The implications for energy crops under China's climate change challenges

This study investigated future bioenergy supply and demand from energy crops in China using the GCAM-integrated assessment model under different climate policy scenarios. The results indicated that China has rich resources of energy crops and marginal land for developing bioenergy. Under future carb...

Full description

Saved in:
Bibliographic Details
Published in:Energy economics 2021-04, Vol.96, p.105103, Article 105103
Main Authors: Zhang, Aiping, Gao, Ji, Quan, Jinling, Zhou, Bo, Lam, Shu Kee, Zhou, Yuyu, Lin, Erda, Jiang, Kejun, Clarke, Leon E., Zhang, Xuesong, Yu, Sha, Kyle, G.P., Li, Hongbo, Zhou, Sheng, Gao, Shuo, Wang, Wei, Guan, Yue
Format: Article
Language:English
Subjects:
Agricultural land
Agricultural production
Arable land
Carbon
Carbon tax
China
Climate change
Climate policy
Crop production
Crop residues
Crops
Cultivated lands
Cultivation
Deployment
Emissions
Energy
Energy crops
Energy economics
Environmental policy
Environmental tax
GCAM model
Grasslands
Integrated assessment
Land
Land resources
Land use
Mitigation
Pasture
Policies
Policy making
Population policy
Prices
Production
Renewable energy
Supply & demand
Taxation
Terrestrial environments
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This study investigated future bioenergy supply and demand from energy crops in China using the GCAM-integrated assessment model under different climate policy scenarios. The results indicated that China has rich resources of energy crops and marginal land for developing bioenergy. Under future carbon related policies, bioenergy production will considerably increase as projected by the GCAM. Current marginal land can completely meet the future bioenergy demand from energy crops by the end of this century in China. Although a high carbon tax would increase the agricultural market price, the bioenergy price does not affect the production of crop residue from which energy is generated. Also cultivated land resources would not be affected by increased competition for land from energy crops. In addition, forest areas will be preserved and greatly expand in China owing to the increased value of terrestrial carbon, and cropland will increase and expand into pasture, grasslands and other arable land. This conversion peaks in 2050 and decreases until 2090 in response to the increasing incomes and population in China. Climate policies with carbon taxes that include terrestrial carbon will likely reduce emissions from land-use changes, although land-use restrictions may lead to greater upward pressure on crop prices. Net cumulative emissions of land-use changes under two mitigation policies will be negative in 2050 and further decrease thereafter. It is important to note that energy crops and BECCS cause relatively low-cost to reduce carbon emissions. Efforts on policy designing to support cultivation of energy crops and to promote research and deployment of BECCS should be ramped up. •Current marginal land resource can meet future bioenergy supply from energy crops.•Bioenergy price does not affect production of the crop in China.•Cultivated land resources would not be affected by land from energy crops.•Climate policies with carbon taxes would reduce the emissions from land use change.
ISSN:0140-9883
1873-6181
DOI:10.1016/j.eneco.2021.105103