杨徐荟

发布时间：2021-08-26浏览次数：6563

一、个人简介

杨徐荟，女，工学博士，讲师，入选福建省高层次人才、福建师范大学“宝琛计划”青年英才。2009.09-2016.01于北京科技大学攻读本科与硕士学位，主要研究方向为纳米半导体器件理论模拟研究；2016.09-2021.06于福州大学攻读博士学位，主要研究方向为二维功能材料的设计及调控研究，在读期间（2018.10-2020.10）获国家公派留学奖学金赴美国内华达大学拉斯维加斯分校进行联合培养，主要研究方向为高通量二维电子化合物计算与设计。2021.08进入福建师范大学环境科学与工程学院工作。目前已在Nature Communications、Advanced Functional Materials、Applied Catalysis B: Environment and Energy、Chemical Engineering Journal、Journal of Colloid And Interface Science、Nano Research、Small、Nano Energy、Physical Review B等刊物上发表50余篇学术论文。

二、研究方向

1. 低维环境与清洁能源材料高通量计算与设计；

2.人工智能驱动的材料理性设计在绿色能源领域中的应用。

三、科研项目

1、国家自然科学基金青年科学基金项目，MXene电子化合物催化还原二氧化碳性能的电子态调控机制（52503359），2026.01-2028.12，主持。

2、福建省自然科学基金面上项目，二维磷基光催化剂共掺杂增效机制的理论研究（2022J01185），2022.09-2025.08，主持。

3、福建省教育厅中青年教师教育科研项目，二维MA2Z4基光催化剂的光催化水分解性能研究（JAT210052），2022.01-2024.12，主持。

4、福建省自然科学基金重点项目，智能冷链物流用锌金属凝胶二次电池的宽温域高性能化研究（2023J02013），2023.08-2026.08，参与。

5、国家自然科学基金面上项目，层间耦合与面内错配调控III-VI族范德华异质结性能的机制研究，（21973012，2020-01至2023-12），参与。

6、国家重点研发计划子项目，面向材料集成设计的高通量自动流程计算算法，（2017YFB0701701，2017.09-2021.09），参与。

7、国家自然科学基金青年科学基金项目，多元硫族超晶格相变存储材料的生长动力学与性质研究，（61504028，2016.01-2018.12），参与。

四、代表性论文

ORCID ID: https://orcid.org/0000-0003-4148-6134

[1]Xu, N.; Xie, R.; Yang, X.*; Xiong, R.; Wen, C.; Sa, B.*, Atomic-Scale Insights into Nonmetallic Single-Atom Catalysis for Li/Na-S Batteries. Appl. Surf. Sci., 2026, 715, 164414.

[2]Yang, X.^#; Luo, L.^#; Yang, M.-Q.*; Qian, Q.*, Synergistic Defect and Doping Engineering of Novel Green Phosphorene for Enhanced Spatial Carrier Separation: A DFT-Based Strategy for High-Efficiency Overall Water Splitting. Sustainable Chem. Pharm., 2025, 47, 102156.

[3]Yang, X.; Cui, W.; Luo, L.; Ke, S.; Xue, H.; Shen, L.*; Yang, M.-Q.*, Two-Dimensional Transition Metal Dichalcogenide Edges for Decomposition of Hydrogen Sulfide: A DFT Study. Appl. Surf. Sci., 2025, 704, 163491.

[4]Li, M.; Yang, X.; Yi, J.; Shen, L.; Yang, X.*; Weng, B.; Yang, M.-Q.*, Boosting Photocatalytic Benzylic C(sp³)-H Bonds Oxidation via an Embedded S-Scheme BA₂PbBr₄/MoO₃ Heterojunction. J. Colloid Interface Sci., 2025, 700, 138450.

[5]Zhou, X.; Zheng, X.; Li, J.; Shen, L.; Pan, X.; Yang, X.*; Yang, M.-Q.*, Boosted Photocatalytic Oxidation of Benzylic C(sp³)-H Bonds over C₃N₄/PMA₂PbBr₄ via Synergistic Promotion of Charge Separation and Substrate Adsorption. Chem. Eng. J., 2025, 522, 167437.

[6]Chen, A.; Yang, X.*; Shen, L.; Zheng, Y.; Yang, M.-Q.*, Directional Charge Pumping from Photoactive P‐doped CdS to Catalytic Active Ni₂P via Funneled Bandgap and Bridged Interface for Greatly Enhanced Photocatalytic H₂ Evolution. Small, 2024, 20 (28), 2309805.

