Sustainable Consumption and Production - Development of an Evidence Base
Project Ref.: SCP001 Resource Flows
Dr Thomas Wiedmann1, Mr Jan Minx1, Dr John Barrett,1 Mr Robin Vanner,2 Professor Paul Ekins2
May 2006
Final Project Report
1Stockholm Environment Institute - York
Sally Baldwin Building - D Block
University of York, Heslington
York, YO10 5DD, UK
Tel.: +44 1904 43 2899
Email:
2Policy Studies Institute
50 Hanson Street,
London, W1W 6UP
Tel: +44 20 7911 7500
Email:
1 Executive Summary 9
2 Introduction: Background on Policy and Research Issues 13
2.1 General Policy Context and Project Background 13
2.2 Material Flow Analysis 15
2.3 Why Matter matters - Motivation and Classification of MFA methodologies 17
2.4 Changing Patterns – MFA and the government’s framework for Sustainable Production and Consumption 19
3 Approach to Assessment 22
4 Review of Resource Flow Methodologies 24
4.1 Introduction 24
4.2 Choice of Methods 25
4.3 Assessment 26
4.3.1 Economy-wide Material Flow Analysis 27
4.3.2 Bulk Material Flow or Material Systems Analysis – Assessing the methodological framework of the Biffaward studies 29
4.3.3 Analysis of Material Flows by Sector: NAMEAs, Generalised Input-Output Models, and Physical Input-Output Analysis 31
4.3.4 Lifecycle Inventories 34
4.3.5 Substance Flow Analysis 37
4.3.6 Integrating approaches – Hybrid Methodologies 39
4.3.7 Approaches with sustainability reference points 42
4.4 From Weight to Impact – Changing Perspective on Material Flows 44
4.5 Policy Analysis 46
4.6 Resource Flow Models in the UK 47
4.7 Synthesis – Painting the Bigger Picture 50
4.8 Answering DEFRA’s specific tender questions 52
4.9 A Brief Guide to Policy Makers: on the choice of MFA tools - Choosing MFA methods for SCP policy use – from general to specific 54
4.10 Establishing strategic evidence sources for informing the prioritisation of SCP policies 55
4.10.1 A general framework for tackling the most important material flows first 56
4.10.2 Using MFA methodologies for informing prioritised MFA policies 57
4.10.3 Towards a comprehensive and strategic evidence-based material flow approach for informing SCP policies 59
4.11 Examples – Applying a strategic evidence-based material flow approach 61
4.11.1 Example 1: Sector Benchmarking – Monitoring Success 61
4.11.2 Example 2: Integrated Product Policies 62
4.11.3 Example 3: Sustainable Waste Management 64
4.12 Towards a Research Agenda for Tracking Strategic Materials in the UK 67
4.12.1 Policy Background and Motivation 67
4.12.2 Identifying key materials based on environmental impacts 67
4.12.4 Prioritising materials based on environmental impacts 69
4.12.5 Towards a modelling framework for tracing strategic materials 72
4.12.6 Challenges for Data Collection and Modelling 74
4.12.7 Further considerations and recommendations for tracing strategic materials in the SCP policy context 76
4.13 Recommendations 78
4.14 References 80
5 Review of Biffaward Studies 87
5.1 Introduction 87
5.2 The Biffaward Studies 87
5.3 The Assessment 88
5.3.1 The process of assessment 88
5.3.2 Assessment specifications 89
5.4 The relationship with the Biffaward Movement report 90
5.5 Assessment results 90
5.6 Discussion of Results 93
5.6.1 Sectoral Studies 93
5.6.2 Product Studies 94
5.6.3 Consumption Studies 94
5.6.4 Waste Studies 95
5.6.5 Material Studies 95
5.7 Discussion and recommendations 96
5.7.1 The policy cycle and the Biffaward studies 96
5.7.2 Specific policy points arising from particular studies 96
5.7.3 The value of the Biffaward studies 98
5.7.4 Recommended additional funding of work 99
5.8 References 101
6 Development of an Indicator for Emissions and Impacts associated with the Consumption of Imported Goods and Services 102
6.1 Introduction 102
6.1.1 Principles of emissions accounting and ‘embedded emissions’ 102
6.1.2 About this part of the project report 104
6.1.3 Requirements for an indicator of embedded emissions and impacts 104
6.2 Assessment Results and Discussion 105
6.3 Specification of an indicator for embedded emissions 107
6.3.1 Main issues 107
6.3.2 Data handling 107
6.3.3 Interpolating time series data 109
6.3.4 Outline of a pragmatic start for a model for embedded indicators 109
6.3.5 Feasibility of extending the model 111
6.3.6 Advantages and strengths of the specified model 113
