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Methodologies for Measurement of GBEPIndicators for Bioenergy
Presented by:
Dr. Ir. Yandra Arkeman, M.Eng
Bilateral Workshop On Market Opportunities for RenewableEnergy and Sustainable Biomass
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Introduction
Title of this workshop: Bilateral workshop on market opportunities for renew
able energy and sustainable biomass
Renewable energy Bioenergy
Bioenergy: Palm oil biodiesel Bioethanol (from Sugar Cane Molasses)
Biogas
Solid Biomass (from Agricultural Waste and Municipal
Waste)
Bioenergy Business Development Technology,
Financial and SUSTAINABILITY
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Topics Covered
Focus of this presentation
Sustainability ofBioenergy in Indonesia
Indonesian perspective (UUD45, ISPO)
Global perspective (EU Standard, RSPO, etc GBEP)
Important Issues covered:
Global Bioenergy Partnership (GBEP)
GBEP Sustainability Indicators for Bioenergy
Methodologies for Measurement of GBEP Indicators
SBRCs Projects related to Bioenergy
Development and Sustainability
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Questions :
Indonesian Bioenergy :
Sustainable or Not?
From upstream (Farming) to downstream
(Processing Industry, Distribution and Use)What are the INDICATORS for
sustainability?
How to MEASURE each indicator?(Methodology)
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What is GBEP ?
http://sbrc.ipb.ac.id
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A Global Commitment to Bioenergy In the 2005 Gleneagles Plan of Action, the
G8 +5 (Brazil, China, India, Mexico and SouthAfrica) agreed to launch a Global Bioenergy
Partnership(GBEP)to support wider, costeffective, biomass and biofuels deployment,particularly in developing countries.
Gleneagles Plan of Action is targeted at
combating CLIMATE CHANGE Bioenergy and GBEP are tools in the fight
against climate change
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Following a consultation process amongdeveloping and developed countries,international agencies and the private sector, theGlobal Bioenergy Partnership (GBEP) waslaunched at the 14th session of the Commissionon Sustainable Development (CSD-14) in NewYork on 11 May 2006.
We invite the Global Bioenergy PartnershipGBEP) to continue its work on biofuel best
practices and take forward the successful andsustainable development of bioenergy(G8 Summit Declaration - Heiligendamm, 7 June2007).
http://sbrc.ipb.ac.id
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GBEP PARTNERS AND OBSERVERS
Italy and Brazil are currently Chair and co-Chair of the Partnership.
The Secretariat is hosted at theF O HQ in Rome
.
36 Partners (23 governments 13 organizations):
G8 Governments (Canada, France, Germany, Italy, Japan, Russian Federation,United Kingdom, United States of America) plus Argentina, Brazil, China,Colombia, Fiji Islands, Ghana, Mauritania, Mexico, Netherlands, Paraguay,
Spain, Sudan, Sweden, Switzerland and Tanzania, as well as ECOWAS,European Commission, FAO, IDB, IEA, UNCTAD, UNDESA, UNDP, UNEP, UNIDO,
UN Foundation, World Council for Renewable Energy and EUBIA.
34 Observers (23 governments 11 organizations):
Angola, Australia, Austria, Cambodia, Chile, Egypt, El Salvador, Gambia, India,Indonesia, Kenya, Lao P.D.R., Madagascar, Malaysia, Morocco, Mozambique,
Norway, Peru, Rwanda, South Africa, Thailand, Tunisia and Vietnam, alongwith the African Development Bank, Asian Development Bank, ECLAC,
European Environment Agency, GEF, IFAD, IRENA, OAS, UEMOA, World Bank,and the WBCSD.
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What are GBEPs SustainabilityIndicators ?
