基本信息
姓 名:杜洪方
职 称:副教授
学 位:理学博士
政治面貌:中共党员
学 科:柔性电子学、化学、材料科学
邮 箱:ifehfdu@fjnu.edu.cn
联系地址:福建省福州市福建师范大学旗山校区海峡柔性电子(未来科技)学院科研实验15号楼1221
教育情况与工作经历
2024.01 — 今,福建师范大学,海峡柔性电子(未来科技)学院,副教授,硕导
2022.04 — 2023.12,福建师范大学,海峡柔性电子(未来科技)学院,讲师,硕导
2018.08 — 2022.03,西北工业大学,柔性电子研究院,讲师,硕导
2016.07 — 2018.03,新加坡南洋理工大学,数理学院,研究助理
2012.09 — 2018.07,西南大学,材料与能源学院,理学博士,导师:李长明 教授
研究方向
1. 高效电催化,包括电解水制氢、电化学合成氨、电化学固碳等
2. 功能纳米材料表界面设与可控合成
3. 柔性电子材料与器件
诚挚欢迎具有化学、材料、物理等背景的同学来海峡柔性电子(未来科技)学院一起探索和研究。
取得成绩
围绕功能纳米材料的表界面设计合成及其在多种电催化体系中的潜在应用展开研究,致力于解决制约电化学催化转化效率的关键科学问题。目前获得4项省部级自然科学基金的资助,在Advanced Materials, Advanced Functional Materials, Applied Catalysis B: Environmental、Small、Journal of Materials Chemistry A等国际知名期刊上发表一/通讯作者论文20余篇,申请中国发明专利10项,相关研究荣获陕西高等学校科学技术研究优秀成果奖一等奖。
论文代表
1. Du, Hongfang; Wang, Tingfeng; He, Song; Li, Boxin; Wang, Ke; Chen, Qing; Du, Zhuzhu; Ai, Wei*; Huang, Wei*. Mountain-shaped nickel nanostripes enabled by facet engineering of nickel foam: a new platform for high-current-density water splitting, Advanced Functional Materials, 2024, 2311854.
2. Li, Boxin; Wang, Ke; He, Song; Du, Hongfang*; Wang, Tingfeng; Du, Zhuzhu; Ai, Wei*. Boosted hydrogen evolution via molten salt synthesis of vacancy-rich MoSxSe2–x electrocatalysts, ACS Sustainable Chemistry & Engineering, 2024, DOI: 10.1021/acssuschemeng.3c07215.
3.Liu, Lei; Li, Boxin; Wang, Jiaqi; Du, Hongfang; Du, Zhuzhu; Ai, Wei*. Molecular intercalation enables phase transition of MoSe2 for durable na-ion storage, Small, 2024, 2309647.
4.He, Song; Wang, Ke; Li, Boxin; Du, Hongfang*; Du, Zhuzhu; Wang, Tingfeng; Li, Siyu; Ai, Wei*; Huang, Wei*. The secret of nanoarrays toward efficient electrochemical water splitting: a vision of self-dynamic electrolyte, Advanced Materials, 2023, 35, 2307017.
5.Liu, Zhenjin; Yang, Jiaqi; Wang, Haiwei; Zhang, Jiaxin; Bai, Hua; Peng, Bo; Ai, Wei; Du, Hongfang*; Li, Lin*; Chen, Peng*. Recent progress in mitochondrial biofuel cells, Journal of Electroanalytical Chemistry, 2023, 950, 117881.
6.Liu, Yuhang; He, Chen; Bi, Jingxuan; Li, Siyu; Du, Hongfang*; Du, Zhuzhu; Guan, Wanqing; Ai, Wei*. High-areal capacity, high-rate lithium metal anodes enabled by nitrogen-doped graphene mesh, Small, 2024, 20, 2305964.
7.Chen, Ben; Li, Boxin; Bi, Jingxuan; Du, Hongfang*; Wang, Siying; Liu, Lei; Xie, Linghai; Sun, Jinmeng*; Du, Zhuzhu; Ai, Wei*. Li+ mobility powered by a crystal compound for fast Li–S chemistry, Chemical Communications, 2023, 59, 12140.
8.Wang, Ke; He, Song; Li, Boxin; Du, Hongfang*; Wang, Tingfeng; Du, Zhuzhu; Xie, Linghai; Ai, Wei*. Relaying alkaline hydrogen evolution over locally amorphous Ni/Co-based phosphides constructed by diffusion-limited phase-transition, Applied Catalysis B: Environmental, 2023, 339, 123136.
