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Timberlake, T., Vaughan, I. P., & Memmott, J. (2019). Phenology offarmland floral resources reveals seasonal gaps in nectar availability forbumblebees. Journal of Applied Ecology, 56(7), 1585-1596.https://doi.org/10.1111/1365-2664.13403
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J Appl Ecol. 2019;00:1–12. | 1wileyonlinelibrary.com/journal/jpe
Received:30August2018 | Accepted:12March2019DOI: 10.1111/1365-2664.13403
R E S E A R C H A R T I C L E
Phenology of farmland floral resources reveals seasonal gaps in nectar availability for bumblebees
Thomas P. Timberlake1 | Ian P. Vaughan2 | Jane Memmott1
ThisisanopenaccessarticleunderthetermsoftheCreativeCommonsAttributionLicense,whichpermitsuse,distributionandreproductioninanymedium,providedtheoriginalworkisproperlycited.©2019TheAuthors.Journal of Applied EcologypublishedbyJohnWiley&SonsLtdonbehalfofBritishEcologicalSociety
1SchoolofBiologicalSciences,UniversityofBristol,Bristol,UK2CardiffSchoolofBiosciences,CardiffUniversity,Cardiff,UK
CorrespondenceThomasP.TimberlakeEmail:[email protected]
Funding informationNaturalEnvironmentResearchCouncil,Grant/AwardNumber:NE/L002434/1
HandlingEditor:FabriceRequier
Abstract1. Floralresourcesareknowntobeimportantinregulatingwildpollinatorpopula-tionsandarethereforeanimportantcomponentofagri‐environmentandresto-ration schemeswhich aim to support pollinators and their associated services.However,thephenologyoffloralresourcesisoftenoverlookedintheseschemes—afactorwhichmaybelimitingtheirsuccess.
2. Ourstudycharacterizesandquantifiesthephenologyofnectarresourcesatthewhole‐farmscaleonreplicatefarmsinSouthwesternUKthroughoutthefloweringseason.Wequantifythecorrespondingnectardemandsofasubsetofcommonwild pollinators (bumblebees) to compare nectar supply and pollinator demand throughouttheyear,therebyidentifyingperiodsofsupply‐demanddeficit.
3. Werecordstrongseasonalfluctuationsinfarmlandnectarsupplies,withtwomainpeaksofnectarproduction(MayandJuly)andaconsiderable“JuneGap”inbe-tween.MarchandAugust/Septemberarealsoperiodsoflownectaravailability.
4. Comparingthephenologyofnectarsupplywiththephenologyofbumblebeenec-tardemandreveals“hungergaps”duringMarchandmuchofAugust/Septemberwhensupplyisunlikelytomeetdemand.
5. Permanentpastureandwoodlandproducedthegreatestshareoffarmlandnectarbecauseoftheirlargearea;however,linearfeaturessuchashedgerowsandfieldmarginsprovidedthegreatestnectarperunitarea.Fiftypercentoftotalnectarwassuppliedby justthreespecies (Allium ursinum, Cirsium arvense and Trifolium repens),butsome lessproductivespecies (e.g.Hedera helix and Taraxacum agg.) wereimportantinensuringphenologicalcontinuityofnectarsupply.
6. Synthesis and applications.Bycomparingthephenologyoffarmlandnectarsupplywiththephenologyofpollinatordemand,wedemonstratethatthetimingofnec-tarsupplymaybeasimportantastotalnectarproductioninlimitingfarmlandpol-linatorpopulations.Consideringphenologyinthedesignofagri‐environmentorrestorationschemesisthereforelikelytoimprovetheirsuitabilityforpollinators.Plant specieswhich flower during periods of resource deficit (early spring andlatesummer)shouldbeprioritizedinschemeswhichaimtoconserveorrestore
2 | Journal of Applied Ecology TIMBERLAKE ET AL.
1 | INTRODUC TION
Theservicethatpollinatorsprovidetoamajorityoftheworld'swildflowering plants (Ollerton,Winfree, & Tarrant, 2011) and 75% ofworld crop species (Kleinet al., 2007)makes their conservation ahighpriority.Understandingthefactorsthatlimitpollinatorpopula-tionsonfarmlandiscriticalindesigningconservationschemesthatensuretheirlong‐termsurvival.Wildpollinatorpopulationsarelim-itedbyseveralfactors includingfloralnectarandpollenresources(Goulson,Nicholls,Botias,&Rotheray,2015;Potts,Vulliamy,Dafni,Ne'eman, & Willmer, 2003), nesting sites (Steffan‐Dewenter &Schiele,2008)andvariousotherfactorssuchasdisease,pesticidesandpredators (Goulsonetal.,2015;Roulston&Goodell,2011). IntheUK,nectar levels fellby32%between1930and1978, in linewith trends in pollinator diversity and agricultural intensificationsincetheSecondWorldWar(Baudeetal.,2016).Changesinthelast30years, likelyduetodecreasedacidification,decreasednitrogendepositionandtheuptakeofEnvironmentalStewardshipSchemes,have led tomodest increases innectarproduction.However,nec-tarproductionremainslowerthanpre‐1930slevelsandsignificantlossesinnectardiversityremain(Baudeetal.,2016).