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AGREED BY 23 COUNTRIES & 13 INTERNATIONAL
ORGANIZATIONS INVOLVING A TOTAL OF 46 COUNTRIESAND 24 INT. ORGANIZATIONS (PS & OS)
24 SUSTAINABILITY INDICATORS3 PILLARS
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Pillars
http://sbrc.ipb.ac.id
Environmental
Social
Economic
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SBRCs Projects on Bioenergy Development andSustainability
At present 3 PhD, 3 Masters and 2 Under-graduate Students conducting research onBioenergy Sustainability
One collaborative research between IPB and
George Mason University (GMU), USA has juststarted this May, for three years
Title:Design of Adaptive Agro-industrial System forMitigating Global Climate Change and Securing Food,Water, Bioenergy and Natural Medicine Supply by
Using SMART-TIN Principal Investigators: Yandra Arkeman (IPB) and
Prof. Kenneth De Jong (GMU-USA)
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E-mail : [email protected]
Office : +62 251 8330970
Thank you
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Environmental Pillar
http://sbrc.ipb.ac.id
THEMES
GBEP considers the followingthemes relevant, and theseguided the development ofindicators under this pillar:
Greenhouse gas emissions,Productive capacity of the landand ecosystems, Air quality,
Water availability, use efficiencyand quality, Biological diversity,Land-use change, includingindirect effects
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
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Indicator 1
http://sbrc.ipb.ac.id
Lifecycle greenhouse gasemissions from bioenergyproduction and use, as per themethodology chosen nationally orat community level, and reportedusing the GBEP CommonMethodological Framework forGHG Lifecycle Analysis ofBioenergy
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 2
http://sbrc.ipb.ac.id
Percentage of land for which soilquality, in particular in terms ofsoil organic carbon, is maintainedor improved out of total land onwhich bioenergy feedstock iscultivated or harvested
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 3
http://sbrc.ipb.ac.id
Annual harvest of wood resourcesby volume and as a percentage ofnet growth or sustained yield, andthe percentage of the annualharvest used for bioenergy
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 4
http://sbrc.ipb.ac.id
Emissions of non-GHG airpollutants, including air toxics,from bioenergy feedstockproduction, processing, transportof feedstock, intermediateproducts and end products, anduse; and in comparison with otherenergy sources
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 5
http://sbrc.ipb.ac.id
Water withdrawn from nationally-determined watershed(s) for theproduction and processing ofbioenergy feedstock, expressed asthe percentage of total actualrenewable water resources(TARWR) and as the percentage oftotal annual water withdrawals(TAWW), disaggregated intorenewable and non-renewablewater sourcesVolume of water withdrawn from
nationally-determined watershed(s) used for the production andprocessing of bioenergy feedstockper unit of bioenergy output,disaggregated into renewable andnon-renewable water sources
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 6
http://sbrc.ipb.ac.id
Pollutant loadings to waterwaysand bodies of water attributableto fertilizer and pesticideapplication for bioenergyfeedstock cultivation, andexpressed as a percentage ofpollutant loadings from totalagricultural production in thewatershedPollutant loadings to waterways
and bodies of water attributableto bioenergy processing effluents,and expressed as a percentage ofpollutant loadings from totalagricultural processing effluents inthe watershed
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 7
http://sbrc.ipb.ac.id
Area and percentage of nationallyrecognized areas of high biodiversity value or critical ecosystemsconverted to bioenergy productionArea and percentage of the landused for bioenergy productionwhere nationally recognizedinvasive species, by risk category,are cultivatedArea and percentage of the land
used for bioenergy productionwhere nationally recognizedconservation methods are used
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Indicator 8
http://sbrc.ipb.ac.id
Total area of land for bioenergyfeedstock production, and as comparedto total national surface and agriculturaland managed forest land areaPercentages of bioenergy from yield
increases, residues, wastes anddegraded or contaminated landNet annual rates of conversion betweenland-use types caused directly bybioenergy feedstock production,including the following (amongst others)
arable land and permanent crops,
permanent meadows and pastures,and managed forests;natural forests and grasslands(including savannah, excludingnatural permanent meadows andpastures), peat lands, and wetlands
Back
Indi
cators1. Life-cycle GHG emissions
2. Soil quality3. Harvest levels of wood resou
rces
4. Emissions of non-GHG air pollutants, including air toxics
5. Water use and efficiency
6. Water quality
7. Biological diversity in the landscape
8. Land use and land-use change related to bioenergy feedstock production
Detailed Methodology
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Social Pillar
http://sbrc.ipb.ac.id
Indi
cators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand accessto modern energy services
15. Change in mortality and burdenof disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
THEMES
GBEP considers the followingthemes relevant, and these guidedthe development of indicatorsunder this pillar:
Price and supply of a national foodbasket, Access to land, water andother natural resources, Labor
conditions, Rural and socialdevelopment, Access to energy,Human health and safety
Back
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Indicator 9
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Percentage of land total and byland-use type used for newbioenergy production where:a legal instrument or domesticauthority establishes title andprocedures for change of title;the current domestic legalsystem and/or socially acceptedpractices provide due process andthe established procedures are
followed for determining legal title
Back
Indi
cators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 10
http://sbrc.ipb.ac.id
Effects of bioenergy use and domesticproduction on the price and supply of afood basket, which is a nationally-definedcollection of representative foodstuffs,
