Closing the Technospheric Flows of Toxic Metals: Modeling Lead Losses from a Lead‐Acid Battery System for Sweden

Karlsson, Sten

doi:10.1162/108819899569377

Cited by 32 publications

(13 citation statements)

References 18 publications

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“…That is, material and energy flows supporting economic transfers are just as fundamental as monetary flows; the focus in this article, hence, is on improving the understanding of material flows in an industrial economy. As is clear from the number of articles focusing on material and/or energy flows (for instance, see, from this journal, Ayres [1997Ayres [ , 1998b, Ayres and Ayres [1997], Fischer-Kowalski [1998], Fischer-Kowalski and Hüttler [1999], Haberl [2001aHaberl [ , 2001b, Karlsson [1999], Keckler and Allen [1999], Kleijn [2000], Koenig and Cantlon [2000], and Rejeski [1998]), we are not alone in identifying the relevance of material and energy flows to environmental issues in industry.…”

Section: Discussionmentioning

confidence: 99%

Applying Ecological Input‐Output Flow Analysis to Material Flows in Industrial Systems: Part I: Tracing Flows

Bailey

Allen²,

Bras³

2004

J of Industrial Ecology

102

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Input‐output mathematics, which allows a modeler to fully consider direct and indirect relationships among conserved flows in a system, has a long history in economics with prominent use dating to Leontief in the 1930s. Nearly all previous industrial applications of input‐output analysis have been grounded in the monetary flows of an economy. Here however, because of the central nature of physical flows in the environmental impact of industry, we consider physical flows to be a fundamental component of an industrial economy. Hence, we propose an input‐output based approach for modeling physical flows in industry independent of their monetary implications. In this first part of a two‐part article, a framework for using input‐output mathematics to model material and energy flows is constructed from a foundation laid by previous research in nutrient and energy cycling in natural ecosystems. The mathematics of input‐output flow analysis is presented from an ecological perspective, culminating in two core capabilities: tracing of flows with environs (investigated in this article) and characterizing system behavior with flow metrics (presented in the second article). We assert that environ analysis is an effective means for tracing flows through industrial systems while fully considering direct and indirect flow paths. We explore material flows of aluminum and five other metals in depth using environ analysis in this article.

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Section: Discussionmentioning

confidence: 99%

Applying Ecological Input‐Output Flow Analysis to Material Flows in Industrial Systems: Part I: Tracing Flows

Bailey

Allen²,

Bras³

2004

J of Industrial Ecology

102

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“…Moreover, photovoltaics may play a key role in the transition to sustainability, probably leading to expanded need for certain scarce metals (Andersson et al 1998). Such materials then must, of course, be safeguarded by essentially closed-loop societal processes to ensure compliance with the SPs (Karlsson 1999). Thus, it must be ensured that such closed loops are economically viable or at least realistic over time.…”

Section: The Dynamics Of Dematerialization and Substitution Under Eacmentioning

confidence: 99%

Sustainability Constraints as System Boundaries: An Approach to Making Life‐Cycle Management Strategic

MacDonald

Broman

et al. 2006

J of Industrial Ecology

160

106

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SummarySustainable management of materials and products requires continuous evaluation of numerous complex social, ecological, and economic factors. A number of tools and methods are emerging to support this. One of the most rigorous is life-cycle assessment (LCA). But LCAs often lack a sustainability perspective and bring about difficult trade-offs between specificity and depth, on the one hand, and comprehension and applicability, on the other. This article applies a framework for strategic sustainable development (often referred to as The Natural Step (TNS) framework) based on backcasting from basic principles for sustainability. The aim is to foster a new general approach to the management of materials and products, here termed "strategic life-cycle management. " This includes informing the overall analysis with aspects that are relevant to a basic perspective on (1) sustainability, and (2) strategy to arrive at sustainability. The resulting overview is expected to help avoid costly assessments of flows and practices that are not critical from a sustainability and/or strategic perspective and to help identify strategic gaps in knowledge or potential problems that need further assessment. Early experience indicates that the approach can complement some existing tools and concepts by informing them from a sustainability perspective-for example, current product development and LCA tools.

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“…New Zealand's zero emissions housing, http://www.zeroplus.net.nz/) and toxicity (e.g. [22]), in implementing industrial ecology, to mention a few examples.…”

Section: Physical Modelsmentioning

confidence: 99%

Modelling sustainability

Todorov

Marinová

2011

Mathematics and Computers in Simulation

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The article presents a general classification of the models being developed in the area of sustainability arguing that the existing models represent the historical conceptualisation of sustainability starting from environmental constraints and moving towards economic valuation and social behaviour and policies. Coupled with computer power, sophisticated models with a varying levels of complexity have also been developed (static/dynamic; local/global; specific/general). However as any model is a simplification of the complex reality, the main purpose of any sustainability modelling (and the newly emerging area of sustainometrics) should be to allow dynamic representation, including the co-evolution of the sustainability systems and the role of humans as sustainability guardians.

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Closing the Technospheric Flows of Toxic Metals: Modeling Lead Losses from a Lead‐Acid Battery System for Sweden

Cited by 32 publications

References 18 publications

Applying Ecological Input‐Output Flow Analysis to Material Flows in Industrial Systems: Part I: Tracing Flows

Applying Ecological Input‐Output Flow Analysis to Material Flows in Industrial Systems: Part I: Tracing Flows

Sustainability Constraints as System Boundaries: An Approach to Making Life‐Cycle Management Strategic

Modelling sustainability

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