The large‐scalecoverageofagricultural land intheUK(70.8%)(WorldBank, 2015), makes it an important consideration for anyprogramme aiming to conserve biodiversity at a national level. In theUK, Environmental Stewardship Schemes provide annual pay-mentstofarmersandlandmanagersformanagingtheir landinanenvironmentallyfriendlyway,includingforthebenefitofpollinators(NaturalEngland2009).Nectar‐richfieldmarginsareanimportantcomponentoftheseschemesandtherearedataonthebestfloralmixturesforsupportingfarmlandbumblebees,forexample(Carvell,Meek,Pywell,&Nowakowski,2004;Pywelletal.,2005).Itisknownthat the addition of floral resources can increase bumblebee col-onygrowthandnestdensity(Carvelletal.,2017;Crone&Williams,2016;Wood,Holland,Hughes,&Goulson,2015),andincreasespe-cies diversity and abundance of trap nesting bees (Dainese et al.,2018). However, the timing of resource availability (i.e. the phe-nology) is also important (Carvell et al., 2017;Williams,Regetz,&Kremen,2012),butthisaspectismuchlessunderstood.
Forpollinatorstopersistandthriveatthelandscapelevel,theymusthavesufficientfloralresourcesfortheentiredurationoftheirflight season (Menz et al., 2011; Russo, DeBarros, Yang, Shea, &
Mortensen,2013;Scheperetal.,2015).“Phenologicalgaps”ofjust15 days severely affect modelled honeybee colony development(Horn,Becher,Kennedy,Osborne,&Grimm,2016),afindingempir-icallysupportedbyRequier,Odoux,Henry,andBretagnolle(2017).Such gaps are likely to be evenmore detrimental to bee specieswhich do not have honey reserves. The importance of a season‐longsupplyoffloralresourceshassofarnotbeengivensufficientconsiderationinthedesignofEnvironmentalStewardshipschemes(Carvell,Meek,Pywell,Goulson,&Nowakowski,2007).Itissimilarlyoverlookedintherestorationofnaturalhabitatswhichrelyonpol-linatorstoensurethereproductivecontinuityoftherestoredplantcommunity(Dixon,2009).Theseoversightscouldultimatelybelim-itingthesuccessofbothtypesofscheme.
Identifying periods of the year inwhich floral resourcesmoststrongly limit pollinator populationswill be key to addressing thisissue inatargetedandcost‐effectiveway.Thisrequiresanunder-standing of both flowering phenology and pollinator floral needsata landscape‐scaleover theirentire flight season.Our studyad-dressestheseknowledgeneedsviathefollowingthreeobjectives:(a)characterizingandquantifyingthephenologyofnectarresourcesatthewhole‐farmscaleonreplicatefarmsthroughoutthefloweringseason (lateFebruary toearlyNovember); (b)quantifying thecor-responding nectar demands of common farmland bumblebees tocomparenectarsupplyandpollinatordemandthroughouttheyear,therebyidentifyingperiodswhenthereisasupply‐demanddeficit;(c) identifyinghabitatsandplantspecieswhichmayfill thesegapsand thereby provide sufficient resources for the entire pollinatorflight seasonon farmland.Ourmethodsprovideanovelapproachto plant‐pollinator phenological matching (Russo et al., 2013) andenable targeted planting strategies for the restoration of nectarsupplies on farmland, an approach that could be applied to otheranthropogenichabitats.
2 | MATERIAL S AND METHODS
2.1 | Study sites
The study was conducted in 2016 and 2017 on four medium‐sized (140–280ha)mixed (dairy, sheepandarable) farms inNorthSomerset,noneofwhichwereinEnvironmentalStewardship.Siteswere surrounded by mixed farmland and rural villages, typical of
pollinatorpopulations.Maintainingarangeofsemi‐naturalhabitatswithcomple-mentaryfloweringphenologies(e.g.woodland,hedgerowsandfieldmargins)willensureamorecontinuoussupplyofnectaronfarmland,therebysupportingpol-linatorsfortheirentireflightseason.
K E Y W O R D S
agri‐environment,bumblebees,floralresources,floweringphenology,nectar,pollination,pollinatorconservation,restoration
| 3Journal of Applied EcologyTIMBERLAKE ET AL.
Southwest UK. The substantial time demands of recording floralabundance at a farm scale regularly from late February to earlyNovemberrestrictedfurtherreplication.Thereisatrade‐offinphe-nologystudiesbetweentheamountandresolutionofdatathatcanbegatheredatasiteandthenumberofsitesthatcanbesampled.Here,weadoptedadualapproachwherebyonesitewassampledintensivelytocapturethefine‐scaletemporalvariationinfloweringphenology and three other siteswere sampled less intensively tocapturethespatialvariation.
The intensive study site, Birches Farm in Somerset, England(51°25′19.04″N, 2°40′49.93″W)was sampled twice per week in2016 from lateFebruaryuntilearlyNovember,providing the in-tensivecomponentofthestudy.Thereweretwocomponentstotheextensivepartofourstudy.First,in2016,threefurtherfarmsin Somerset — Eastwood Farm (51°29′41.71″N, 2°60′56.74″W),ChestnutFarm(51°24′22.94″N,2°91′08.96″W)andElmtreeFarm(51°21′58.04″N, 2°85′44.36″W)—were sampled each fortnightfromMarchuntilNovemberin2016.Thefourfarmswere6–20kmfromeachotheranddifferedslightlyintheirhabitatcomposition,withvaryingproportionsofpastureandarablefields,hedgerows,margins andwoodland (see Table S1 and Figure S1). The nectarproductionandhabitatcompositionofallfourfarmswerebroadlyrepresentative of thewider landscape, based upon unpublisheddatafrom11farmsinSouthwestUK(seeAppendixS1andFigureS2).Thesefourfarmswereusedtocomparetheplantspeciesandhabitatcontributionstofarmlandnectarsupply.Second,in2017,threeofthefourfarms(Birches,EastwoodandElmtreefarms,re-ferredtohereafterasthephenologyfarms)weresampledeveryweek throughout the flowering season; thisprovidingbothphe-nologically informativedataandtemporal replicationforBirchesfarm.
