Can Green Finance Be a Regulator of “Water–Energy–Food” Synergy? Evidence from the Yangtze River Delta
Abstract
:1. Introduction
2. Theoretical Analysis and Research Assumptions
2.1. Literature Review
2.2. The Impact of Green Finance on the WEF Synergy
2.3. Mechanisms for Green Finance to Influence WEF Synergy under Strategic Scenarios
2.3.1. Moderating Role of Digital Strategy
2.3.2. Moderating Role of “Dual Carbon” Strategy
2.3.3. Threshold Effect of New Urbanization Strategy
3. Materials and Methods
3.1. Samples
3.2. Model Setting
3.2.1. Network DEA Model
3.2.2. Coupled Coordination Degree Model
3.2.3. Fixed Panel Model
3.2.4. Simultaneous Equation Model
3.2.5. Moderated Effect Model
3.2.6. Threshold Effect Model
3.3. Variable Selection
3.4. Data Source
4. Results
4.1. Spatial and Temporal Evolution of WEF Synergy Level in YRD Cities
4.2. Benchmark Regression Results
4.3. Further Analysis
4.4. Robustness and Endogeneity Tests
4.5. Mechanism Analysis of National Strategies in Green Finance Influencing WEF Synergy
4.5.1. Moderating Effect Analysis
4.5.2. Threshold Effect Analysis
4.6. Differences in the Effects of Green Finance on Different Endowment Areas
5. Conclusions and Policy Implications
5.1. Conclusions
- (1)
- The WEF synergy level of the YRD city cluster shows an upward trend in general. However, it shows the distribution characteristics of high in the east and low in the west. Despite the high demand for resources in the YRD region, Zhang et al. found that Jiangsu and Zhejiang Provinces can import virtual water, implied energy, and implied arable land through trade networks, thus alleviating the problem of insufficient local resource supply [7]. This also explains to some extent why the study in this paper found the WEF synergy in Jiangsu and Zhejiang Provinces higher than in Anhui Province, compared to some studies. Having solved the problem of resource scarcity, Zhejiang and Jiangsu Provinces have achieved sustainable WEF synergy by virtue of higher resource utilization efficiency [71].
- (2)
- Green finance promotes the water subsystem efficiency and WEF synergy level in YRD cities but does not improve the energy and food subsystem efficiency. However, the nonlinear regression results show that the effect of green finance on both the WEF synergy level and the efficiency of each subsystem is inhibited before being promoted. These findings in general support the hypothesis that green finance can improve the level of WEF synergy. However, they also further expose some problems of green finance. In the previous period, in order to pursue rapid development, it failed to consider WEF synergy in a comprehensive manner, resulting in the inability of green finance to effectively support the efficiency improvement of various resource subsystems. This suggests that green finance, while expanding, is not supported in the same way in each of the areas involved. For example, the investment in agriculture is much lower than in the energy sector. At the same time, “greenwashing” leads to wasted funds for green finance and even exacerbates the waste of resources by investing funds in projects that are not in line with sustainable development. Therefore, it is necessary to standardize the criteria for green finance investment and to deploy funds to areas and fields where funds are scarce.
- (3)
- The digital strategy and the “dual carbon” strategy can positively regulate the impact of green finance on the level of WEF synergy. After urbanization crosses the threshold, the effect of green finance on the level of WEF synergy is more significant. Hou et al. found that the degree of informatization can enhance the environmental benefits of green finance, and that green finance improves the environment through digital finance [72]. After considering environmental factors, this paper further finds that digital strategy also enhances the contribution of green finance to WEF synergy. Huang et al. found that the economic consequences of green finance become worse under stricter environmental regulations. However, they also mentioned that the non-linear relationship is complex and does not imply that lower environmental regulations are better [61]. Therefore, environmental policies should be formulated in light of the characteristics of the region, such as the level of economic development and the level of technology. The above findings suggest that, in order to enhance synergies among sustainable policies, green finance needs to be deeply integrated with national strategies and, through the new technologies and models promoted by those strategies, look in a new direction for the development of the resource industry and improve the resource allocation capacity of green finance.
- (4)
- Compared with the comparison group, green finance enhances WEF synergy in non-resource cities, cities in non-main food-producing areas, cities not along the South-to-North water diversion route, and large cities. This suggests that green finance promotes WEF synergy primarily by supporting the development of regional scarce resources. For relatively abundant resources, green finance has to further increase the efficiency of abundant resources to reduce the consumption of abundant resources on other resources. Thus, while some studies have shown that green finance mitigates the problem of lower sustainable money growth rates in natural resource-rich countries than in countries with fewer natural resources, this does not tell us whether this economic growth is based on the synergy of resource systems. At the same time, Liu et al. found that green finance can indeed attenuate the negative impact of the resource curse on factor productivity to a certain extent (although the inhibitory effect is still larger overall) [73]. This paper does not deny this improvement function of green finance and only states that this effect is not significant enough to be demonstrated in the WEF synergy or that it needs to be further enhanced.
