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Economic Valuation of Changesin Ecosystem Services Provision
with a Life Cycle Approach
Aurélien Bruel, PhD student
ACES - 2014
Supervisors : Nadège Troussier - Bertrand Guillaume
Summary
Problem Hypothesis State of the art Method Illustrative case Conclusion
How to make the link between product and territory?
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
Territory Product
Information
Decision support in business- improve environmental performance
Decision support in public politics- modify and build economic incentives
Links ?
3
(Hanson et al., 2008 ; Ruckelshaus et al. 2013 ; TEEB, 2012 )
What kind of information?
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
Do we have any information of our environmental impact on the territory?
To get this information we could use the ES concept.
No, we don’t only at the product level with LCA.
Why not, it seemsto be a good idea.
4
Existing environmental accounting systems (Zhang et al. 2010 ; Loiseau et al. 2012) Mass Flow Analysis (MFA) Life Cycle Assessment (LCA) Energy analysis Emergy analysis Ecological footprint analysis
Some works have been suggested integrating ES into LCA (Bare 2010 ; Hau and Bakshi 2004 ; Houdet et al. 2009 ; TEEB 2012 ; WBCSD 2011 ; Zhang et al. 2010)
Integrating ES into LCA would give relevant information
Problem
HypothesisState of the art
MethodIllustrative case
Conclusion
5
What is LCA?
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
(Azapagic and Clift 1999; EU 2001; Finnveden et al. 2009; Hunkeler and Rebitzer 2005; Rebitzer et al. 2004) 6
What is its framework?
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
(ISO 14040 and 14044, 2006)
Goal and Scope
Life Cycle Impact Assessment
InterpretationLife Cycle Inventory (LCI)
Life cycle assessment framework
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(Jolliet et al. 2003, 2004)
Traditional Life Cycle Impact Assessment
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
• Human Health
• Resource depletion
• Ecosystem quality
= Midpoints = Endpoints
Impact categories Damage categoriesLCI results
Areas of protection
• Raw materialextraction
• Emissions (in air, water, and soil)
• Physical modification of natural area (e.g. land conversion)
• Noise
• Climate change• Resource depletion• Land use• Water use• Human toxic effects• Ozone depletion• Photochemical ozone
creation• Ecotoxic effects• Eutrophication• Acidification
Life Cycle Impact Assessment (LCIA)
8
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
Complexity in ES assessment
EconomicValuation
Biophysical valuation
ES conceptual relationships
Scales(spatio-temporal)
(Boyd and Banzhaf 2007, ten Brink, 2008 ; Fisher et al. 2009 ; Hein et al. 2006 ; Hanley and Shogren 2002 ; Randall 2002 ; Turner et al. 2003 ; Wallace, 2007 ; Yang et al. 2006) 9
Proposition
ProblemHypothesis
State of the art
MethodIllustrative case
Conclusion
Goal and Scope
Life Cycle Impact Assessment
InterpretationLife Cycle Inventory (LCI)
Life cycle assessment framework
EconomicValuation
Biophysicalvaluation
ES conceptualrelationships
Scales(spatio-temporal)
10
Proposition
ProblemHypothesis
State of the art
MethodIllustrative case
Conclusion
Changesin
final ES
= Midpoints = Endpoints
Impact categories Damage categoriesLCI results
• Raw materialextraction
• Emissions (in air, water, and soil)
• Physical modification of natural area (e.g. land conversion)
• Noise
Changes in
ecosystem quality(biophysical changes)
Life Cycle Impact Assessment (LCIA)
Changesin ES value
11
Changes in safe drinking water
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
Changesin ES final
safe drinking water
= Endpoints
Damage categoriesLCI results
= Midpoints
Impact categories
Changes inwater quality
(nutrient concentration of water)
Life Cycle Impact Assessment (LCIA)
InVEST modelnutrient retention
InputsLand-use
management
Outputsretained nutrients
Outputsexportednutrients
Changesin ES value
water treatment cost
12
Expected results
ProblemHypothesis
State of the artMethod
Illustrative caseConclusion
Water treatment cost
time
S1
S2
Changesin ES value
water treatment cost
13
Changes in safedrinking water
Product A
Product B
Product C
Impact category
Water treatment cost
Towards an integrated product-territory approach
ProblemHypothesis
State of the artMethod
Illustrative case
Conclusion
Decision support in business- improve environmental performance
Decision support in public politics- modify and build economic incentives
Territory
Product
Information
14
Question time
Université de technologie de Troyes (UTT)ICD/HETIC/CREIDD
12, rue Marie Curie 10010 Troyes http://www.creidd.utt.fr
INSPIRE Institut11, cours Joseph Thierry 13001 Marseille
http://www.inspire-institut.org/
Fondation 2019 (Fondation de France)40, avenue Hoche 75008 Parishttp://www.fondation-2019.fr/
15
Contact : aurelien.bruel@utt.fr
Linking changes
Actions
Nitrogenemission
Phosphorusemission
Change in water quality
Water clarity/algal development
Nutrient concentration of
water
Change in ES
Recreativefishing
Swimming
Commercial fishing
Safe drinking water
Change in value
Value of lake fishing
Value of swimming
Value of boating
Value of commercial fishing
Value of avoidedwater treatment
(Adapted from Keeler et al. 2012)
Change in Safe drinking water : steps
∑ nutrient emission that reach aquatic system
Define a steady state of concentration (N and P)
Assessing changes in concentration (N and P)
Assessing effect of this changes on water treatment cost
Allocating these cost to emissions
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