2.2 | Objective 1: Characterizing and quantifying the phenology of nectar resources at the whole‐farm scale
2.2.1 | Nectar measurements
On each sampling occasion, six randomly located 50m transectswereconductedwithineachhabitattype(e.g.24transectsintotal,forafarmwithfourhabitattypes).Oneachtransect,thenumberofopenfloralunitsofeachfloweringplantspecieswasrecordedina1 m2quadratat5mintervalsalongitsentirelength(i.e.10quadratspertransect).Fortreesandshrubs,allflowersina5‐mverticalcol-umnabovethequadratwerecounted.Abovethis,thetree'sheightwithintheverticalcolumnwasestimatedwithaclinometerandthefloralabundancevaluesweremultipliedupaccordingly,asinBaudeet al. (2016).Values for the nectar sugar production of each spe-cieswerefromBaudeetal. (2016)whomeasuredormodelledthesugar(sucrose)productionof305plantspeciesintheUK,includingthe175mostcommonspecies.Thesugarproductionofeightspe-ciesencounteredinthestudybutnotcoveredbyBaudeetal.(2016)weremeasuredaccordingtotheirmethods(seeAppendixS2).
2.2.2 | Quantifying flowering phenology
Eachvisittoafarmgeneratedanestimateofthenumberofopenflowers per square metre in each habitat for that point in time.Whenmultipliedbythemeanfloralsugarproductionofeachspe-cies,anestimateofthegramsofsugarperunitareaper24‐hrpe-riodwasobtainedforeachhabitat.Thiswasmultipliedbytheareaofthathabitatonthefarm(calculatedusingQGISv.2.12.3)togiveanestimateofsugaravailabilityonthewholefarm.Ageneralizedadditivemodel(GAM),wasusedtomodelasmooth,nonlineartrendinsugaravailabilitybytime,withseparateanalysesperformedata farm andhabitat level.GAMsprovide a usefulwayof fitting asmoothcurvetodatawithnonlinearpatterns,thusallowinginter-polation between data points. To incorporate uncertainty associ-atedwithestimatesof individualspecies’nectarproduction,highandlowestimatesoffarmlandnectarprovisioningwerecalculatedusing upper (mean + SE)andlower(mean−SE)estimatesofeachspecies’sugarproduction.Thesethreeestimates(upper,lowerandmean)weremodelled separately.AGammaerror familywith loglinkfunctiongavethebestfitforthezero‐inflatedcountdata.Theextent of smoothing was varied between candidate models andguidedbyVaughanandOrmerod(2012)whoadvisevaluesaround0.3ofthenumberoftimepoints,asacompromisetocapturebothseason‐long trends and shorter term variation. Akaike's informa-tion criterion (AIC) was used to compare candidate models andselect thetop‐rankingone (with lowestAICvalue). Inadditiontomodellingsugarproductionatthewhole‐farmscaleandthehabitatlevel,the20mostcommonplantspeciesineachhabitatweremod-elledseparatelyusingtheapproachoutlinedabove.Thisallowedustocomparethesequenceofspeciesfloweringbetweenfarmsandbetweenyearsandidentifyparticularlyimportantspecies—bothin terms of total sugar production and phenological importance.Allstatisticalanalyses,figureplotting,andmodelswereperformedwithrversion3.2.2(RCoreTeam),usingthemgcvpackage(Wood,2011).
2.3 | Objective 2: Quantifying the nectar demands of three common bumblebee species to compare nectar supply and pollinator demand throughout the year
Toidentifyperiodsinwhichfarmlandnectarsuppliesarelikelytobelimitingpollinatorpopulations,wecomparedthetotalsugaravailabil-ityofBirches,EastwoodandElmtreefarms(usingtheGAMpredic-tions)withtheestimatedpopulation‐level,farm‐scalesugardemandsofthethreemostcommonbumblebeesonUKfarmland(Bombus ter-restris, Bombus pascuorum and Bombus lapidarius).Bumblebeeswerechosenasafocalgroupastheyweretheonlytaxonwithsufficientdataonenergyconsumption,colonydensityandphenologytomakethenecessarycalculations.Theyarealsoknowntobeimportantpol-linatorsofwildplants(Kovacs‐Hostyanszkietal.,2013)andarangeofcrops(Garrattetal.,2014)andyetare indeclineacrossvariouspartsoftheworld(Goulson,Lye,&Darvill,2008).
4 | Journal of Applied Ecology TIMBERLAKE ET AL.
