• Energy Research

Abstract The development of the regional economy in China is unbalanced. Interregional "carbon leakage" and "carbon transfer" have a significant impact on the realization of carbon emission mitigation targets and the allocation of responsibility. Using China's interregional input-output tables and the corresponding carbon emission data for 2007 and 2010, this paper proposes an interregional Ghosh input-output model and estimates the amount of interprovincial carbon emission transfer from the supply-side perspective. We find that the main direction of supply-side carbon emission transfer is from resource-intensive provinces in the central and western regions to developed provinces in the eastern coastal regions. Further analysis shows that the transfer is mainly concentrated in the production and distribution of electricity and heat, nonmetallic mineral products, and basic metals, whose carbon emissions account for approximately 70% of all sectors’ carbon emissions. The differences between the supply side and the demand side of China's provinces are mainly reflected in the transfer out of carbon emissions.

Abstract Cities consume more than 67% of global primary energy, the production of which results in approximately three-quarters of global CO2 emissions, exacerbating the global warming trend and related extreme weather events and natural disasters. Therefore, it is critical for cities to use existing and new sources of energy efficiently and effectively. This paper introduces a methodology that can combine sustainable energy planning with economic analysis, proposing a form of sustainable urban energy planning that could reduce energy consumption with the minimum economic cost. Taking a postindustrial city (Shenzhen, China) as an example, this paper defines four scenarios by which to analyze future projections of energy generation and consumption from 2015 to 2030 based on the Long-range Energy Alternatives Planning System model. Also developed are Sankey maps for the energy flow from the energy supply to demand sectors for different scenarios. The results show that energy efficiency improvement and energy structure upgrade policies implemented in Shenzhen would have a significant impact on its energy system. Energy consumption is projected to increase steadily up to 2030 under each scenario except for the Peak Scenario, but with different growth rates. Electricity generation in all scenarios is supposed to expand by 2030 and sustainable electricity (such as distributed photovoltaic power, waste-to-energy power, and Combined Cooling, Heating, and Power) will play an important role in the Energy structure upgrade and Peak scenarios.