5.2. Policy Implications
- (1)
- Strengthening interregional integration of resources and realizing resource complementarity: Zhi et al. mentioned that the current water supply network between cities in the YRD still needs to be upgraded [74]. As mentioned earlier, strengthening trade links can also optimize the spatial allocation of resources. Therefore, integrated development should be promoted and administrative and trade barriers between regions should be reduced. The integrated development of resources is inseparable from the development of cross-regional infrastructure, so it is necessary to improve the layout of cross-regional water resources, energy, and other facilities. Large-scale resource facilities will be used as blood vessels connecting cities, meeting the development needs of regions with high resource consumption, and improving the economic efficiency of resource-exporting regions. In addition, the original infrastructure should be transformed with intelligent equipment. The Internet of Things and other technologies should be utilized to improve real-time monitoring and flexible scheduling of resources in order to ensure that regional resource supply meets demand.
- (2)
- Optimizing green financial policies and promoting the digital transformation of green finance: The government should enhance green finance categorization standards, both by strictly defining the criteria for projects to qualify for green ratings and by balancing the financing needs of the WEF system. It should eliminate “greenwashing” while preventing the waste of resources caused by the influx of funds into a single system. Regional governments should take into account the structure of local resource endowments and formulate green finance development strategies. For example, in setting up green financial reform demonstration zones, China has set different development goals based on the different economic and natural conditions of each region. Financial institutions should actively introduce financial technology and utilize it to create a green information base and enhance project screening capabilities, and make full use of past green information such as ESG disclosure reports and environmental violation tickets of enterprises.
- (3)
- Focus on urban development planning and make good use of environmental regulatory policies: Governments should balance the relationship between agriculture and industry, and between urban and rural areas, when formulating urban development plans. This should include mitigating disputes over agricultural and industrial water use and limiting the squeeze on agricultural land by industrial land for energy and other uses. When making investment choices, financial institutions should carefully consider policy risks and actively invest in projects consistent with sustainable development, such as green energy, green agriculture, and water recycling. For high-energy-consuming and high-polluting enterprises, now is the best time to transform. It is necessary to make full use of low-cost green finance to eliminate backward production methods. Otherwise, they will face increasingly stringent policy restrictions.
5.3. Limitations and Future Research
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Appendix A
Province/Municipality | Prefecture Level City |
---|---|
Shanghai Municipality | - |
Jiangsu Province | Nanjing, Suzhou, Wuxi, Nantong, Changzhou, Xuzhou, Yangzhou, Yancheng, Zhenjiang, Huaian, Lianyungang, Suqian |
Zhejiang Province | Hangzhou, Ningbo, Huzhou, Jiaxing, Shaoxing, Wenzhou, Quzhou, Lishui, Taizhou |
Zhejiang Province | Hefei, Wuhu, Bengbu, Huainan, Maanshan, Huaibei, Tongling, Anqing, Huangshan, Fuyang, Suzhou, Chuzhou, Lu’an, Xuancheng, Chizhou, Bozhou |
Appendix B
Appendix C
Name | |
---|---|
Bank list | Ping An Bank, Bank of Ningbo, Bank of Shanghai, Pudong Development Bank, Huaxia Bank, Minsheng Bank, China Merchants Bank, Bank of Jiangsu, Bank of Nanjing, Indus-trial Bank, Everbright Bank, Bank of Beijing, Bank of Shanghai, Agricultural Bank of China, Bank of Communications and Industrial and Commercial Bank of China, Construction Bank, Bank of China, Postal Savings Bank, CITIC Bank, Bank of Suzhou, Hangzhou Bank, Zheshang Bank, Guangfa Bank, Bohai Bank. |
