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Wang, Wei

Bibliometric Analysis of Greenhouse Gas Research on a Global Scale from 2000 to 2014

Abstract Views :242 | PDF Views:84

Authors

Wei Yang ¹, Haijin Zhou ¹, Fuqi Si ¹, Cheng Liu ², Wei Wang ¹, Youwen Sun ¹, Wenqing Liu ², Changgong Shan ²

Affiliations
1 Key Laboratory of Environmental Optics and Technology, Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Science, Hefei 230031, CN
2 University of Science and Technology of China, Hefei 230026, CN

Source

Current Science, Vol 114, No 08 (2018), Pagination: 1624-1631

Abstract

A bibliometric approach is used in this study for the assessment of greenhouse gas (GHG) research trends on a global scale. The relevant literature published from 2000 to 2014 in journals of all subject categories of the Science Citation Index Expanded from the Web of Science Core Collection databases has been used. The strings ‘greenhouse gas*’ or ‘green house gas*’ are used for retrieving data. The information of GHG research-related literature is analysed, including the types and languages of literature, characteristics of articles published, source countries/territories of articles, distribution of articles in different subject categories and journals, frequency/number of words in the title of articles and the frequency/number of keywords used. Over the past 15 years, an obvious growth trend is seen in the number of published articles, and countries/territories involved in the study of GHG. The number of the world articles published by the seven most developed industrialized countries (G7) is maximum in the field of GHG research. The G7 countries have played a predominant role in GHG research in the last 15 years. Analysis of the title words, author keywords and keywords plus showed that ‘greenhouse gas emission’ and ‘climate change’ were the keywords with highest frequency during the whole research period. Carbon sequestration and biotechnology have been widely used in reducing the environmental pressure of the greenhouse effect and the dependence on fossil energy.

Keywords

Bibliometric Analysis, Climate Change, Global Trends, Greenhouse Gas Research, SCI.

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References

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Full-Parameter Optimization to Locate Multi-Passage-Seepage in Abutment Using Groundwater Temperature

Abstract Views :165 | PDF Views:83

Authors

Xinjian Wang ¹, Wei Wang ²

Affiliations
1 North China University of Water Resources and Electric Power, Zhengzhou, 450011, IN
2 Henan Geology and Mineral Construction Engineering Group Co LTD, Zhengzhou, 450007, IN

Source

Current Science, Vol 120, No 7 (2021), Pagination: 1233-1240

Abstract

With groundwater temperature, hybrid-genetic algorithm is employed to locate multi-passage concentrated seepage underground to increase the probability of optimal global solutions, calculation efficiency and precision. The parameters of concentrated seepage passages (CSPs) indicated initially by the previous optimization and attraction basins of modified temperature residuals are evaluated again by the proposed full parameter optimization. The smaller CSP impacts on the stronger are eliminated, since all the parameters associated with all the CSPs are calculated by the last one-off optimization. In this case, three optimization steps are implemented with crossover fractions of 0.8, 0.5 and 0.45 (0.3), and the modified resultant residuals are 13.441, 2.27 and 0.7 individually. Results of this method are more effective compared to those from other methods and actual applications.

Keywords

Abutment, Dam Safety, Hybrid-Genetic Algorithm, Geothermal Temperature, Seepage.

Full Text

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