including main staple crops, measured atthe national, regional, and/or householdlevel, taking into consideration:changes in demand for foodstuffs for food,feed, and fibre;changes in the import and export offoodstuffs;changes in agricultural production due to
weather conditions;changes in agricultural costs frompetroleum and other energy prices; andthe impact of price volatility and priceinflation of foodstuffs on the national,regional, and/or household welfare level,as nationally-determined
Back
Indi
cators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 11
http://sbrc.ipb.ac.id
Contribution of the following tochange in income due tobioenergy production:wages paid for employment inthe bioenergy sector in relation tocomparable sectorsnet income from the sale, barterand/or own-consumption ofbioenergy products, includingfeedstock, by self-employed
households/individuals
Back
Indi
cators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 12
http://sbrc.ipb.ac.id
Net job creation as a result ofbioenergy production and use,total and disaggregated (ifpossible) as follows:
skilled/unskilledtemporary/indefinite
Total number of jobs in thebioenergy sector and percentageadhering to nationally recognizedlabor standards consistent with
the principles enumerated in theILO Declaration on FundamentalPrinciples and Rights at Work, inrelation to comparable sectors
Back
Indicators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 13
http://sbrc.ipb.ac.id
Change in average unpaid timespent by women and childrencollecting biomass as a result ofswitching from traditional use ofbiomass to modern bioenergyservices
Back
Indicators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 14
http://sbrc.ipb.ac.id
Total amount and percentage ofincreased access to modernenergy services gained throughmodern bioenergy (disaggregatedby bioenergy type), measured interms of energy and numbers ofhouseholds and businessesTotal number and percentage ofhouseholds and businesses usingbioenergy, disaggregated into
modern bioenergy and traditionaluse of biomass
Back
Indicators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 15
http://sbrc.ipb.ac.id
Change in mortality and burden ofdisease attributable to indoorsmoke from solid fuel use, andchanges in these as a result of theincreased deployment of modernbioenergy services, includingimproved biomass-based cookstoves
Back
Indicators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Indicator 16
http://sbrc.ipb.ac.id
Incidences of occupational injury,illness and fatalities in the production of bioenergy in relation tocomparable sectors
Back
Indicators
9. Allocation and tenure of land fornew bioenergy production
10. Price and supply of a national food basket
11. Change in income
12. Jobs in the bioenergy sector
13. Change in unpaid time spent bywomen and children collecting biomass
14. Bioenergy used to expand access
to modern energy services15. Change in mortality and burden
of disease attributable to indoorsmoke
16. Incidence of occupational injury,illness and fatalities
Detailed Methodology
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Economic Pillar
http://sbrc.ipb.ac.id
THEMESGBEP considers the following themes relevant, and these guidedthe development of indicatorsunder this pillar:Resource availability and useefficiencies in bioenergyproduction, conversion,distribution and end-use,Economic development, Economic
viability and competitiveness ofbioenergy, Access to technologyand technological capabilities,Energy security/Diversification ofsources and supply, Energysecurity/Infrastructure andlogistics for distribution and use Back
Indicators17.Productivity
18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
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Indicator 17
http://sbrc.ipb.ac.id
Productivity of bioenergyfeedstock by feedstock or byfarm/plantationProcessing efficiencies bytechnology and feedstockAmount of bioenergy endproduct by mass, volume orenergy content per hectare peryearProduction cost per unit of
bioenergy
Back
Indicators17.Productivity
18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 18
http://sbrc.ipb.ac.id
Energy ratio of the bioenergyvalue chain with comparison withother energy sources, includingenergy ratios of feedstockproduction, processing offeedstock into bioenergy,bioenergy use; and/or lifecycleanalysis
Back
Indicators17.Productivity
18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 19
http://sbrc.ipb.ac.id
Gross value added per unit ofbioenergy produced and as apercentage of gross domesticproduct
Back
Indicators17.Productivity
18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 20
http://sbrc.ipb.ac.id
Substitution of fossil fuels withdomestic bioenergy measuredby energy content and in annualsavings of convertible currencyfrom reduced purchases of fossilfuelsSubstitution of traditional use ofbiomass with modern domesticbioenergy measured by energycontent
Back
Indicators17.Productivity
18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 21
http://sbrc.ipb.ac.id
Percentage of trained workers inthe bioenergy sector out of totalbioenergy workforce, andpercentage of re-qualified workersout of the total number of jobslost in the bioenergy sector
Back
Indicators17.Productivity
18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 22
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Change in diversity of totalprimary energy supply due tobioenergy
Back
Indicator
s17.Productivity18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 23
http://sbrc.ipb.ac.id
Number and capacity of routes forcritical distribution systems, alongwith an assessment of theproportion of the bioenergy
associated with each
Back
Indicator
s17.Productivity18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
Detailed Methodology
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Indicator 24
Ratio of capacity for usingbioenergy compared with actualuse for each significant utilizationrouteRatio of flexible capacity whichcan use either bioenergy or otherfuel sources to total capacity
Back
Indicator
s17.Productivity18.Net energy balance19.Gross value added
20.Change in consumption of fossil fuels and traditional useof biomass
21.Training and re-qualificationof the workforce
22.Energy diversity23. Infrastructure and logistics for distribution of bioenergy
24.Capacity and flexibility of use of bioenergy
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