EnergydemanddatacamefromRotheray,Osborne,andGoulson(2017)who recorded thegramsof sugar consumedeachweekbycaptive B. terrestris audax colonies as they grew from singlewild‐collectedqueens to full colonies.Toaccount for theextraenergyexpendedduringforagingflight,0.312gofsugarwasaddedperindi-vidualforagingbeeperday(Rotherayetal.,2017),basedoncalorificcalculationsfromHeinrich(1979).WefollowedtheassumptionsofRotherayetal.(2017),thathalfoftheworkersforage4daysaweek,theothersremaininginthenestashousebees,andthatthequeenforagesuptothepointatwhichfiveworkersareproduced.SugarconsumptiondatawereonlyavailableforB.terrestris,butB. pascuo-rum and B. lapidarius were assumed to have similar consumptionratesbecausetheirbodysizes(Intertegularspan[mm]for:B. terres-tris [3.5];B. lapidarius and B. pascuorum [5.2]) (Greenleaf,Williams,Winfree,&Kremen,2007),andtotalcolonysizes(400individualsforB.terrestris and B. lapidariusand300forB. pascuorum)(Dicksetal.,2015) are broadly similar.
ColonydensitiesweretakenfromDicksetal.(2015)whosum-marize (froma rangeof studies) thenestdensityestimatesof thethreemostcommonBombus species on agricultural land: B. terrestris (meannestdensity:32/km2),B. pascuorum(83/km2) and B. lapidarius (78/km2).WorkernumberspercolonyandtheirchangesthroughtheyearweretakenfromRotherayetal.(2017).
Toestimatethetimingofcolonyfoundationinourstudyarea,weusedBeeWalktransectdata(BumblebeeConservationTrust2016&2017)from31recordingsitesinNorthSomerset.TheproportionsofB. terrestris, B. pascuorum and B. lapidariusqueensemergingindif-ferentmonthsoftheyearwerecalculated,allowingustomatchthetimingofcolonydevelopmentandnectardemandwiththetimingsoffarmlandnectaravailability.
2.4 | Objective 3: Identifying habitats and plant species which fill the gaps in nectar production
TherelativeimportanceofdifferentfarmlandhabitatswasassessedbycomparingtheGAMpredictionsforeachhabitatonthefourfarmsrecordedin2016.Thephenologicalimportanceofeachplantspeciesineachhabitatwascalculatedbysummingtheproportionalcontribu-tiontototalweeklysugarsupplymadebythespecies,foreachweekoftheyear.Themetriccapturesboththetemporaluniquenessofaspecies’nectarsupplyanditslengthoffloweringtime.
3 | RESULTS
3.1 | Objective 1: Characterizing and quantifying the phenology of nectar resources at the whole‐farm scale
During137visitstothefourfarmsover2years,nearlyhalfamillion(494,291)individualfloralunitsfrom176floweringplantspecieswerecounted in 2,664 transects (761 hedgerow transects, 759 pasture,576woodlandand568margins).ThedailysugarproductionofeightnewspecieswasrecordedandaddedtothenectardatabaseofBaudeetal.(2016)(seeTableS2).Thetop‐rankinggeneralizedadditivemodel(seeTableS3)describedanonlineartrendinsugaravailabilitywhichfluctuatedgreatlythroughtheyear,creatingthesixfloweringperiodshighlightedinFigure1.Althoughtotalyearlysugarproductionperkil-ometresquaredvarieduptothreefoldbetweenfarmsin2017(342kgofsugarkm−2 year−1onBirchesFarm,461onEastwoodFarmand131onElmtreeFarm),thephenologicalpatternofsugarproductionwasrelativelyconsistentamongthefarms(Figure2).
F I G U R E 1 DailysugarproductionofBirchesFarm(squares),EastwoodFarm(circles)andElmtreeFarm(triangles)duringindividualvisitsoveranentirefloweringseasonin2017.DataaresmoothedwithaGeneralizedAdditiveModel.Thecurvebaseduponthemeansugarproductionofeachplantspecies(±SE;dashedlines)isshowninblack,whilethecurvesbaseduponlowandhighestimatesofeachspecies’sugarproductionareshowninred(±SE;dottedlines).Theyearisdividedintowhatisvisuallyperceivedasthemainfloweringseasons,withpinkrepresentingtroughsandpurplerepresentingpeaks
| 5Journal of Applied EcologyTIMBERLAKE ET AL.
3.2 | Objective 2: Quantifying the nectar demands of a subset of common wild pollinators to compare nectar supply and pollinator demand throughout the year
Thestrongseasonalityofnectarsupplydidnotsynchronizewellwiththesugardemandofcommonbumblebeespecies(Figure3).Oneach
ofthethreephenologyfarms,thepollinatorflightseasonwaschar-acterizedbyalternatingperiodsofnectardeficitandsurpluswhichwere relatively consistent in their timings, though differed some-what in themagnitudeof theirpeaksand troughs. InearlyMarchwhen queens emerge, sugar demand per individual bee was highwhilefarmlandnectarproductionwasatitslowestfortheflowering
F I G U R E 2 Nectarphenologyprofilesof(a)BirchesFarm2016,(b)BirchesFarm2017,(c)EastwoodFarm2017and(d)ElmtreeFarm2017.Resultsaretakenfromsummingtheoutputsofindividualspeciesmodelsforeachfarm.Reddottedlinesshowmediandailysugarproductionfortheyear.Peaksofnectarproduction(>median)aremarkedinpurple,whiletroughsorgaps(<median)areshowninpink.Notethedifferentscaleforeachgraph.TheJuneGaponBirchesFarm2016(plotA)isevidentfromthecurvebutdoesnotregisterasaformaltroughasitdoesnotcrossthemedianline
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6 | Journal of Applied Ecology TIMBERLAKE ET AL.
