Waste input-output analysis : concepts and application to industrial ecology

Industrial ecology (IE) is a rapidly growing scienti?c discipline that is concerned with the sustainability of industrial systems under explicit consideration of its int- dependence with natural systems. In recent years, there has been an ever-increasing awareness about the applicability of Input-Output Analysis (IOA) to IE, in particular to LCA (life cycle assessment) and MFA (material ?ow analysis). This is witnessed in the growing number of papers at ISIE (International Society for Industrial Ec- ogy) conferences, which use IOA, and also by the installment of subject editors on IOA in the International Journal of Life Cycle Assessment. It can be said that IE has become a major ?eld of application for IOA. The broadening of users of IOA from various backgrounds implies a need for a self-contained textbook on IOA that can meet the needs of students and practitioners without compromising on basic c- cepts and the latest developments. This book was written with the aim of ?lling this need, and is primarily addressed to students and practitioners of IE. As the title suggests, the core contents of the book have grown out of our research in IOA of waste management issues over the last decade. We have been fascinated by the versatile nature of IOA with regard to various technical issues of waste m- agement in particular, and to IE in general. For us (both economists by training), IOA has turned out to be extremely useful in establishing productive communi- tion with scientists and engineers interested in IE.

1. Introduction.- 1.1 The Aim of the Book.- 1.2 Outline of the Book's Content.- 1.3 Putting IOA in Practice by Excel.- References.- Part I: Input-Output Analysis.- 2. Basics of Input-Output Analysis.- 2.1 The One-sector Model.- 2.1.1 Input and Output in a Productive Economy.- 2.1.2 The Leontief Quantity Model.- 2.1.3 Production, Income, and Consumption: The Input-Output Table.- 2.1.4 Cost And Price: The Price Model.- 2.2 The Two-sector Model.- 2.2.1 Production Processes.- 2.2.2 The Leontief Quantity Model.- 2.2.3 The Price Model.- 2.2.4 The IO Table.- 2.3 The N Sectors Model.- 2.3.1 Matrix Notations.- 2.3.2 Inversion of a Matrix and the Quantity Model.- 2.3.3 Exogenous Inputs and Waste Generation.- 2.3.4 Cost and Price.- 2.3.5 Structural Decomposition Analysis.- 2.3.6 IOA for the Case of N = 2.- 2.4 Exercise with Excel.- 2.4.1 Basic Analysis.- 2.4.2 Consolidating of Sectors.- References.- 3. Extensions of IOA.- 3.1 Regional Extensions.- 3.1.1 A Two-region Open Model.- 3.1.2 A Two-region Closed Model.- 3.1.3 A Three-region Model: An Open Model.- 3.1.4 International IO Tables.- 3.2 By-product.- 3.2.1 Defining By-product And Waste.- 3.2.2 The Leontief Quantity Model With By-product.- 3.2.3 A Numerical Example.- 3.2.4 Implications for Positivity Conditions.- 3.3 The Model Based on Use and Make Matrices.- 3.3.1 U and V Matrices, and Related Identities.- 3.3.2 Industry-based Technology.- 3.3.3 Commodity-based Technology.- 3.4 Extension Towards a Closed Model.- 3.4.1 Integrating Consumption.- 3.4.2 The Dynamic Model: Closing The IO Model with Regard to Capital Formation.- 3.4.3 A Fully Closed Model.- 3.5 Extension to the System with Inequalities.- 3.5.1 Limited Supply of Exogenous Inputs.- 3.5.2 Issues of Substitution: Programming Model.- 3.6 The 'Supply-side Input-output' Model of Ghosh.- 3.7 The Fundamental Structure of Production.- 3.7.1 Identifying the Fundamental Structure of Production.- 3.7.2 Application to the Japanese IO Table.-3.8 Exercise with Excel.- 3.8.1 Accounting for Competitive Imports.- 3.8.2 The Upper Bounds of Final Demand When the Supply of Exogenous Inputs is Limited.- 3.8.3 The Choice of Technology.- References.- 4. Microeconomic Foundations.- 4.1 Introduction.- 4.2 Representation of Technology.- 4.2.1 Technology and Production Function.- 4.2.2 Cost and Input Demand Functions.- 4.2.3 Duality Between Cost and Production Functions.- 4.3 Specification of Technology.- 4.3.1 Top-Down and Bottom-Up Approaches.- 4.3.2 The Elasticity of Substitution Between Inputs.- 4.3.3 CES Functions.- 4.3.4 Flexible Functional Forms.- 4.3.5 Tree Structure of Technology: Separability.- 4.4 Technology in the Leontief IO Model.- 4.4.1 Characteristics of Technology in IOA.- 4.4.2 Substitution Theorems.- 4.4.3 Supply and Demand Curves in IOA.- 4.4.4 IOA: Bottom-Up or Top-Down?- References.- Part II: Waste Input-Output Analysis.- 5. Basics of WIO.- 5.1 Environmental IO (EIO).- 5.1.1 Linking the Economy and the Environment in IOA.- 5.1.2 Energy Analysis.- 5.1.3 Emission IO Model.- 5.2 The IO Models of Pollution Abatement and Their Relevance to Waste Management.- 5.2.1 The Leontief Model Of Pollution Abatement.- 5.2.2 Further Extensions of the Leontief EIO Model.- 5.2.3 IO Tables with Waste and Waste Management.- 5.3 Waste IO: Concepts and Modeling.- 5.3.1 The Leontief-Duchin EIO and the Dutch NAMEA.- 5.3.2 The Waste IO.- References.- 6. WIO Analysis.- 6.1 WIO Tables and Analysis: Empirical Examples.- 6.1.1 WIO for a City in Hokkaido, Japan.- 6.1.2 WIO Tables for Japan.- 6.2 The Dynamic Nature of Waste Treatment Processes.- 6.2.1 A System Engineering Representation of the Incineration Process.- 6.2.2 Implications for WIO.- 6.2.3 Effects of Changing the Allocation Pattern of Waste to Treatment Processes.- 6.3 The WIO Cost/Price Model.- 6.3.1 The WIO Price Model with Waste Treatment.- 6.3.2 The WIO Price Model with Waste Treatment and Recycling.- 6.3.3 Numerical Example.-