9.Du, Zhuzhu; Yang, Kai; Du, Hongfang*; Li, Boxin; Wang, Ke; He, Song; Wang, Tingfeng; Ai, Wei*. Facile and scalable synthesis of self-supported Zn-doped cuo nanosheet arrays for efficient nitrate reduction to ammonium, ACS Applied Materials & Interfaces, 2023, 15, 5172.
10.Liu, Lei#; Du, Zhuzhu#; Wang, Jiaqi; Du, Hongfang*; Wu, Sheng; Li, Mengjun; Zhang, Yixuan; Sun, Jinmeng; Sun, Zhipeng*; Ai, Wei*. Fast-charging sodium-ion batteries enabled by molecular-level designed nitrogen and phosphorus codoped mesoporous soft carbon, Research, 2023, 6, 0209.
11.Du, Hongfang#; Du, Zhuzhu#; Wang, Tingfeng; Li, Boxin; He, Song; Wang, Ke; Xie, Linghai; Ai, Wei*; Huang, Wei*. Unlocking interfacial electron transfer of ruthenium phosphides by homologous core–shell design toward efficient hydrogen evolution and oxidation, Advanced Materials, 2022, 34, 2204624.
12.Du, Hongfang#; Du, Zhuzhu#; Wang, Tingfeng; He, Song; Yang, Kai; Wang, Ke; Xie, Linghai; Ai, Wei*; Huang, Wei*. Interface engineering of tungsten carbide/phosphide heterostructures anchored on N,P-codoped carbon for high-efficiency hydrogen evolution reaction, Science China Materials, 2021, 184, 177.
13.Wang, Ke; Du, Hongfang*; He, Song; Liu, Lei; Yang, Kai; Sun, Jinmeng; Liu, Yuhang; Du, Zhuzhu; Xie, Linghai; Ai, Wei*; Huang, Wei*. Kinetically controlled, scalable synthesis of γ-FeOOH nanosheet arrays on nickel foam toward efficient oxygen evolution: the key role of in-situ-generated γ-NiOOH, Advanced Materials, 2021, 33, 2005587.
14.Sun, Jinmeng#; Du, Zhuzhu#; Liu, Yuhang; Ai, Wei*; Wang, Ke; Wang, Tian; Du, Hongfang*; Liu, Lei; Huang, Wei*. State-of-the-art and future challenges in high energy lithium–selenium batteries, Advanced Materials, 2021, 33, 2003845.
15.He, Song; Du, Hongfang*; Wang, Ke; Liu, Qianchi; Sun, Jinmeng; Liu, Yuhang; Du, Zhuzhu; Xie, Linghai; Ai, Wei*; Huang, Wei*. Low-temperature molten salt synthesis of MoS2@CoS2 heterostructures for efficient hydrogen evolution reaction, Chemical Communications, 2020, 56, 5548.
16.Du, Hongfang; Zhao, Zhi Liang; Zhang, Lian Ying; Niu, Yubin; Yu, Ting*; Li, Chang Ming*. Ion exchange synthesis of cobalt ion modified titanate nanoarray as an electrocatalyst toward efficient hydrogen evolution reaction, ACS Applied Energy Materials, 2019, 2, 8946.
17.Du, Hongfang; Ai, Wei; Zhao, Zhi Liang; Chen, Yu; Xu, Xin; Zou, Chenji; Wu, Lishu; Su, Lan; Nan, Kaikai; Yu, Ting*; Li, Chang Ming*. Engineering morphologies of cobalt pyrophosphates nanostructures toward greatly enhanced electrocatalytic performance of oxygen evolution reaction, Small, 2018, 14, 1801068.
18.Du, Hongfang; Gu, Shuang; Liu, Rongwei; Li, Chang Ming*. Tungsten diphosphide nanorods as an efficient catalyst for electrochemical hydrogen evolution, Journal of Power Sources, 2015, 278, 540.
19.Du, Hongfang; Gu, Shuang; Liu, Rongwei; Li, Chang Ming*. Highly active and inexpensive iron phosphide nanorods electrocatalyst towards hydrogen evolution reaction, International Journal of Hydrogen Energy, 2015, 40, 14272.
20.Du, Hongfang; Liu, Qian; Cheng, Ningyan; Asiri, Abdullah M.; Sun, Xuping*; Li, Chang Ming*. Template-assisted synthesis of CoP nanotubes to efficiently catalyze hydrogen-evolving reaction, Journal of Materials Chemistry A, 2014, 2, 14812.