season.Thisleftameandeficitof12.3gofsugarkm−2 day−1(±1.7SE) betweenwhatwasavailableandourestimatesofbumblebeeneeds.This“hungergap”lastedfromthestartofthepollinatorflightseasonuntillateMarch.Duringthistime,theonlyspeciesproducingecolog-icallymeaningfulquantitiesofsugaronthefarmswereTaraxacum agg., Prunus spinosa, Glechoma hederacea, Ranunculus ficaria and Bellis perennis.Together,thesespeciescontributedameanof13.1gofsugarkm−2 day−1 (±6.8SE)during thehungergap. Justone for-agingqueenrequiresanestimated0.7gofsugarperday,meaningthatformostofMarch,amaximumof19queenbumblebeescouldbesupportedon1km2offarmland.Thisdoesnotaccountforanyyoungworkers that have been produced, or other pollinator spe-ciescompetingfornectarsuchasearlyspeciesofsolitarybeesorhoverflies.
In late summer (August‐October), the three study farmshad ameandeficitof1,053gof sugarkm−2 day−1 (±81.4SE) lasting be-tween1 and3months (Figure3).Although sugarproductionwasrelatively high at this time, Bombus colonies were reaching theirmaximum size, generating a high demand for nectar which could
notbemetbythefarmlandlandscape,resultinginasecondhungergap.AverysmallproportionofthefarmlandsugarwasproducedbyplantsspeciesunlikelytobeutilizedbyBombus (e.g. Stellaria media) implyingnectaravailabilitymaybeevenlowerthanpredicted.
From lateMarchuntilmid‐lateMay, therewasameansurplusof2,196gofsugarkm−2 day−1(±986SE)onthethreestudyfarms.Mass‐floweringoil seedrapewasnotpresentonanyof thestudyfarmsbutnormallyflowersduringthisperiodandwouldthereforebe expected to add to the nectar surplus recorded on our farmsratherthanfillahungergap.
3.3 | Objective 3: Identifying habitats and plant species which fill the gaps in nectar production
Habitatsdifferedgreatlyintheirsugarproductionvalueatafarmscalebuttheirrelativevaluesamongfarmsweresimilar(Figure4).Hedges produced the greatest sugar per unit area (1.88 g ofsugar m−2 year−1;±0.24SE)andwithameancoverageof1%offarmarea,theymadeup9.4%(±3SE)oftotalsugar.Theirphenological
F I G U R E 3 Comparisonbetweendailynectarsupplyanddailydemandofthreecommonbumblebeespeciespresenton1km2offarmlandon:(a)BirchesFarm2016,(b)BirchesFarm2017,(c)EastwoodFarm2017and(d)ElmtreeFarm2017.Blacklinesshowgramsofsugaravailableeachdayon1km2farmland,dividedbythenumberofcommonbumblebeespresentonthelandscapeatthattimethatis,sugaravailableperindividualbee(±SE).TheredlineshowstheestimatedmeandailysugarrequirementofaBombus terrestris individual at eachpointintheyear(±SE),fromRotherayetal.(2017).Notethatenergydemandperindividualishighestinearlyspringwhenqueensareforagingandestablishingcolonies.Shadedregionshighlightperiodsofnectardeficitwheredemand(redline)exceedssupply(blackline).Notethey-axis is plotted on a log10 scale
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| 7Journal of Applied EcologyTIMBERLAKE ET AL.
continuitywasalsohighest,beingthemostnectar‐richhabitatperunitarea62% (±3SE)of theyear.Fieldmarginswerealsoa richhabitatfornectar,withameanof1.68gofsugarm−2 year−1(±0.09SE). However, their period of nectar production was relativelyshort‐lived (seeFigureS3).Witha coverageof1%of farmarea,theymadeup3.1%(±4SE)oftotalsugarproduction.Thenectarproductionofpasturewassubstantial(54%oftotalsugarproduc-tion,±12SE)becauseofitslargeareaonthefarm(mean64%cov-erage),butperunitareaitproducedonly0.27gofsugarm−2 year−1
(±0.12SE).Wherewoodlandwaspresent,itcoveredanaverageof8%ofthefarm,producing1.08gofsugarm−2 year−1(±0.06SE) and makingup33.1% (±12SE)of total farmnectar supply.However,approximately90%of this supplywasproduced in just1month(May) and it was almost exclusively provided by Allium ursinum (89%).Figure5showsthesugarcontributionsofthemostproduc-tiveplantspeciesineachofthefourhabitats.
