainablepulseproductionacrossdiversefarmingsystems.
Ø Environmental:Canmulti-yearresearchonsoils(nutrientsandmanagement),nitrogen,cropsequencing,tillagepractices,crop-livestockintegration,andyieldimprovementwithoutcropexpansionbesupported?Giventhefocusoninvestmentalreadyinplantgeneticsandyieldimprovement,howcanunderfundedareassuchasextensionservices,andnewinnovationsinpublic-privatepartnershipsbepromoted?
Ø Social:HowcaninvestmentsinR&Dhelpdevelopindicatorsandmeasuresofthesocialbenefitsofpulses?Howcanextensionserviceshelpruralproducersevaluatebenefitsandtrade-offsofcropresidueuse(affectssoils,livestock,etc.)promotegenderequity(orbetterunderstandgenderinequity)?
Ø Economic:Howcanproducermarketpricesupport,importorexporttariffs,andothermeasuresmaximizedomesticandinternationalfoodsecurityandeconomicreturnssimultaneously,withoutundueriskifvolatilityinmarketpricesoccurs?
Ø Production:Practicesatproductionlevelsimproveifalreadyproducingpulsesandifintegratingpulsesintorotations,haveresearchandsupporttooptimizepulsecropandvarietieswithoutimpactingotherkeycropyields;farmersaresupportedintransitionsincropresiduemanagementandtillagepractices;moreisdocumentedandanalyticsaresuppliedtofarmerstohelptroubleshoottrade-offsandrecognizehowtomaximizelabouruseefficiency,lowerfuelandinputcosts,andmaximizesustainableyields.
Ø Regional:Livelihood,community,nutrition,foodsecuritybenefitsmaybehardtoquantify,yetsignificant.
Ø Global:Avoidedcostsoflesssoil,airandwaterdegradationmaybehardtoestimate,butshouldbepartofmeasuringR&Dimpacts.
59
Potentialaction
Examplesofsub-
activities
Frameworkelementsthatapply
Scalestomeasureperformanceorimpact
Investin
plann
ingan
dinfrastructureand
develop
supp
ortiv
epo
licies
§ Establish/modernizetransport,storage,andprocessingfacilities.
§ Buildlandusemonitoringsystemsandlocalandregionalcapacityforspatialplanningandcontributedatatoglobalstatistics.
§ Reviseagriculture,food,andclimatechangepolicies(e.g.,MRLs,landtenure,cerealsubsidies,purchasingprograms)andfacilitatefinancingtopromotesustainablepulseproduction.
Ø Environmental:Multipleenvironmentalbenefitsrealized,suchasdecreasednon-renewablefueluseandGHGemissionminimization.Productionincreasesarethroughyieldimprovementsandincreasedcroprotationsonasustainablebasis,notareaexpansion,andaccesstomarketsandinformationisfacilitated.
Ø Social:Qualityoffoodisenhancedthroughbetterpost-harveststorage,improvedaccesstomarkets.Howtosupportdomesticfoodsecurity,whilepromotingexportmarketaccess?Public-privatepartnershipstomaximizepublicvalueandprivatesectorinvestment?
Ø Economic:Productionincreasesduetoinvestments,soincreasedprofitsatallscalesofsupplychain?Post-harvestlossisminimizedandqualityofproductbroughttomarketisimproved,exportsareincreasedwithoutriskingdomesticfoodsecurity.
Ø Production:Farmershavebettertoolstoadapttoclimate/market/economiccircumstancesthroughimprovedinformationandcanmoreeasilyaccessmarkets.Accesstofiscalincentivesbasedonsustainablepractices.
Ø Regional:Improvedefficiencyinmarkets,enabledbysupportivepolicies,positivelyaffectsincomelevels.Foodsecurityandnutritionimprovementsatfarmandregional/nationalscalesshouldbeenabled.Checkforappropriatelyspreadingvaluecapturethroughsupplychain,policiessupportgenderequity.Appropriatewaterandsoilmanagementtosupportproductionincreases.
Ø Global:NetGHGemissionreduction,macro-scalediversificationinplant-basedproteins.
60
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