Acta Chimica Sinica ›› 2023, Vol. 81 ›› Issue (8): 979-989.DOI: 10.6023/A23040133 Previous Articles Next Articles
Special Issue: 庆祝《化学学报》创刊90周年合辑
Review
投稿日期:
2023-04-13
发布日期:
2023-09-14
作者简介:
侯威, 上海交通大学环境科学与工程学院2021级硕士研究生, 研究方向为电催化还原含氧酸根阴离子及其机制研究. |
么艳彩, 上海交通大学环境科学与工程学院长聘教轨副教授, 研究方向为电催化、单原子催化剂在环境、能源领域的应用. 以第一作者/通讯作者身份在Nat. Catal., J. Am. Chem. Soc., Angew. Chem., Int. Ed. (2篇)、Sci. Bull.等期刊发表多篇论文, 共3篇入选ESI高被引论文, 截至2023年4月发表论文累计被引用1200余次. 申请发明专利6项, 成果转化1项. 撰写英文专著1部. 曾获中科院“百篇优博论文”和中科院院长优秀奖. 先后获得国家自然科学基金、上海市科委面上项目、科技部重点研发计划项目子课题、博后站前特别资助及博士后面上资助等7项省部级项目资助. 现任Colloid and Surface Science编委. |
张礼知, 华中师范大学化学学院教授、上海交通大学特聘教授、博士生导师. 主要研究领域为污染控制化学、光催化及环境催化材料设计合成. 在Chem、Nat. Commun., J. Am. Chem. Soc., Angew. Chem., Int. Ed., Adv. Mater., Environ. Sci. Technol.等学术期刊发表论文360多篇, 其中29篇入选ESI高被引论文. 2011年获湖北省青年科技奖, 并入选湖北省自主创新“双百计划”, 2012年入选湖北省高端人才引领培养计划和湖北省高层次人才工程, 2014年起连续入选Elsevier发布“化学领域中国高被引学者榜单”, 2015年获教育部高等学校科学研究优秀成果奖(科学技术)自然科学二等奖(第一完成人), 2018年起连续入选Clarivate交叉领域全球高被引科学家榜单, 2019年获湖北省自然科学一等奖(第一完成人). |
基金资助:
Wei Hou, Yancai Yao(), Lizhi Zhang()
Received:
2023-04-13
Published:
2023-09-14
Contact:
*E-mail: yyancai@sjtu.edu.cn; zhanglizhi@sjtu.edu.cn
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Wei Hou, Yancai Yao, Lizhi Zhang. Advances in Electrochemical Reductive Removal of Oxyanions in Water★[J]. Acta Chimica Sinica, 2023, 81(8): 979-989.
电极材料 | 最佳电位/电流密度 | 活性(performance) | 能耗(Energy consumption) | 参考文献 |
---|---|---|---|---|
Bi1Pd | -0.6 V (vs. RHE) | 产氨速率为33.8 mg•h-1•cm-2, FE约为100% | N/A | [ |
Pd-Cu/γAl2O3 | 10 mA/cm2 | 氮气的选择性约为80.37% | N/A | [ |
Irnanotube | 0.06 V (vs. RHE) | 产氨速率为921 μg•h-1•mgcat-1, FE为84.7% | N/A | [ |
Strained Ru Nanoclusters | -0.20 V (vs. RHE) | 产氨速率为5.56 mol•gcat-1•h-1, FE为100% | N/A | [ |
Cu Nanosheets | -0.15 V (vs. RHE) | 产氨速率为390.1 g•mgCu-1•h-1, FE为99.7% | N/A | [ |
Cu(I)-N3C1 | -0.64 V (vs. RHE) | 硝酸盐去除率94.8% | 0.149 kWh/g-N | [ |
Fe single atom catalyst | -0.66 V (vs. RHE) | 产氨速率为0.46 mmol•h-1•cm-2, FE为75% | N/A | [ |