Althoughupto59plantspeciesproducedecologicallymean-ingful quantities of sugar at some point in the year (>0.3 g of
F I G U R E 4 Totalyearlynectarproductionofthefourmainhabitattypespresenton(a)atypical1km2areaoffarmland(includingvaluesfromfarmswherethathabitatwasnotpresent)and(b)asquaremetreofthegivenhabitat.Valuesforeachhabitatareexpressedasameanofthefourstudyfarms(Birches,Eastwood,ElmtreeandChestnut)±SE
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F I G U R E 5 Nectarcontributionsofthemostproductiveplantspeciesin(a)fieldmargins,(b)hedgerows,(c)pastureand(d)woodland.Valuesshownareameanofthefourstudyfarms(Birches,Chestnut,EastwoodandElmtree)
Rubusfru�cosus
25%
Heracleumsphondylium
15%Cirsiumarvense
15%
Prunusspinosa
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Anthriscussylvestris
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Salix sp6%
Crataegusmonogyna
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Other16%
Allium ursinum89%
Rubus fru�cosus3%
Anthriscus sylvestris2%
Ilex aquifolium 2% Other
Heracleumsphondylium
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Trifoliumrepens
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Anthriscussylvestris
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Taraxacumofficinale
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Cirsium arvense3%
Convolvulus arvensis2%
Calystegia sepium2% Other
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Trifolium repens26%
Cirsium arvense19%
Trifoliumpratense
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Ranunculusacris12%
Taraxacumofficinale
6%
Centaurea nigra5%
Heracleum sphondylium4% Other
11%
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8 | Journal of Applied Ecology TIMBERLAKE ET AL.
F I G U R E 6 Plantspecies’contributionstototalfarmlandnectarsupplyon(a)BirchesFarm,(b)EastwoodFarm,(c)ElmtreeFarmand(d)ChestnutFarmin2016.Linesshowthecumulativecontributionofeachspecies.Onlythe20mostproductivespeciesoneachfarmareshown
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TA B L E 1 The10mostphenologicallyimportantspeciesonBirchesfarmin2016,rankedinorderofdecreasingscore.Thephenologicalimportancemetricgivestheproportionalcontributiontototalweeklynectarsupplymadebythespecies,summedacrosseachweekoftheyear.Highscoringspeciesarethosewhichflowerattimeswhenlittleelseisinbloom,contributingaveryhighproportionoftotalnectar.Theirdateofpeakfloweringisshown,alongsidethedateatwhichtheyaremakingthegreatestproportionalcontributiontototalnectarsupply,thatis,thepointatwhichtheirprovisioningismostimportant
Species Phenological importance metric Peak flowering date Peak phenological importance
Hedera helix 8.0 05 October 02 November
Taraxacum officinale 6.6 04May 06 April
Cirsium arvense 3.6 13July 13July
Allium ursinum 3.3 11May 11May
Rubus fruticosus 2.5 20July 17August
Heracleum sphondylium 2.5 15June 08June
Trifolium repens 2.5 13July 03 August
Bellis perennis 1.1 11May 02March
Glechoma hederacea 1.1 18May 02March
Centaurea nigra 1.0 29June 29June
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sugarkm−2 day−1),50%of total sugarwas suppliedby just threespecies and 80% of the sugar was supplied by eight species(Figure 6). These were:A. ursinum (18%), Cirsium arvense (16%),Trifolium repens (14%),Trifolium pratense (12%),Heracleum sphon-dylium (6%),Ranunculus acris (5%),Rubus fruticosus agg. (5%)andTaraxacumagg.(4%).Severallessproductivespeciesmadeimport-antcontributionstothephenologicalcontinuityofnectarsupply,due to their unusual flowering times (Table1).Hedera helix pro-videdoverhalfofall sugar frommid‐Septemberuntil theendofthefloweringseason,whileTaraxacumagg.providedthemajorityofsugarfrommid‐MarchuntiltheendofApril.
4 | DISCUSSION
OurstudyquantifiesthefloweringphenologyoffourUKfarmsatahightemporalresolutionthroughoutthefloweringseason.There-sultsshowstrongseasonalfluctuationsinfarmlandnectarsuppliesandsuggestthephenologyofnectarsupplycouldbeasimportantastotalnectarproduction in limitingfarmlandpollinatorpopulations,thoughthisremainstobetested.Comparingnectarsupplywiththeenergy demands of a subset of common Bombus species reveals gapsbetweennectar supplyanddemandduringMarchandmuchofAugustandSeptember.Habitatsonthefarmsdifferedgreatlyintheirpatternofnectarproductionbuttendedtocomplementeachother'snectarsupply.Permanentpastureandwoodlandproducedthegreatest shareof farmlandnectarbecauseof their large area;however, linearfeaturessuchashedgerowsandfieldmarginspro-videdthegreatestnectarperunitarea,reflectingfindingsbyBaudeetal.(2016)intheirUK‐wideanalysis.Mostofthefarmlandnectarwassuppliedbyasmallnumberofplantspecies,butsomelesspro-ductivespecieswereimportantinensuringphenologicalcontinuityofnectarsupply.
