项目来源

美国国家科学基金(NSF)

项目主持人

Huichun Zhang

项目受资助机构

TEMPLE UNIVERSITY

项目编号

1507981

立项年度

2015

立项时间

未公开

项目级别

国家级

研究期限

未知 / 未知

受资助金额

300000.00美元

学科

未公开

学科代码

未公开

基金类别

Standard Grant

关键词

Environmental Chemical Science ; Sustainable Chemistry

参与者

未公开

参与机构

未公开

项目标书摘要：With this award,the Environmental Chemical Sciences Program of the Division of Chemistry is funding Professor Huichun J.Zhang of Temple University to examine the nitrogen-oxygen single bond(N-O)as a reducible functional group toward reductive transformations under environmental conditions.The introduction of N-O containing contaminants(NOCs)into aquatic environments is an important emerging water issue.This project aims to develop accurate environmental risk assessment of NOCs and to develop advanced technologies to effectively treat NOCs contaminated water and sites.The findings are expected to help guide the chemical industry to design more environmentally-friendly chemical products.The project is expected to broaden participation from underrepresented minorities and women in environmental chemistry/engineering and to provide training for future scientists and engineers in this cross-disciplinary area.This project focuses on examining reduction kinetics and mechanisms of a diverse range of NOCs by soluble Fe(II)species through a combination of experimental and theoretical approaches.Advanced experimental approaches,including kinetic,electrochemical cell,isotopic,spectroscopic and chromatographic approaches,are to be conducted to elucidate key elementary steps in NOC reductions,such as protonation,complexation,electron transfer and N-O bond cleavage.The most likely rate-limiting step of each subset of NOCs is to be identified by characterizing all of the stationary points in the relevant elementary steps along the reaction pathway.Molecular descriptors are being computed to develop quantitative structure-activity relationships so as to provide the community with quantifiable and experimentally grounded numbers that pertain to the susceptibility of N-O bonds to reductive cleavage in the environment.