Estimation of water demand of the three major Brazilian shale-gas basins: Implications for water availability

Michael, M.; Parente, Virgínia; Santos, Edmílson Moutinho dos

doi:10.1016/j.enpol.2022.113170

Cited by 3 publications

(2 citation statements)

References 34 publications

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“…Improve relevant laws and regulations, and mine under the premise of laws; Putting people first and ensuring people's safety. Improving government regulatory policies and establishing laws and regulations to improve water resources' strange ability can also constrain the generation of water resources risks from the outside [9]. Improve the construction quality standard of storage facilities, reduce the risk of spillage or leakage, and build and improve the monitoring system.…”

Section: Government Measures For Risk Preventionmentioning

confidence: 99%

Investigation on Water Resource Risk of Shale Gas Exploration and Development

Liu¹,

Yu²,

Li³

et al. 2023

Advances in Economics, Business and Management Research

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For the Sichuan basin of China, water resources are scattered in various regions, limiting the development of shale gas. Exploitation of shale gas has undoubtedly aggravated the contradiction between supply and demand of water resources. For this problem, from the enterprise level, use technological innovation, control the source, and use technological progress to make up for the shortcomings of energy development and water resource health. Strengthen the whole process supervision, set up monitoring points in an all-round way before mining, during mining and after mining, and regularly monitor the water quality and water body in the mining area. For the government, scientific and technological innovation should be encouraged, relevant laws and regulations and industry regulatory system should be improved, resource allocation should be optimized by various means, and regional shale gas development strategy should be scientifically and systematically planned.

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Section: Government Measures For Risk Preventionmentioning

confidence: 99%

Investigation on Water Resource Risk of Shale Gas Exploration and Development

Liu¹,

Yu²,

Li³

et al. 2023

Advances in Economics, Business and Management Research

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“…In recent years, water scarcity has become a major bottleneck constraining sustainable socio-economic development due to the uncontrolled exploitation of water resourses by human beings and changes in the climate [1,2]. In response to this problem, many countries have begun to pay attention to the prediction of future water demand, which is used to guide water resource planning and management to meet the challenges of sustainable water resource utilization [3,4]. In the past, it was traditionally recognized that population growth, economic growth, improved living standards, and the resulting changes in lifestyles tended to increase water demand and that total water use would continue to grow with socio-economic development [5,6].…”

Section: Introductionmentioning

confidence: 99%

The Driving Effects of the Total Water Use Evolution in China from 1965 to 2019

Wang,

Qin,

Han

2023

Water

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To understand the influence mechanism of the total water use evolution in a certain region more deeply, it is necessary to accurately identify the driving effects of the total water use evolution, and quantitatively analyze the influence of the driving effects on the total water use evolution. In this research, we studied the driving effects of the total water use evolution in China from the perspective of multi-year long time-series in the whole country for the first time. Through the logarithmic mean Divisia index (LMDI) decomposition method, we constructed an LMDI decomposition model for the regional total water use evolution, and decomposed the total water use evolution in China and its five stages from 1965 to 2019 into the water use intensity effect (WUIE), sector proportion effect (SPE), per capita total economy effect (PCTEE), and total population effect (TPE). We also considered the driving effects of the total water use evolution when the population or economic proportion changed in the six major districts in China for the first time. Based on the LMDI decomposition method, we separately added the district population proportion variable and the district economic proportion variable to contrast a logarithmic mean Disivia index-population (LMDI-P) decomposition model and a logarithmic mean Divisia index-economic (LMDI-E) decomposition model for the regional total water use evolution. Compared with the LMDI decomposition model, the district population proportion effect (DPPE) and the district economic proportion effect (DEPE) were separately added. We calculated the value and proportion of the driving effects of the total water use evolution in China and analyzed their influence mechanisms. Our findings provide better decision-making reference for water resource planning and management in China. The results show the following: (1) According to the overall situation from 1965 to 2019, the prohibitive role played by the PCTEE (total 22,263.79 × 108 m3) and the TPE (total 2945.38 × 108 m3) with respect to the total water use increasing in China offset the inhibitive role played by the WUIE (total −16,094.31 × 108 m3) and the SPE (total −5930.02 × 108 m3) with respect to the total water use increasing in China; (2) According to the overall situation from 1965 to 2019, both the DPPE and DEPE had heterogeneity in the total water use evolution in the six major districts in China. The DPPE played a prohibitive role in the three population inflow districts (Southeast China, Central South China, and Northwest China) with respect to the total water use increasing (total 291.09 × 108 m3), and an inhibitive role in the other three population outflow districts (North China, Central South China, and Southwest China) with respect to the total water use increasing (total −207.78 × 108 m3). The DEPE played a prohibitive role in the three economically developed districts (North China, Southeast China, and Central South China) with respect to the total water use increasing (total 428.26 × 108 m3), and an inhibitive role in the other three economically underdeveloped districts (Northeast China, Southwest China, and Northwest China) with respect to the total water use increasing (total −477.74 × 108 m3).

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Replenishable but Depletable Resource: Water

Deng,

Song,

et al. 2024

Environmental and Natural Resources Economics

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Estimation of water demand of the three major Brazilian shale-gas basins: Implications for water availability

Cited by 3 publications

References 34 publications

Investigation on Water Resource Risk of Shale Gas Exploration and Development

Investigation on Water Resource Risk of Shale Gas Exploration and Development

The Driving Effects of the Total Water Use Evolution in China from 1965 to 2019

Replenishable but Depletable Resource: Water

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