Assessing land-use impacts by clean vehicle systems

Transition of the current gasoline-based transportation system into a renewable fuel-based clean vehicle system has the potential to reduce greenhouse gas emissions and improve national energy security. However, the realized net environmental benefit or energy security improvement is tightly linked...

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Main Authors: Pontau, Patricia, Hou, Yi, Cai, Hua, Zhen, Yi, Jia, Xiaoping, Chiu, Anthony S.F., Xu, Ming
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Published: Animo Repository 2015
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Online Access:https://animorepository.dlsu.edu.ph/faculty_research/2710
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Institution: De La Salle University
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spelling oai:animorepository.dlsu.edu.ph:faculty_research-37092021-10-28T00:48:15Z Assessing land-use impacts by clean vehicle systems Pontau, Patricia Hou, Yi Cai, Hua Zhen, Yi Jia, Xiaoping Chiu, Anthony S.F. Xu, Ming Transition of the current gasoline-based transportation system into a renewable fuel-based clean vehicle system has the potential to reduce greenhouse gas emissions and improve national energy security. However, the realized net environmental benefit or energy security improvement is tightly linked to the electricity fuel mix (for electric cars and plug-in hybrids) and fueling strategy (for cars using alternative liquid fuels). In addition, different types of transportation fuels have significantly different demands on land resources, both on land type and quantity. For example, biofuel production requires large quantities of agricultural land, while wind farms require land with sufficient wind density. Furthermore, there is substantial regional variation in the quality of necessary resources. Regions with higher wind speeds require less land to produce the same amount of electricity than those with lower wind speed, assuming the same turbine design. Similarly, regions with optimal soil conditions and climate for crop cultivation require less land to produce the same amount of biofuel. To enable comparison of land demand among different fuel choices for clean vehicles, this research provides a county-scale assessment of land demand based on a "per-vehicle-mile-traveled" basis. Potential clean vehicle fuels assessed in this study include ethanol produced from different feedstocks (corn and switchgrass), biodiesel from algae cultivated in open ponds and closed systems, and electricity produced from renewable sources (wind and solar). Our results show that, in general, engineered systems (wind electricity, solar electricity, and biodiesel from closed-system algae) are more land efficient than natural systems (corn ethanol from corn starch and stover, switchgrass ethanol, and biodiesel from open-pond algae). Solar electricity is the dominant regional optimal fuel choice from the land-use perspective for engineered systems while lowland switchgrass ethanol and biodiesel from open-pond algae are the major optimal choices for the natural systems. These results shed light on developing both federal and state level policies to minimize land-use impact for the development of a clean vehicle system. © 2014 Elsevier B.V. All rights reserved. 2015-01-01T08:00:00Z text https://animorepository.dlsu.edu.ph/faculty_research/2710 Faculty Research Work Animo Repository Clean energy Biodiesel fuels Greenhouse gas mitigation Industrial Engineering Operations Research, Systems Engineering and Industrial Engineering
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
topic Clean energy
Biodiesel fuels
Greenhouse gas mitigation
Industrial Engineering
Operations Research, Systems Engineering and Industrial Engineering
spellingShingle Clean energy
Biodiesel fuels
Greenhouse gas mitigation
Industrial Engineering
Operations Research, Systems Engineering and Industrial Engineering
Pontau, Patricia
Hou, Yi
Cai, Hua
Zhen, Yi
Jia, Xiaoping
Chiu, Anthony S.F.
Xu, Ming
Assessing land-use impacts by clean vehicle systems
description Transition of the current gasoline-based transportation system into a renewable fuel-based clean vehicle system has the potential to reduce greenhouse gas emissions and improve national energy security. However, the realized net environmental benefit or energy security improvement is tightly linked to the electricity fuel mix (for electric cars and plug-in hybrids) and fueling strategy (for cars using alternative liquid fuels). In addition, different types of transportation fuels have significantly different demands on land resources, both on land type and quantity. For example, biofuel production requires large quantities of agricultural land, while wind farms require land with sufficient wind density. Furthermore, there is substantial regional variation in the quality of necessary resources. Regions with higher wind speeds require less land to produce the same amount of electricity than those with lower wind speed, assuming the same turbine design. Similarly, regions with optimal soil conditions and climate for crop cultivation require less land to produce the same amount of biofuel. To enable comparison of land demand among different fuel choices for clean vehicles, this research provides a county-scale assessment of land demand based on a "per-vehicle-mile-traveled" basis. Potential clean vehicle fuels assessed in this study include ethanol produced from different feedstocks (corn and switchgrass), biodiesel from algae cultivated in open ponds and closed systems, and electricity produced from renewable sources (wind and solar). Our results show that, in general, engineered systems (wind electricity, solar electricity, and biodiesel from closed-system algae) are more land efficient than natural systems (corn ethanol from corn starch and stover, switchgrass ethanol, and biodiesel from open-pond algae). Solar electricity is the dominant regional optimal fuel choice from the land-use perspective for engineered systems while lowland switchgrass ethanol and biodiesel from open-pond algae are the major optimal choices for the natural systems. These results shed light on developing both federal and state level policies to minimize land-use impact for the development of a clean vehicle system. © 2014 Elsevier B.V. All rights reserved.
format text
author Pontau, Patricia
Hou, Yi
Cai, Hua
Zhen, Yi
Jia, Xiaoping
Chiu, Anthony S.F.
Xu, Ming
author_facet Pontau, Patricia
Hou, Yi
Cai, Hua
Zhen, Yi
Jia, Xiaoping
Chiu, Anthony S.F.
Xu, Ming
author_sort Pontau, Patricia
title Assessing land-use impacts by clean vehicle systems
title_short Assessing land-use impacts by clean vehicle systems
title_full Assessing land-use impacts by clean vehicle systems
title_fullStr Assessing land-use impacts by clean vehicle systems
title_full_unstemmed Assessing land-use impacts by clean vehicle systems
title_sort assessing land-use impacts by clean vehicle systems
publisher Animo Repository
publishDate 2015
url https://animorepository.dlsu.edu.ph/faculty_research/2710
_version_ 1715215720914092032