4.1 | Limitations
Therewerethreemainlimitationstoourwork.First,thepracticaland time constraints of recording flowering phenology at a highresolutioninmultiplelocationsmeantthatourstudywaslimitedtofourfarmsacrossoneregionoftheUK.Whilethepatternofnec-tar supplywas relatively consistentacross these four farms, thispatternwill differ according to geography, inter‐annual variationandagriculturalpractices.Forexample, farmswithmanyearlier‐flowering tree species or late‐flowering haymeadows, are likelytohaveadifferentphenologicalpatternofnectarproduction.Thephenomenonofnectargapshowever, is likely tobea featureofmanyhuman‐alteredlandscapes,particularlythosethathavebeenheavily simplified. Second, while we model Bombus nectar de-mandsoneachfarm,alackofdatameansthatwecannotincludethedemandsofthemanysolitarybees,honeybees,hoverfliesetc.It is thereforea conservativeestimateofdemandand shouldbeviewedasaminimumbaselinerequirementforbumblebeesalone,rather than an ideal level.However, this approach still allowsus
toidentifythemostseverenectargapswhicharelikelytoaffectall pollinatorgroups.And finally,whilewehavedetaileddataonnectar,wedid not quantify pollen.Althoughboth are importantresources,wefocusonnectarbecauseofitsimportanceasanen-ergysourceinthedietsofadultbeesandotherpollinatorgroups.It also allowsus todirectly compare thenutritional contributionofallplantspeciesandhabitatsthroughthecommoncurrencyoftotalsugars(Willmer,2011).Itispossiblehoweverthatpollenre-sources (which are known to limit brood production and colonysizeofhoneybees,Requieretal.,2017andbumblebees,Rotherayetal.,2017),maydifferfromnectarresourcesintheirphenology,resultinginadifferenttimingofresourcegaps.Thisisanimportanttopicforfutureresearch.
4.2 | Flowering and pollinator phenology
Thehighlyseasonalnectarsupplydetected inourstudyonfarm-landinSouthWestUKislikelytohaveimportantimplicationsforwild andmanagedpollinators.The largedifferencesbetween theflowering phenology of different habitats (see Figure S3), sug-gestthatpollinatorsneedtomovebetweenhabitats,trackingthechangingresourcesupplies,toensureacontinuoussupplyofnectar.ThiseffecthasbeendemonstratedinagriculturalareasoftheU.S.wherecomplementaryhabitatsprovideresourcesatdifferenttimesof the year and the pollinator community tracks these resources(Mandelik,Winfree,Neeson,&Kremen,2012).Thishighlightstheimportanceofhavingarangeofdistincthabitattypespresentonfarmland.
Variousstudieshave identifieda fooddeficit forhoneybees inJune/July(Couvillon,Schurch,&Ratnieks,2014;Requieretal.,2015)whichcoincideswiththeperiodbetweenthespringfloralresources(includingmass‐floweringoilseedrapewhichisknowntobeimport-antforwildpollinators(Westphal,Steffan‐Dewenter,&Tscharntke,2003))andsummerfloralresources.Thisperiodoftheyearhasbeenanecdotallynamedthe“JuneGap”bybeekeepers.Withthelargedipinnectarresourcesrecordedbetweenthespring(May)andsummer(July)wildflowerbloomsandthemodestgapbetweennectarsupplyandbumblebeedemandrecordedinJune,ourstudyprovidesstrongempiricalevidencefortheexistenceofthe“JuneGap”onfarmlandinthisregion.
Theearlyspringseason(lateFebruarytolateMarch)isaperiodofverylownectaravailability.Thiscoincideswithaperiodofhighenergy demand by queen bumblebeeswhich are foraging, estab-lishingnestsandheatingtheirbrood(Heinrich,1972),resultinginanectardeficitformostofMarch.Thismodestgapcouldbehavingamarkedeffectonthesurvivalofqueens—aneffectwhichislikelytocascadethroughtheyearbylimitingthenumberofcolonieses-tablished.Indeed,ourdatahelpexplainthefindingbyCarvelletal.(2017)thatavailabilityofearlyspringresourcesonfarmlandstronglyinfluencesbumblebeecolonydensities.EarlyBombus colonies grow very littleunderfood limitation (Rotherayetal.,2017),suggestingtheeffectsofthisgapmayextendbeyondcolonyestablishment,af-fectingcolonysizetoo.
10 | Journal of Applied Ecology TIMBERLAKE ET AL.
Compared with the early spring gap, the late‐season gap isgreater inmagnitudeandlasts longer (one‐threemonths),which islikelytothreatenthesurvivalof late‐emergingbumblebeespeciesonfarmland.This isconsistentwithBalfour,Ollerton,Castellanos,and Ratnieks (2018) who found significantly greater numbers ofextinctions in late‐summer flying British pollinator species, andFitzpatrick et al. (2007), who found a disproportionate decline inlate‐emergingbumblebeespeciesinIrelandandBritain.Theyattri-butethesedeclinestoareductioninlate‐summerfloralresources,partiallydrivenbytheshiftinagriculturalpracticesfromhaytosi-lage production. Other wild pollinators such as solitary bees andhoverflies have shorter flight seasons, somay not be affected byallthesameresourcegaps.However,thepopulationsofmostpolli-natorspeciespeakinlatesummer(Balfouretal.,2018),suggestingthismaybeaperiodofnectardeficitformanydifferentpollinatortaxa.Hornetal.(2016)demonstratedthatbadlytimedgapsinnec-tarsuppliescangreatlyaffecttheresilienceofmodelledhoneybeecolonies;bumblebees,whichdonotaccumulatesignificantresourcereserves,arelikelytobemorestronglyaffectedbysuchgaps.Morevulnerablestillwillbespecieswithshort flightseasons (e.g.manysolitarybees)whoseemergencetimescoincidewithanectardefi-cit.Resourcegapsdifferedslightlybetweensamplingyears,withanorderofmagnitudegreaterspringnectardeficitin2017than2016onBirchesFarm(Figure3a,b), likelyduetothewarmerspringandearlieremergencetimesofqueenbumblebeesin2017(BumblebeeConservation Trust 2016 & 2017). Variation in resource gaps be-tweensites(Figure3b–d)waslikelyduetodifferenthabitatcompo-sitionandmanagementofthefarms,particularlypasture,themostvariablehabitat(Figure4a),whichislikelytoofferthegreatestpo-tential for improvement. The effects of inter‐annual variation andlandscapecompositiononnectarphenologyareimportanttopicsforfuturestudy.
