| Title | A Measurement and Analysis of the Growth of Urban Green Total Factor Productivity--Based on the Perspective of Energy and Land Elements |
|---|---|
| ID_Doc | 33737 |
| Authors | Liu, P; Luo, ZM |
| Title | A Measurement and Analysis of the Growth of Urban Green Total Factor Productivity--Based on the Perspective of Energy and Land Elements |
| Year | 2022 |
| Published | |
| Abstract | From the perspective of input and output differentiation, using the SBM directional distance function method and Luenberger productivity index, this paper calculates the index of the green total factor productivity (GTFP) growth of 280 cities in China, from 2004 to 2016. This study also analyzes the growth sources of urban GTFP and the decomposition situation of GTFP in four cases, as well as the factors that affect the growth of GTFP. Finally, the following conclusions are drawn: 1) the overall growth trend of GTFP under four different situations of elements input is basically consistent. As a whole, the growth trend can be divided into three stages. The first rising stage of GTFP growth was from 2004 to 2008; the next declining stage was from 2008 to 2012, and a further rising stage occurred from 2012 to 2016. 2) From the decomposition situation of GTFP growth, we can know that the main source of GTFP growth is in the scale efficiency (LSEC) of GTFP. The decomposition of inefficiency levels in four cases shows that the inefficiency of land resources is the highest among many factors. Land resource inefficiency is also the key factor determining the output efficiency; the input inefficiency and bad-output inefficiency between them account for about 50% of the overall inefficiency level. 3) Among the factors that influence GTFP growth, the negative effect of urban land and energy structure is mainly reflected in the pure technology growth (LPTP) and scale efficiency growth (LSEC) of GTFP. In addition, investment in scientific and technological innovation and foreign direct investment both have a significantly positive effect on GTFP growth, as well as in improving urban population density and road area per capita. |
| https://www.frontiersin.org/articles/10.3389/fenvs.2022.838748/pdf |
Similar Articles
| ID | Score | Article |
|---|---|---|
18311
|
Zhou, RM; Zhang, YS Measurement of Urban Green Total Factor Productivity and Analysis of Its Temporal and Spatial Evolution in China(2023)Sustainability, 15.0, 12 | |
| 33614
|
Xu, YH; Deng, HT Green total factor productivity in Chinese cities: Measurement and causal analysis within a new structural economics framework(2022)Journal Of Innovation & Knowledge, 7.0, 4 | |
| 30342
|
Wang, HR; Cui, HR; Zhao, QZ Effect of green technology innovation on green total factor productivity in China: Evidence from spatial durbin model analysis(2021) | |
| 31783
|
Cui, HR; Wang, HR; Zhao, QZ Which factors stimulate industrial green total factor productivity growth rate in China? An industrial aspect(2019)Greenhouse Gases-Science And Technology, 9, 3 | |
| 33164
|
Chen, CF; Lan, QX; Gao, M; Sun, YW Green Total Factor Productivity Growth and Its Determinants in China's Industrial Economy(2018)Sustainability, 10.0, 4 | |
| 31844
|
Yao, YY; Hu, DD; Yang, CY; Tan, Y The impact and mechanism of fintech on green total factor productivity(2021)Green Finance, 3, 2 | |
| 32530
|
Liu, T; Li, Y Green development of China's Pan-Pearl River Delta mega-urban agglomeration(2021)Scientific Reports, 11, 1 | |
| 35253
|
Fan, M; Yang, P; Li, Q Impact of environmental regulation on green total factor productivity: a new perspective of green technological innovation(2022)Environmental Science And Pollution Research, 29, 35 | |
| 32993
|
Mao, JH; Wu, Q; Zhu, MH; Lu, CP Effects of Environmental Regulation on Green Total Factor Productivity: An Evidence from the Yellow River Basin, China(2022)Sustainability, 14.0, 4 | |
| 45116
|
Jiang, HL; Jiang, PC; Wang, D; Wu, JH Can smart city construction facilitate green total factor productivity? A quasi-natural experiment based on China's pilot smart city(2021) |