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Variable | (1) | (2) |
---|---|---|
Gf | 0.0848 *** (3.45) | −0.2600 *** (−4.63) |
0.0278 *** (6.72) | ||
Pop | 0.0014 *** (3.52) | 0.0012 *** (3.23) |
Cc | −0.0022 (−0.56) | −0.0039 (−1.06) |
Rgdp | 0.0433 * (1.71) | 0.0823 *** (3.39) |
Inno | −0.0418 ** (−2.45) | −0.0206 (−1.27) |
Ind | −0.4618 *** (−3.95) | −0.1954 * (−1.68) |
Wt | 0.0018 ** (2.09) | 0.0012 (1.51) |
Constant | −0.0778 (−0.30) | 0.3687 (1.47) |
Individual—Time | Y | Y |
N | 342 | 342 |
0.2257 | 0.3303 |
Variable | (1) | (2) | (3) | (4) | (5) | (6) |
---|---|---|---|---|---|---|
WE | EE | FE | ||||
gf | 0.2543 *** (2.63) | −1.1139 *** (−6.00) | −0.4994 *** (−2.63) | −1.7544 *** (−3.26) | −0.3626 * (−1.83) | −1.7947 ** (−2.31) |
0.0954 *** (8.42) | 0.1136 *** (2.66) | 0.1471 ** (2.35) | ||||
L.EE | 0.0178 (0.50) | −0.1340 *** (−4.20) | ||||
L.FE | 0.1459 *** (3.95) | −0.1475 *** (−3.34) | ||||
WE | 0.3584 (0.98) | −1.0709 ** (−2.40) | 2.2336 *** (4.97) | −1.0205 (−1.36) | ||
EE | 0.0590 (0.46) | −0.3874 *** (−2.66) | ||||
Constant | 1.8610 (1.35) | 4.2508 *** (2.70) | −2.2835 * (−1.77) | 0.6145 (0.36) | −0.4453 (−0.54) | 2.4208 *** (2.94) |
Controls | Y | Y | Y | Y | Y | Y |
Individual—Time | Y | Y | Y | Y | Y | Y |
N | 304 | 304 | 304 | 304 | 304 | 304 |
Variable | (1) | (2) | (3) | (4) | (5) |
---|---|---|---|---|---|
xttobit | GMM | DID | |||
gf | 0.3578 *** (4.76) | −0.0310 (−0.21) | 0.1703 *** (4.00) | −0.4008 *** (−6.92) | |
0.0313 *** (3.01) | 0.0242 *** (6.50) | ||||
DID | 0.0293 ** (2.27) | ||||
L.DWEF | 0.8030 *** (12.73) | 0.2927 *** (9.14) | |||
Constant | 0.2396 (0.36) | 0.9249 (1.34) | −0.5419 * (−1.82) | 0.5844 * (1.88) | 0.9091 ** (2.56) |
Controls | Y | Y | Y | Y | Y |
Individual—Time | Y | Y | Y | Y | Y |
N | 342 | 342 | 304 | 304 | 304 |
LR test p-value | 0.000 | 0.000 | |||
Log-likelihood value | 155.49 | 159.97 | |||
Wald test | 115.44 *** | 128.72 *** | |||
AR(1) | 0.042 | 0.020 | |||
AR(2) | 0.175 | 0.346 | |||
Sargan | 0.914 | 0.473 | |||
Hansen | 0.876 | 0.757 |
Variable | (1) | (2) |
---|---|---|
Gf | −0.0083 (−0.15) | 0.0585 ** (2.34) |
Df | 0.0712 (0.63) | |
gf_df | 0.1051 *** (6.50) | |
Er | −0.0150 (−1.09) | |
df_er | 0.0483 *** (4.38) | |
Constant | −0.6752 * (−1.96) | −0.1868 (−0.74) |
Controls | Y | Y |
Individual—Time | Y | Y |
N | 342 | 342 |
0.3363 | 0.2832 |
Variable | (1) | (2) |
---|---|---|
City ≤ 82.90 | City > 82.90 | |
city ≤ 82.90 | 0.0437 ** (2.17) | 0.0726 *** (3.63) |
Constant | −0.0911 (−0.41) | |
Controls | Y | |
Individual—Time | Y | |
N | 342 | |
0.3659 |
Variable | (1) | (2) | (3) | (4) | (5) | (6) | (7) | (8) |
---|---|---|---|---|---|---|---|---|
gf | −0.0079 (−0.22) | 0.0877 *** (2.61) | 0.0209 (0.80) | 0.3059 *** (4.65) | 0.1135 (1.24) | 0.0817 *** (3.04) | 0.0017 (0.08) | 0.1354 ** (2.53) |
Constant | −0.5996 * (−1.94) | 0.4622 (1.15) | −0.2227 (−0.84) | 1.5371 * (1.72) | 0.1460 (0.11) | −0.1749 (−0.61) | −0.0544 (−0.27) | −0.4199 (−0.75) |
Individual—Time | Y | Y | Y | Y | Y | Y | Y | Y |
N | 98 | 244 | 252 | 90 | 72 | 270 | 171 | 171 |
0.5199 | 0.2380 | 0.2885 | 0.5002 | 0.2077 | 0.2723 | 0.3954 | 0.3244 |
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Wang, Y. Can Green Finance Be a Regulator of “Water–Energy–Food” Synergy? Evidence from the Yangtze River Delta. Sustainability 2024, 16, 4931. https://doi.org/10.3390/su16124931
Wang Y. Can Green Finance Be a Regulator of “Water–Energy–Food” Synergy? Evidence from the Yangtze River Delta. Sustainability. 2024; 16(12):4931. https://doi.org/10.3390/su16124931
Chicago/Turabian StyleWang, Yuchao. 2024. "Can Green Finance Be a Regulator of “Water–Energy–Food” Synergy? Evidence from the Yangtze River Delta" Sustainability 16, no. 12: 4931. https://doi.org/10.3390/su16124931
APA StyleWang, Y. (2024). Can Green Finance Be a Regulator of “Water–Energy–Food” Synergy? Evidence from the Yangtze River Delta. Sustainability, 16(12), 4931. https://doi.org/10.3390/su16124931