Extension of Energy and Transport Scenario Modelling to Include a Life Cycle Perspective

Simon Pichlmaier; Michael Kult; Ulrich Wagner

doi:10.3390/futuretransp1020012

Extension of Energy and Transport Scenario Modelling to Include a Life Cycle Perspective

Simon Pichlmaier, Michael Kult, Ulrich Wagner

TUM Emeriti of Excellence

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

The paper outlines the methodology for the extension of the assessment of transport scenarios to include a life cycle perspective. When considering greenhouse gas emissions in the operational phase, the inclusion of the upstream chain increases emissions in conventional systems by only 17% to 19%. In transport systems that utilise a large share of electricity generated predominantly from renewable energies without direct emissions, this value can rise sharply. In the present case, up to 304%. The emissions currently associated with the production of the transport fleet correspond to 56 Mt CO₂e and thus 22% of total emissions. In most scenarios, however, this value decreases more slowly than the operational emissions. This increases the share of emissions caused by production. Thus, the inclusion of life cycle emissions is an important component for assessing sustainability.

Original language	English
Pages (from-to)	188-201
Number of pages	14
Journal	Future Transportation
Volume	1
Issue number	2
DOIs	https://doi.org/10.3390/futuretransp1020012
State	Published - Sep 2021

Keywords

energy system modelling
energy systems analysis
life cyle assessment
transport

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3390/futuretransp1020012

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title = "Extension of Energy and Transport Scenario Modelling to Include a Life Cycle Perspective",

abstract = "The paper outlines the methodology for the extension of the assessment of transport scenarios to include a life cycle perspective. When considering greenhouse gas emissions in the operational phase, the inclusion of the upstream chain increases emissions in conventional systems by only 17\% to 19\%. In transport systems that utilise a large share of electricity generated predominantly from renewable energies without direct emissions, this value can rise sharply. In the present case, up to 304\%. The emissions currently associated with the production of the transport fleet correspond to 56 Mt CO2e and thus 22\% of total emissions. In most scenarios, however, this value decreases more slowly than the operational emissions. This increases the share of emissions caused by production. Thus, the inclusion of life cycle emissions is an important component for assessing sustainability.",

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AU - Kult, Michael

AU - Wagner, Ulrich

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N2 - The paper outlines the methodology for the extension of the assessment of transport scenarios to include a life cycle perspective. When considering greenhouse gas emissions in the operational phase, the inclusion of the upstream chain increases emissions in conventional systems by only 17% to 19%. In transport systems that utilise a large share of electricity generated predominantly from renewable energies without direct emissions, this value can rise sharply. In the present case, up to 304%. The emissions currently associated with the production of the transport fleet correspond to 56 Mt CO2e and thus 22% of total emissions. In most scenarios, however, this value decreases more slowly than the operational emissions. This increases the share of emissions caused by production. Thus, the inclusion of life cycle emissions is an important component for assessing sustainability.

AB - The paper outlines the methodology for the extension of the assessment of transport scenarios to include a life cycle perspective. When considering greenhouse gas emissions in the operational phase, the inclusion of the upstream chain increases emissions in conventional systems by only 17% to 19%. In transport systems that utilise a large share of electricity generated predominantly from renewable energies without direct emissions, this value can rise sharply. In the present case, up to 304%. The emissions currently associated with the production of the transport fleet correspond to 56 Mt CO2e and thus 22% of total emissions. In most scenarios, however, this value decreases more slowly than the operational emissions. This increases the share of emissions caused by production. Thus, the inclusion of life cycle emissions is an important component for assessing sustainability.

KW - energy system modelling

KW - energy systems analysis

KW - life cyle assessment

KW - transport

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Extension of Energy and Transport Scenario Modelling to Include a Life Cycle Perspective

Abstract

Keywords

UN SDGs

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