[7]Yang, X.*; Xue, H.; Luo, L. Exploiting MoSi₂N₄ , WSi₂N₄ and WGe₂N₄ Monolayers for Efficient Photocatalytic Overall Water Splitting across a Broad pH Range. New J. Chem., 2024, 48 (30), 13405–13412.

[8]Luo, L.; Cui, W.; Xue, H.; Ke, S.; Yang, X.*; Yang, M.-Q.; Qian, Q.*, Activating Black Phosphorene’s Inert Basal Plane via Nonprecious Metal–Nonmetal Co-Doping for Visible-Light-Driven Photocatalytic H₂ Evolution. New J. Chem., 2024, 48 (3), 1141–1151.

[9]Lei, Z.; Zheng, J.; He, X.; Wang, Y.; Yang, X.*; Xiao, F.; Xue, H.; Xiong, P.; Wei, M.; Chen, Q.; Qian, Q.*; Zeng, L.*, Defect-Rich WS₂–SPAN Nanofibers for Sodium/Potassium-Ion Batteries: Ultralong Lifespans and Wide-Temperature Workability. Inorg. Chem. Front., 2023, 10 (4), 1187–1196.

[10]Yuan, Z.; Xiao, F.; Fang, Y.; Xiong, P.; Sun, X.*; Duan, X.; Yang, X.*; Fan, H.; Wei, M.; Qian, Q.; Chen, Q.; Zeng, L.*, Defect Engineering on VO₂(B) Nanoleaves/Graphene Oxide for the High Performance of Cathodes of Zinc-Ion Batteries with a Wide Temperature Range. J. Power Sources, 2023, 559, 232688.

[11]Chen, Y.; Zhang, Z.; Wang, X.; Lin, Y.; Zuo, J.*; Yang, X.*; Chen, S.; Luo, Y.*; Qian, Q.; Chen, Q. Crystal Plane Effect of Co₃O₄ on Styrene Catalytic Oxidation: Insights into the Role of Co³⁺ and Oxygen Mobility at Diverse Temperatures. ACS Appl. Mater. Interfaces, 2023, 15 (27), 32404–32415.

[12]Lu, X.; Shan, T.; Deng, L.; Li, M.; Pan, X.; Yang, X.*; Zhao, X.; Yang, M.-Q.*, Facile Synthesis of Hierarchical CdS Nanoflowers for Efficient Piezocatalytic Hydrogen Evolution. Dalton Trans., 2023, 52 (37), 13426–13434.

[13]Lin, P.; Xu, N.; Tan, X.; Yang, X.*; Xiong, R.; Wen, C.; Wu, B.; Lin, Q.; Sa, B.*, The Interlayer Coupling Modulation of a G-C₃N₄/WTe₂ Heterostructure for Solar Cell Applications. RSC Adv., 2022, 12 (2), 998–1004.

[14]Yang, X.; Parrish, K.; Li, Y.-L.; Sa, B.; Zhan, H.; Zhu, Q.*, Switchable Two-Dimensional Electrides: A First-Principles Study. Phys. Rev. B, 2021, 103 (12), 125103.

[15]Yang, X.; Sa, B.*; Lin, P.; Xu, C.; Zhu, Q.; Zhan, H.*; Sun, Z. Tunable Contacts in Graphene/InSe van Der Waals Heterostructures. J. Phys. Chem. C, 2020, 124 (43), 23699–23706.

[16]Yang, X.; Sa, B.*; Xu, C.; Zhan, H.*; Anpo, M.; Sun, Z.*, Enhanced Photocatalytic Performance of Black Phosphorene by Isoelectronic Co-Dopants. Inorg. Chem. Front., 2019, 6 (9), 2369–2378.

[17]Yang, X.; Sa, B.*; Zhan, H.*; Sun, Z. Electric Field-Modulated Data Storage in Bilayer InSe. J. Mater. Chem. C, 2017, 5 (46), 12228–12234.

[18]Yang, X.^#; Gu, Y.^#; Migliorato, M. A.; Zhang, Y.*, Impact of Insulator Layer Thickness on the Performance of Metal–MgO–ZnO Tunneling Diodes. Nano Res., 2016, 9 (5), 1290–1299.

[19]Gu, Y.^#; Yang, X.^#; Guan, Y.; Migliorato, M. A.; Zhang, Y.*, Enhanced Electromechanical Performance in Metal–MgO–ZnO Tunneling Diodes Due to the Insulator Layers. Inorg. Chem. Front., 2016, 3 (9), 1130–1136.

五、联系方式

电子邮箱：xhyang@fjnu.edu.cn

办公地址：福建省福州市闽侯县上街镇乌龙江中大道18号福建师范大学旗山校区(350117)

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杨徐荟

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