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School of Environment , Harbin Institute of Technology
School of Environment , Harbin Institute of Technology
News & Events
2026-06-29
IWA Executive Vice President Dr. Tao Li Visits the School of Environment for Mid-Term Review and Academic Exchange on the Global “Next Generation Sanitation Systems” Project
2026-05-11
Professor Wang Wei's research group from the School of Environment has made significant progress in the field of low-energy, low drug green water treatment
2026-04-23
Professor Li Zhilin’s research group, part of Professor Wang Aijie’s team at Harbin Institute of Technology, has made significant progress in the field of water pollution control and resource recycling
2026-02-28
Prof. Liang Heng and Tang Xiaobin’s team from Harbin Institute of Technology (HIT) engineering a biomimetic nanofiltration membrane with anti-Janus charge structure for Li+ recovery from waste lithium battery wastewater
Academic Exchange
The 1st International Conference on CO2 Conversion and Circular Carbon Economy (2025) Was Successfully Held in Shenzhen
Speaker:opening ceremony
Time: 2025-04-11
Location: Shenzhen
The Third Interdisciplinary PhD Innovation Forum on Environment and Life Health Sciences and the Second Frontier Forum for Engineering Master's and PhD Candidates at Harbin Institute of Technology Successfully Held
Speaker:Innovation Forum
Time: 2025-06-16
Location: The School of Environment
Research
Harbin Institute of Technology All Media (Youyuan Zhang, Xi Chen /Text; Xi Chen/Image). Recently, the research group led by Prof. Wei Wang from the School of Environment, Harbin Institute of Technology (HIT), under the guidance of Academician Jun Ma, has made significant progress in the field of low-energy, chemical-free green water treatment. The study, entitled “Ultrafast energy-neutral molecular oxygen activation via atomically adjacent bimetallic catalytic sites”, was published in Nature Communications and selected as an Editors’ Highlights article.Molecular oxygen (O2) activation is a fundamental catalytic process in energy conversion, green chemistry, and environmental remediation. As the most abundant natural oxidant, O2 is widely regarded as an ideal alternative to conventional chemical oxidants such as hydrogen peroxide, persulfate, and ozone. However, the triplet ground state of O2 imposes intrinsic spin-forbidden constraints, leading to sluggish electron transfer kinetics and significant reaction barriers. To overcome these limitations, existing O2 activation strategies typically rely on external energy inputs such as light, electricity, or heat, which compromise economic feasibility and sustainability. In contrast, energy-neutral O2 activation systems often suffer from isolated active sites, localized electronic states, and cumulative multi-step electron-transfer barriers, resulting in low reactive oxygen species (ROS) generation rates, insufficient catalytic activity, and rapid intermediate dissipation, thereby limiting practical applicability.Addressing this scientific and technological challenge, Prof. Wei Wang’s group proposed a novel strategy for molecular oxygen activation that requires neither external oxidants nor additional energy input. By constructing atomically adjacent bimetallic catalytic sites, the team leveraged d-d orbital coupling and electron delocalization to establish short-range, highly efficient electron-transfer pathways within the catalyst. This design enhances O2 adsorption and facilitates effective weakening of the O-O bond through π* orbital interactions, enabling direct and selective conversion of O2 into singlet oxygen (1O2) under mild conditions. Under bias-free conditions with simple aeration, the system achieved ROS generation rates and pollutant degradation performance comparable to those of conventional chemical oxidation processes, while reducing operational costs by approximately two orders of magnitude. Moreover, the catalyst demonstrated excellent stability and versatility in complex water matrices, showing broad applicability in organic pollutant degradation, inorganic ion transformation, and bacterial inactivation. This work establishes a new design paradigm for sustainable and efficient molecular oxygen activation and lays a solid foundation for the development of next-generation energy-neutral catalytic technologies.The activation mechanism of molecular oxygen electron transfer driven by adjacent dual-site cooperationHIT is the first corresponding institution of the paper.Xi Chen , a doctoral candidate from the School of Environment, is the first author. Associate Researcher Aiwen Wang, Prof. Dongmei Liu, and doctoral student Yang Cao , among others, are co-authors. Prof. Wei Wang serves as the corresponding author, and Prof. Xianwei Liu from the University of Science and Technology of China is co-corresponding author. Academician Jun Ma provided important guidance throughout the study.This research work was supported by the National Key Research and Development Program of China, the National Natural Science Foundation of China, the Natural Science Foundation of Heilongjiang Province of China, and the Independent Project of the State Key Laboratory of Urban -rural Water Resources and Environment.Paper link:https://doi.org/10.1038/s41467-025-67706-4
State Key Laboratory
National Engineering Research Center
2026-05-11
Professor Wang Wei's research group from the School of Environment has made significant progress in the field of low-energy, low drug green water treatment
2026-04-23
Professor Li Zhilin’s research group, part of Professor Wang Aijie’s team at Harbin Institute of Technology, has made significant progress in the field of water pollution control and resource recycling
InternitionalColleboration
2025-11-11
International Collaboration
The School of Environment at Harbin Institute of Technology promotes international cooperation with an open approach, establishing a diversified cooperation system covering education, scientific research, and talent exchange.Inter-institutional collaboration continues to deepen. Relying on platforms such as the Sino-Russian University Alliance of Engineering and Technology, we have launched cooper...
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School of Environment, Harbin Institute of Technology (HIT), 73 Huanghe Road, Nangang District, Harbin City, Heilongjiang Province, China
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