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个人简介
Professor Huang's research aims to discover new knowledge of microbial driven bioweathering of tailings minerals and associated biogeochemical processes and develop new technology and methodology for rehabilitating metal mine tailings.
The emerging technology is significantly different from conventional rehabilitation technology (such as soil remediation, phytoremediation and soil-capping), which essentially treat the tailings as engineered parent materials (rather than “soil” per se) and harness in situ microbial power purposely primed and enhanced to accelerate mineral bioweathering and secondary mineral formation, which underpin the development of suitable physicochemical properties and biological capacity in expected technosols and/or hardpans. In particular, research efforts are underway to understand geo-microbial mechanisms and processes in bioweathering primary minerals in various metal mine tailings (e.g., bauxite residues/red mud, Cu/Pb-Zn tailings), by means of Omics-approach (metagenomics/proteomics), advanced microscopic and microspectral tools (e.g., SEM-EDS, Confocal EM, Synchrotron-based XFM/XAS). The emerging technology and methodology are expected to deliver much needed knowledge and know-how to speed up metal mine tailings rehabilitation which has emerged as global economic and environmental liabilities. Professor Huang's research theme is of a multi-disciplinary nature, building on sciences of geomicrobiology, mineralogy, pedogenesis, soil microbial ecology, rhizosphere biology, and ecological dynamics of soil-plant systems.
The emerging technology is significantly different from conventional rehabilitation technology (such as soil remediation, phytoremediation and soil-capping), which essentially treat the tailings as engineered parent materials (rather than “soil” per se) and harness in situ microbial power purposely primed and enhanced to accelerate mineral bioweathering and secondary mineral formation, which underpin the development of suitable physicochemical properties and biological capacity in expected technosols and/or hardpans. In particular, research efforts are underway to understand geo-microbial mechanisms and processes in bioweathering primary minerals in various metal mine tailings (e.g., bauxite residues/red mud, Cu/Pb-Zn tailings), by means of Omics-approach (metagenomics/proteomics), advanced microscopic and microspectral tools (e.g., SEM-EDS, Confocal EM, Synchrotron-based XFM/XAS). The emerging technology and methodology are expected to deliver much needed knowledge and know-how to speed up metal mine tailings rehabilitation which has emerged as global economic and environmental liabilities. Professor Huang's research theme is of a multi-disciplinary nature, building on sciences of geomicrobiology, mineralogy, pedogenesis, soil microbial ecology, rhizosphere biology, and ecological dynamics of soil-plant systems.
研究兴趣
论文共 181 篇作者统计合作学者相似作者
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期刊级别
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Plant and Soilno. 1-2 (2024): 1-5
Yunjia Liu, Zeqi Wu, Tingrui Zhang, Jiachen Zhao,Chongyang Shen,Huaizhi Tang,Jianying Shang,Yuanfang Huang,Longbin Huang
SCIENCE OF THE TOTAL ENVIRONMENT (2024)
Plant and Soilno. 1-2 (2024): 25-41
Environmental pollution (Barking, Essex 1987) (2024): 124492-124492
ENVIRONMENTAL SCIENCE & TECHNOLOGYno. 51 (2023): 21744-21756
The New phytologistno. 4 (2023): 1417-1425
Zhōng-xī yī jiéhé hùlǐno. 7 (2023): 71-77
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作者统计
#Papers: 179
#Citation: 5275
H-Index: 35
G-Index: 65
Sociability: 6
Diversity: 0
Activity: 2
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