2015.01-2019.05 新加坡南洋理工大学 博士研究生

2012.09-2014.07 哈尔滨工业大学 硕士研究生

2008.09-2012.07 哈尔滨工业大学 学士

• 国家自然科学基金“面上”: 面向近红外二区超分辨成像应用的光纤生成STED光束技术研究, 2023-2026
• 重点资助项目: 太赫兹拓扑波导集成幅度调制器研究, 2022-2025
• 国家重点研发计划-课题: 悬臂式光波导生物纳米测量系统及应用研究, 2021-2025
• 自然科学类人才基金项目: 钙钛矿太阳能电池电子传输层的优化, 2019-2022

《光网络技术》

《复变函数》

1. S. Ma, B. Ma, J. Luo, X. Zhang, N. Zhang, G. Fan, S. Ramakrishna, T. Ye, Small Molecule-Induced Modulation of Grain Crystallization and Ion Migration Leads to High-Performance MAPbI3 Mini-Modules,  ACS Applied Energy Materials, 5, 9471-9478 (2022).

2. S. Ma, Z. Wang, Y. Zhu, Y. Tang, G. Fan, B. Ma, T. Ye, and L. Wei, Micro/Nanofiber fabrication technologies for wearable sensors: a review, Journal of Micromechanics and Microengineering 32, 064002 (2022).
3. S. Ma, H. Li, R. Yao, H. Zhang and T. Ye, "Optimization of Annealing Treatment for CsSnI3-Based Solar Cells with Enhanced Efficiency," 2021 IEEE 6th Optoelectronics Global Conference (OGC), 2021, pp. 246-248.
4. T. Ye#, K. Wang#, S. Ma#, C. Wu, Y. Hou, D. Yang, K. Wang, S. Priya, Strain-Relaxed Tetragonal MAPbI3 Results in Efficient Mesoporous Solar Cells, Nano Energy 83, 105788 (2021). 
5. S. Ma, X. Gu, A. K. K. Kyaw, D. H. Wang, S. Priya and T. Ye, Fully inorganic CsSnI₃-based solar cells with >6% efficiency and enhanced stability enabled by mixed electron transport layer, ACS Applied Materials & Interfaces 13, 1345-1352 (2021).
6. S. Ma, T. Ye, T. Wu, Z. Wang, Z. Wang, S. Ramakrishna, C. Vijila, and L. Wei, Hollow rice grain-shaped TiO₂ nanostructures for high-efficiency and large-area perovskite solar cells, Solar Energy Materials and Solar Cells 191, 389-398 (2019).
7. S. Ma, T. Ye, T. Zhang, Z. Wang, K. Li, M. Chen, J. Zhang, Z. Wang, S. Ramakrishna, and L. Wei, Highly oriented electrospun P(VDF-TrFE) fibers via mechanical stretching for wearable motion sensing, Advanced Materials Technologies 3, 1800033 (2018).
8. T. Ye#, S. Ma#, X. Jiang, M. Petrovic, V. Chellapan, S. Ramakrishna, and L. Wei, Electrosprayed TiO₂ nanoporous hemi-spheres for enhanced electron transport and device performance of formamidinium based perovskite solar cell, Nanoscale 9, 412-420 (2017). 
9. T. Ye, X. Wang, K. Wang, S. Ma, D. Yang, Y. Hou, J.Yoon, K. Wang, S. Priya, Localized Electron Density Engineering for Stabilized B-γ CsSnI3-Based Perovskite Solar Cells with Efficiencies >10%, ACS Energy Letters 6, 1480–1489 (2021). ( ESI热点、高被引文章)
10. M. Chen, Z. Wang, X. Ge, Z. Wang, K. Fujisawa, J. Xia, Q. Zeng, K. Li, T. Zhang, Q. Zhang, M. Chen, N. Zhang, T. Wu, S. Ma, G. Gu, Z. Shen, L. Liu, Z. Liu, M. Terrones, and L. Wei, Controlled fragmentation of single-atom-thick polycrystalline graphene, Matter 2, 666-679 (2020).
11.  K. Li, N. Zhang, T. Zhang, Z. Wang, M. Chen, T. Wu, S. Ma, M. Zhang, J. Zhang, Dinish U. S, P. Shum, M. Olivo, and L. Wei, Formation of ultra-flexible, conformal, and nano-patterned photonic surfaces via polymer cold-drawing, Journal of Materials Chemistry C 6, 4649-4657 (2018).
12. T. Ye, S. Ma, X. Jiang, L. Wei, C. Vijila, and S. Ramakrishna, Performance enhancement of tri-cation and dual-anion mixed perovskite solar cells by Au@SiO₂ nanoparticles, Advanced Functional Materials 27, 1606545 (2017).
13. T. Zhang, K. Li, J. Zhang, M. Chen, Z. Wang, S. Ma, N. Zhang, and L. Wei, High-performance, flexible, and ultralong crystalline thermoelectric fibers, Nano Energy 41, 35-42 (2017).
14. Y. He, Y. Sun, Z. Wang, S. Ma, N. Zhang, J. Zhang, S. Soh, and L. Wei, Pristine graphene oxide film-based contactless actuators driven by electrostatic force, Journal of Materials Chemistry C 5, 9534-9539 (2017).
15. T. Zhang, K. Li, C. Li, S. