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The International Journal of Life Cycle Assessment

Erschienen in:

01.09.2012 | CARBON FOOTPRINTING

Time-adjusted global warming potentials for LCA and carbon footprints

verfasst von: Alissa Kendall

Erschienen in: The International Journal of Life Cycle Assessment | Ausgabe 8/2012

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Abstract

Purpose

The common practice of summing greenhouse gas (GHG) emissions and applying global warming potentials (GWPs) to calculate CO₂ equivalents misrepresents the global warming effects of emissions that occur over a product or system’s life cycle at a particular time in the future. The two primary purposes of this work are to develop an approach to correct for this distortion that can (1) be feasibly implemented by life cycle assessment and carbon footprint practitioners and (2) results in units of CO₂ equivalent. Units of CO₂ equilavent allow for easy integration in current reporting and policy frameworks.

Methods

CO₂ equivalency is typically calculated using GWPs from the Intergovernmental Panel on Climate Change. GWPs are calculated by dividing a GHG’s global warming effect, as measured by cumulative radiative forcing, over a prescribed time horizon by the global warming effect of CO₂ over that same time horizon. Current methods distort the actual effect of GHG emissions at a particular time in the future by summing emissions released at different times and applying GWPs; modeling them as if they occur at the beginning of the analytical time horizon. The method proposed here develops time-adjusted warming potentials (TAWPs), which use the reference gas CO₂, and a reference time of zero. Thus, application of TAWPs results in units of CO₂ equivalent today.

Results and discussion

A GWP for a given GHG only requires that a practitioner select an analytical time horizon. The TAWP, however, contains an additional independent variable; the year in which an emission occurs. Thus, for each GHG and each analytical time horizon, TAWPs require a simple software tool (TAWPv1.0) or an equation to estimate their value. Application of 100-year TAWPs to a commercial building’s life cycle emissions showed a 30 % reduction in CO₂ equivalent compared to typical practice using 100-year GWPs. As the analytical time horizon is extended the effect of emissions timing is less pronounced. For example, at a 500-year analytical time horizon the difference is only 5 %.

Conclusions and recommendations

TAWPs are one of many alternatives to traditional accounting methods, and are envisioned to be used as one of multiple characterizations in carbon accounting or life cycle impact assessment methods to assist in interpretation of a study’s outcome.

Vorheriger Artikel Life cycle assessment (LCA) applied to the process industry: a review

Nächster Artikel The influence of contaminants in the environmental impact of recovered paper: a life cycle assessment perspective

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As indicated earlier, a lack of significant digits reported for radiative efficiency, lifetime, and/or indirect effects in the IPCC methodology leads to differences between the GWP and TAWP, even when in theory they should be identical. For example, the TAWP₅₀₀(y = 10) for methane should be identical to the IPCC GWP₅₀₀, but in fact it deviates by 0.08 kg CO₂e.

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Titel: Time-adjusted global warming potentials for LCA and carbon footprints
verfasst von: Alissa Kendall
Publikationsdatum: 01.09.2012
Verlag: Springer-Verlag
Erschienen in: The International Journal of Life Cycle Assessment / Ausgabe 8/2012
Print ISSN: 0948-3349
Elektronische ISSN: 1614-7502
DOI: https://doi.org/10.1007/s11367-012-0436-5

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Abstract

Purpose

Methods

Results and discussion

Conclusions and recommendations

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Thank you, Almut!