Withclimatechangeadvancingthefloweringphenologyofmanyplantspecies(e.g.FitterandFitter(2002)),andthepotentialforre-sulting phenological mismatches between plants and pollinators(Forrest,2015;Hegland,Nielsen,Lazaro,Bjerknes,&Totland,2009),itwillbecomeincreasinglyimportanttounderstandhowthetimingof resource suppliesaffectspollinatorpopulations.Byquantifyingthecurrentphenologyofnectar resources,wecanmakemore in-formed predictions about how this resource supplymight changeandwhichspeciesaremostlikelytobeaffected.
4.3 | Management implications
Wehavedemonstratedthat itmaynotbe just theavailabilityofnectar resources limiting Bombus populations, but also the tim-ingof these resources, though this remains tobe tested.MarchandAugust/Septemberareperiodsofgreatestnectardeficit forBombuspopulationsandshouldthereforebeprioritizedtoensureasufficientannualnectarsupply.Plantspecieswhichflowerduringtheseperiodsofdeficit—so‐called“bridgingspecies”(Menzetal.,2011)—shouldbeprioritizedinschemeswhichaimtoconserveorrestorepollinatorpopulationsonfarmland.Theearlyhungergap
weobservedon the four farms could theoretically be “plugged”byaddingjust12.3extragramsofsugareachdayacross1km2offarmland, the equivalent of c. 1,000willow catkins for example(datafromBaudeetal.,2016).WillowsSalix spp. could be readily addedtoUKfarmingsystems,deliveringpollenandnectarintheearlyspringwhenfloralresourcesareparticularlyscarce(Moquet,Mayer,Michez,Wathelet,& Jacquemart, 2015).The late‐seasongaphoweverwouldrequirebetween500and2,000extragramsofsugarperday,whichequatestoapproximatelyonehectareoflate‐flowering red cloverT. pratense (Rundlof, Persson, Smith, &Bommarco,2014),oranextra40brambleR. fruticosusagg.flowerspermetresquaredofhedgerow(basedonameanfarmcoverageof1%hedgerowarea).
Onallfourstudyfarms,halfofthetotalnectarsupplywaspro-videdbythreespeciesorfewer,afindinginaccordwithBaudeetal.(2016)intheirUK‐wideanalysis.Withjustafewplantspeciesdom-inatingfarmlandnectarsupplyformostoftheyear,thereisthepo-tentialforthesespeciestodominatethedietsofpollinators,reducingtheirdietdiversity.Theimmunocompetenceofhoneybeeshasbeenshowntoreducewithalessvarieddiet(Alaux,Ducloz,Crauser,&LeConte,2010;DiPasqualeetal.,2013)anditislikelythatthesameistrueforbumblebees.Resourcediversityshouldthereforebeconsid-eredalongsidetotalresourceavailabilityinthedesignofanyschemesaimingtorestoreorconservehealthypollinatorcommunities.
5 | CONCLUSIONS
Wild pollinator populations are known to be limited by floral re-sources and we have demonstrated why the timing of these re-sources may be an important factor driving this limitation. Thetemporalmismatchbetweenpollinator resourcedemandandphe-nologyoffarmlandresourcesupplydetectedinthisstudy, is likelytobeafeatureofmanyotherhuman‐alteredlandscapes;thoughthisremainstobetested.Ourresultssuggestthat inanyagri‐environ-mentorrestorationschemewhichaimstosupportpollinatorsandtheprovisioningofpollinationservices,consideringthephenologyofbothplantsandpollinatorswillbecritical.
ACKNOWLEDG EMENTS
This work was supported by the Natural Environment ResearchCouncil through the NERC GW4+ Doctoral Training Partnership(NE/L002434/1).Wewouldalsoliketothankthefollowingfieldas-sistants:EmmaBall,IzzyCarpenterandRowanHookham,alongwiththefourfarmerswhogavepermissiontousetheirland.
AUTHORS’ CONTRIBUTIONS
J.M.andT.P.T.conceivedtheideasanddesignedthemethodology;T.P.T.collectedthedata;T.P.T.andI.P.V.analysedthedata;T.P.T.andJ.M.ledthewritingofthemanuscript.Allauthorscontributedcriti-callytothedraftsandgavefinalapprovalforpublication.
| 11Journal of Applied EcologyTIMBERLAKE ET AL.
DATA ACCE SSIBILIT Y
Data available via the Dryad Digital Repository https://doi.org/10.5061/dryad.3nk236h (Timberlake, Vaughan, & Memmott,2019).
ORCID
Thomas P. Timberlake https://orcid.org/0000‐0001‐8166‐0825
Ian P. Vaughan https://orcid.org/0000‐0002‐7263‐3822
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SUPPORTING INFORMATION
Additional supporting information may be found online in theSupportingInformationsectionattheendofthearticle.
How to cite this article:TimberlakeTP,VaughanIP,MemmottJ.Phenologyoffarmlandfloralresourcesrevealsseasonalgapsinnectaravailabilityforbumblebees.J Appl Ecol. 2019;00:1–12. https://doi.org/10.1111/1365‐2664.13403