Co-CuOx | -1.1 V (vs. Ag/AgCl) | 硝酸盐去除率95.2%, N2选择性为96.0% | 0.60 kWh•m-3 | [ |
Co Nanoarray | -0.24 V (vs. RHE) | 产氨速率为10.4 mmol•h-1•cm-2, FE≥96% | N/A | [ |
电极材料 | 最佳电位/电流密度 | 活性(performance) | 能耗(Energy consumption) | 参考文献 |
---|---|---|---|---|
Bi1Pd | -0.6 V (vs. RHE) | 产氨速率为33.8 mg•h-1•cm-2, FE约为100% | N/A | [ |
Pd-Cu/γAl2O3 | 10 mA/cm2 | 氮气的选择性约为80.37% | N/A | [ |
Irnanotube | 0.06 V (vs. RHE) | 产氨速率为921 μg•h-1•mgcat-1, FE为84.7% | N/A | [ |
Strained Ru Nanoclusters | -0.20 V (vs. RHE) | 产氨速率为5.56 mol•gcat-1•h-1, FE为100% | N/A | [ |
Cu Nanosheets | -0.15 V (vs. RHE) | 产氨速率为390.1 g•mgCu-1•h-1, FE为99.7% | N/A | [ |
Cu(I)-N3C1 | -0.64 V (vs. RHE) | 硝酸盐去除率94.8% | 0.149 kWh/g-N | [ |
Fe single atom catalyst | -0.66 V (vs. RHE) | 产氨速率为0.46 mmol•h-1•cm-2, FE为75% | N/A | [ |
Co-CuOx | -1.1 V (vs. Ag/AgCl) | 硝酸盐去除率95.2%, N2选择性为96.0% | 0.60 kWh•m-3 | [ |
Co Nanoarray | -0.24 V (vs. RHE) | 产氨速率为10.4 mmol•h-1•cm-2, FE≥96% | N/A | [ |
电极材料 | 电化学活性/ (mmol•gcat-1•h-1) | 能耗/ (kWh•mmol-1) | 参考文献 |
---|---|---|---|
nZVI/ACF | 0.7×10-3 | 6.42 | [ |
Pd/rGO/CFP | 0.31 | N/A | [ |
Pd/NLSBC-800 | 2.4×10-3 | 1.998 | [ |
Pd-In/Al2O3 | 1.14×10-3 | N/A | [ |
RuCu/CNT | 15.12 | N/A | [ |
NG-Cu foam | N/A | N/A | [ |
电极材料 | 电化学活性/ (mmol•gcat-1•h-1) | 能耗/ (kWh•mmol-1) | 参考文献 |
---|---|---|---|
nZVI/ACF | 0.7×10-3 | 6.42 | [ |
Pd/rGO/CFP | 0.31 | N/A | [ |
Pd/NLSBC-800 | 2.4×10-3 | 1.998 | [ |
Pd-In/Al2O3 | 1.14×10-3 | N/A | [ |
RuCu/CNT | 15.12 | N/A | [ |
NG-Cu foam | N/A | N/A | [ |
电极材料 | ClO4-去除效率 | 能耗/(kWh•mmol-1) | 参考文献 |
---|---|---|---|
Ni | N/A | N/A | [ |
Ti | N/A | N/A | [ |
Rh | N/A | N/A | [ |
Pd/Pt-ACF | 53% | 17.9 | [ |
Pd/Pt-NACF | 81% | 9.9 | [ |
Rh/Cu | 78% | N/A | [ |
Rh/Ru | 60% | N/A | [ |
电极材料 | ClO4-去除效率 | 能耗/(kWh•mmol-1) | 参考文献 |
---|---|---|---|
Ni | N/A | N/A | [ |
Ti | N/A | N/A | [ |
Rh | N/A | N/A | [ |
Pd/Pt-ACF | 53% | 17.9 | [ |
Pd/Pt-NACF | 81% | 9.9 | [ |
Rh/Cu | 78% | N/A | [ |
Rh/Ru | 60% | N/A | [ |
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