6.3.7 Assumptions, limitations and weaknesses specific to MRIO modelling 114
6.4 Policy and Other Applications 115
6.4.1 Indicator for environmental impacts embedded in trade 115
6.4.2 Sustainable procurement and business options – greening international supply chains 117
6.4.3 Other applications 118
6.5 Conclusions and recommendations 119
6.6 References 122
List of Figures
Figure 2.1 - Material Flows of the Domestic Economy 14
Figure 2.2 - Human induced physical flows 16
Figure 2.3 - Classification of MFA Methodologies 18
Figure 3.1 - Illustrative example of assessment matrix 23
Figure 4.1 - Software interfaces of REAP (left) and REEIO (right) 50
Figure 4.2 - MFA methodologies in relation to dematerialisaton, detoxification and policy analysis 52
Figure 4.3 - MFA methodologies in relation to policy demands on different level 54
Figure 4.4 - Framework for prioritising SCP material flow policies 56
Figure 4.5 - MFA methodologies in an integrated material flow approach 58
Figure 4.6 - Studying the physical flows associated with aluminium and steel production 73
Figure 5.1 The groupings for the Biffaward studies 88
Figure 5.2 - Assessment Matrix: the Biffaward studies 91
Figure 5.3 - The policy cycle and the Biffaward studies 96
Figure 6.1 - Consumer (“consumption emissions”) versus producer (“production emissions”) responsibility for CO2 emissions in the UK 102
Figure 6.2: Data handling protocol for a multi-region input-output model 108
List of Tables
Table 2.1 - The SCP policy agenda and other relevant environmental agendas 21
Table 4.1 - Material Flow Methodologies included in this review 26
Table 4.2 - Summary economy wide material flow analysis 29
Table 4.3 - Summary bulk material flow/ material systems analysis 30
Table 4.4 - Overview ecological footprinting and environmental space 42
Table 4.5 - Examples: results ES analysis 43
Table 4.6 - Comments on linkage of MFA methodologies to environmental impact categories 45
Table 4.7 - Overview assessment results DEFRA tender questions 53
Table 4.8 - Pollutant agents and their environmental impacts 69
Table 4.9 - Environmental impact categories applied by Van der Voet et al. (2005) 70
Table 4.10 - Ranks of environmental impacts per kg of materials 71
Table 4.11 - Ranks of total environmental impacts of materials 71
Table 4.12 - Shortlist of strategic materials 72
Table 4.13 - Specific Recommendations derived from the review of the individual methodologies 79
Table 4.14 - General Recommendation 79
Table 5.1 - Studies which van be used directly to inform policy 92
Table 5.2 - Studies which can be used for policy with an appreciation of the study's limitations 93
Table 5.3 - Studies which should not be used to inform policy without further work 93
Table 5.4 - The robustness of the evidence base provided by the Biffaward studies 93
Table 6.1 - Overview of approaches and assessment results 105
List of Boxes
Box 2.1 - Tender Questions 15
Box 4.1 - Policy questions economy-wide material flow analysis 27
Box 4.2 - Policy questions environmental input-output analysis 31
Box 4.3 - Policy questions LCI/LCA 34
Box 4.4 - Policy questions substance flow analysis 37
Box 4.5 – Key recommendations environmental impact assessment 46
Box 4.6 - Key recommendations policy analysis 47
Box 4.7 - Good practive sector benchmarking 62
Box 4.8 - Good practice prioritising product groups according to environmental themes 64
Box 4.9 - Good practice: The Japanese waste input-output model 66
Acknowledgements
The authors are grateful to Jonathan Nobbes and David Aaron Thomas for their valuable contributions to the review of the Biffaward studies (Section 5). We are further indebted to Dr. Manfred Lenzen for his active involvement in Section 6.3 and Appendix III.3 and his very useful comments on the report as well as Dr. Karen Turner, University of Strathclyde for her contributions to Appendix III.3. We would also like to thank the Steering Group members and the reviewers for their comments on the interim report as well as Dr. Klaus Hubacek, University of Leeds, for commenting on earlier drafts.
The work has been funded by the UK Department for Environment, Food and Rural Affairs (DEFRA) through the programme ‘Sustainable Consumption and Production – Development of an Evidence Base’, Project code CTX0505/SCP1.1.
