钱傲

发布者：王鹏发布时间：2025-09-06浏览次数：399

博士，讲师

2023.9至今江汉大学环境与健康学院

2019.7-2023.8 中国地质大学（武汉）生物地质与环境地质国家重点实验室博士后

2014.9-2019.6 中国地质大学（武汉）环境学院获环境科学与工程博士学位

2016.9-2017.9 美国圣路易斯华盛顿大学，能源、环境和化学工程系，公派联合培养博

士研究生

2012.9-2014.6 中国地质大学（武汉）环境学院硕士研究生

2008.9-2012.6 原华中科技大学文华学院城市建设工程学部获工学学士学位

研究方向：矿物界面化学及其环境效应

项目：

1.国家自然科学基金青年科学基金：还原态含铁黏土矿物向铁（氢）氧化物传递电子的规律与受控机制（42102040，2022-2024），主持

2.中国博士后科学基金面上项目：吸附态Fe(II)有氧氧化产生活性氧化物种及转化污染物机制（2020M672438，2020-2022），主持

3.国家自然科学基金杰出青年科学基金项目：地下水动态变化环境过程与污染修复，参与

4.国家自然科学基金优秀青年科学基金项目：地下环境有害物质迁移转化与修复机理，参与

5.国家自然科学基金面上项目：低渗透黏土介质在氧化扰动下长距离电子传递规律与受控机制，参与

6.国家自然科学基金青年科学基金项目：还原态含铁粘土矿物活化氧气产生羟基自由基机理，参与

文章：

1. Yu C. L.^#, Qian A.^#, Lu Y. X., Liao W. J., Zhang P., Tong M., Dong H. L., Zeng Q., Yuan S. H.* Electron transfer processes associated with structural Fe in clay minerals. Critical Reviews in Environmental Science and Technology, 2023. 54, 13–38. (^#共同第一作者, IF=12.6)

2. Qian A., Lu Y. X., Zhang Y. T., Yu C. L., Zhang P., Liao W. J., Yao Y., Zheng Y. S., Tong M., Yuan S. H. Mechanistic insight into electron transfer from Fe(II)-bearing clay minerals to Fe (hydr)oxides. Environmental Science & Technology, 2023. 57, 8015–8025. (IF=11.4, Nature Index期刊)

3. Qian A., Pan C., Yuan S. H., Giammar D. E. Cr(VI) formation from Cr_xFe_1-x(OH)₃ induced by Mn(II) oxidation on the surface of Cr_xFe_1-x(OH)₃. ACS Earth and Space Chemistry, 2020, 4, 1558‒1564. (IF=3.4)

4. Qian A., Yuan S. H., Xie S. W., Tong M., Zhang P., Zheng Y. S. Oxidizing capacity of iron electrocoagulation systems for refractory organic contaminant transformation. Environmental Science & Technology, 2019, 53, 12629–12638. (IF=11.4, Nature Index期刊)

5. Qian A., Zhang W., Shi C., Pan C., Giammar D. E., Yuan S. H., Zhang H. L., Wang Z. M. Geochemical stability of dissolved Mn(III) in the presence of pyrophosphate as a model ligand: complexation and disproportionation. Environmental Science & Technology, 2019, 53, 5768–5777. (IF=11.4, Nature Index期刊，封面论文)

6. Qian A., Yuan S. H., Zhang P., Tong M. A new mechanism in electrochemical process for arsenic oxidation: production of H₂O₂ from anodic O₂ reduction on the cathode under automatically developed alkaline conditions. Environmental Science & Technology, 2015, 49, 5689–5696. (IF=11.4, Nature Index期刊)

7. Qian A., Liao P., Yuan S. H., Luo M. S. Efficient reduction of Cr(VI) in groundwater by a hybrid electro-Pd process. Water Research, 2014, 48, 326–334. (IF=12.8, Nature Index期刊)

8. Liao W. J., Peng W., Liao P., Xiao Y. Q., Xie W. J., Qian A., Ning Y. Q., Zhang N., Niyuhire E., Cui H. J. Natural sediments activating peroxydisulfate for in situ degradation of antibiotics under anoxic conditions: The critical role of surface-adsorbed and structural Fe(II). Chemical Engineering Journal, 2023, 472, 144938.

