Research on the Geographical Pattern, Evolution Model, and Driving Mechanism of Carbon Emission Density from Urban Industrial Land in the Yangtze River Economic Belt of China

To achieve the goals of “carbon peaking and carbon neutrality”, this paper puts forward the connotation and measurement method for the carbon emission intensity of urban industrial land and conducts an empirical study with the Yangtze River Economic Belt (YREB) as an example. We defined the carbon i...

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Bibliographic Details
Published inISPRS international journal of geo-information Vol. 13; no. 6; p. 192
Main Authors Xie, Fei, Zhang, Shuaibing, Zhang, Qipeng, Zhao, Sidong, Lai, Min
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2024
Subjects
Autocorrelation
BCG
BCG vaccines
Carbon
Carbon cycle
carbon emission
China
Cities
Climate change
Construction
Decomposition
Density
Economic aspects
Economic development
Economic growth
Economic indicators
Economics
Emission measurements
Emissions
Emissions (Pollution)
Empirical analysis
Energy conservation
Energy consumption
Evolution
Foreign investments
Geospatial data
Globalization
Industrial emissions
industrial land
Innovations
Land use
Literature reviews
Measurement methods
Policies
Pollution
Population density
Principles
Rivers
Spatial planning
Synergistic effect
Urban areas
Urban planning
Urban policy
Yangtze River Economic Belt
China
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Summary:To achieve the goals of “carbon peaking and carbon neutrality”, this paper puts forward the connotation and measurement method for the carbon emission intensity of urban industrial land and conducts an empirical study with the Yangtze River Economic Belt (YREB) as an example. We defined the carbon intensity of urban industrial land as the industrial carbon emissions per unit area of land, which is a spatial mapping of urban industrial economic development and carbon spillover and a key indicator for urban and territorial spatial planning oriented towards the “dual carbon” goal. Findings: The carbon emission density of industrial land in the YREB varied greatly between cities and exhibited significant positive spatial autocorrelation. In addition, the geographical pattern and spatio-temporal evolution model of the urban industrial land carbon emission density had a very complex driving mechanism, and different factors had significant synergistic effects. Therefore, it is suggested that while striving towards the goal of “dual carbon”, the government should incorporate the carbon emission density indicator of urban industrial land into the urban and territorial spatial planning system, and based on the threshold of the medium suitable density, they should design differentiated management policies according to concrete urban policies and encourage cooperation among cities to jointly promote carbon emission management of urban industrial land. In policy design, emphasis should also be placed on highlighting the interactive effects of foreign direct investment, fiscal expenditure, and the number of patent authorizations as well as constructing a combination of policies centered around them to better leverage the impacts of globalization, government intervention, and innovation.
ISSN:2220-9964
2220-9964
DOI:10.3390/ijgi13060192