Glossary
ACORN A classification of residential neighbourhoods
BedZed Beddington zero energy development
BRE Building Research Establishment
BMFA Bulk material flow analysis
CDM Clean Development Mechanism
CO2 Carbon Dioxide
CSR Corporate social responsibility
Defra Department for Environment, Food & Rural Affairs
DMC Domestic material consumption
DTI Department for Trade and Industry
EA Environmental accounts
EC European Community
EF Ecological Footprint
EIOA Environmental input output analysis
EIOLCI Environmental input-output life-cycle inventories
EMFA Economy-wide material flow accounting
EPA Environmental Protection Agency
ES Environmental Space
EU European Union
Eurostat Statistical Office of the European Communities
GDP Gross Domestic Product
GINFORS Global Inter-industry forecasting system
GIOA Generalised input-output analysis
GTAP Global Trade Analysis Project
IEA International Energy Agency
IIOHLCI Integrated input-output hybrid life-cycle inventories
IO Input-output
IOHLCI Input-output hybrid life-cycle inventories
IPA Impact Potential Approaches
IPP Integrated product policy
IPPC Intergovernmental Panel on Climate Change
ISIC International Standard Industrial Classification
ISO International Organisation for Standardisation
IVEM Centre for Energy and Environmental Studies, University of Groningen
JI Joint Implementation
LCA Life-cycle analysis
LCI Life-cycle inventories
MFA Material flow analysis
MIOTs Monetary input-output tables
MOSUS Modelling opportunities and limits for restructuring Europe towards sustainability
MRIO Multi-regional input-output
MSA Material system analysis
NAMEA National accounting matrix including environmental accounts
NHS National Health Service
NISP National Industrial Symbiosis Programme
NOx Nitrogen oxides
OECD Organisation for Economic Co-ordination and Development
ONS Office of National Statistics
PIOA Physical input-output analysis
PM10 Particulate Matter of less than 10 millionths of a metre
POITs Physical input-output tables
Prodcom Products of the European Community
REAP Resources and Energy Analysis Programme (Stockholm Environment Institute)
REEIO Regional Environment-Economic Input Output model (Cambridge Econometrics)
REMAT Resource Management Tool (University of Surrey)
RMFA Regional Material Flow Accounting Model (University of Surrey)
ROW Rest of the world
RSWT Royal Society for Wildlife Trusts
SCP Sustainable consumption and production
SCPnet Sustainable consumption and production Network
SEI Stockholm Environment Institute
SD Sustainable Development
SFA Substance flow analysis
SPA Structural Path Analysis
TIOLCI Tiered input-output life-cycle inventories
TMI Total material input
TMC Total material requirement
UK United Kingdom
UN United Nations
UNCTAD United Nations Conference on Tariffs and Trade
WRAP Waste and Resources Action Plan
WSSD World Summit for Sustainable Development
WTO World Trade Organisation
Executive Summary
Part A – Review of Biffaward Studies
(by Robin Vanner and Paul Ekins)
This part of the report introduces the Biffaward series of reports which were commissioned following the publication in 1997 of an overview publication (Biffa 1997) relating to resource use and waste management in the UK. The rationale for the investment of more than £10.6 million from the landfill tax credit scheme was that information about resource flows though the UK economy is of fundamental importance to the cost effective management of those flows, especially at the point at which those flows become ‘wastes’. Now that the Biffaward programme of research is nearing completion, the purpose of this assessment is to identify those studies which are both sufficiently robust, and relevant to future policy agendas. The results of the assessment have been the subject of a formal consultation with the reports’ authors, as well as a dialogue with practitioners and policy makers through a project workshop. Of the 48 studies which have been assessed:
· 7 studies can be used to inform policy directly.
· 29 studies can be used to inform policy, but with a note of caution about some aspect of the study (in many cases this is due to the results representing modelled data’.
· 12 studies were assessed not to be usable in relation to future policy without further work.
Considering the results by how they relate to the chain of production and consumption:
· The product, material and consumption type studies were all assessed to be robust and policy relevant, although many require a note of caution in relation to some study limitations.
· There were mixed assessments of studies relating to production. There was only one completed primary production study available for assessment. All but one of the secondary production studies were considered to be usable in policy, although the age and lack of updateability of some of the datasets was identified as a significant limitation for some. The tertiary or service sector studies faced an even greater challenge in terms of the collection of data and only two of them were assessed as usable in policy,
· 10 out of the 15 waste studies were considered to be usable in policy in some way. It is difficult to make generalisations for such a varied group of studies. However, the studies relating to research and model development tended to be more robust than the sectoral level waste studies, due to the higher quality of the data that they used.
This part to of the project goes on to conclude that the Biffaward programme of studies generated many benefits for a large range of users and showed how a comprehensive or consistent classification of material flows within the economy might be achieved. A full and comprehensive reading of the reports has led to the conclusion that, in industry, there may be potential to enhance industrial symbiosis utilising the present knowledge base, through the development of industrial networks. Such networks need to be developed and shown to lead to mutual industrial advantages and benefits, on the basis of current knowledge, before further investment is made in extending the quantification and specification of industrial material flows. The process of mapping out consumption is now well developed but needs to be supported by better data sources so that the findings relate even more closely to actual consumption patterns.
Part B – Review of Resource Flow Methodologies
(by Jan Minx, John Barrett and Thomas Wiedmann)
Resource Flow or Material Flow Analysis (MFA) can be considered as the application of the biological concept of metabolism to human society. Society is depicted as a living organism which continuously withdraws resources from nature, digests them in the transformation processes of production and consumption and finally releases them back to nature as wastes/residuals. MFA can be seen as an attempt to describe and analyse all or a subset of these metabolic (material and energetic) processes quantitatively.