9. Zhang Y. T., Zhang N., Qian A., Yu C. L., Zhang P., Yuan S. H. Effect of C/Fe molar ratio on H₂O₂ and •OH production during oxygenation of Fe(II)-humic acid coexisting systems. Environmental Science & Technology, 2022, 56, 13408‒13418.

10. Yu C. L., Lu Y. X., Zhang Y. T., Qian A., Zhang P., Tong M., Yuan S. H. Significant contribution of solid organic matter for hydroxyl radical production during oxygenation. Environmental Science & Technology, 2022, 56, 11878‒11887.

11. Xie S. W., Li C., Liao P., Wang J. F., Chen J. G., Qian A., Zhang Y., Wei T. Y., Cheng D., Jia M. Q. Experimental and modeling evidence of hydroxyl radical production in iron electrocoagulation as a new mechanism for contaminant transformation in bicarbonate electrolyte. Water Research, 2022, 220, 118662.

12. Yu C. L., Zhang Y. T., Lu Y. X., Qian A., Zhang P., Cui Y. P., Yuan S. H. Mechanistic insight into humic acid-enhanced hydroxyl radical production from Fe(II)-bearing clay mineral oxygenation. Environmental Science & Technology, 2021, 55, 13366‒13375.

13. Zhang Y. T., Tong M., Yuan S. H., Qian A., Liu H. Interplay between iron species transformation and hydroxyl radicals production in soils and sediments during anoxic-oxic cycles. Geoderma, 2020, 370, 114351.

14. Cheng D., Neumann A., Yuan S. H., Liao W. J., Qian A. Oxidative degradation of organic contaminants by FeS in the presence of O₂. Environmental Science & Technology, 2020, 54, 4091‒4101.

15. Pan C., Liu H., Catalano J., Wang Z. M., Qian A., Giammar D. Understanding the roles of dissolution and diffusion in Cr(OH)₃ oxidation by δ-MnO₂. ACS Earth and Space Chemistry, 2019, 3, 357‒365.

16. Niyuhire E., Yuan S. H., Liao W. J., Zhu J., Liu X. X., Xie W. J., Qian A. Sulfide drives hydroxyl radicals production in oxic ferric oxyhydroxides environments. Chemosphere, 2019, 234, 450‒460.

17. Liao W. J., Ye Z. L., Yuan S. H., Cai Q. Z., Tong M., Qian A., Cheng D. Effect of coexisting Fe(III) (oxyhydr)oxides on Cr(VI) reduction by Fe(II)-bearing clay minerals. Environmental Science & Technology, 2019, 53, 13767‒13775.

18. Zhu J., Zhang P., Yuan S. H, Liao P., Qian A., Liu X. X., Tong M., Li L. N. Production of Hydroxyl radicals from oxygenation of simulated AMD due to CaCO₃-induced pH increase. Water Research, 2017, 111, 118‒126.

19. Pan C., Liu H., Catalano J., Qian A., Wang Z. M., Giammar D. Rates of Cr(VI) generation from Cr_xFe_1-x(OH)₃ solids upon reaction with manganese oxide. Environmental Science & Technology, 2017, 51, 12416‒12423.

20. 胡珊琼，钱傲*，袁松虎，过氧化氢氧化Cr(III)_xFe(III)_1-x(OH)₃产生六价铬的规律与机制，安全与环境工程，2022，29，164‒174。

获奖：

2019年12月湖北省自然科学奖二等奖，地下水修复电化学调控机理与方法，排名第三

2016年5月国家留学基金委联合培养博士研究生奖学金

2016–2018年中国地质大学（武汉）优秀博士论文创新基金

2015年10月博士研究生国家奖学金

2015年10月中国地质大学（武汉）第二十六届研究生科技论文报告会一等奖

2014年7月中国地质大学（武汉）优秀研究生

2013年10月硕士研究生国家奖学金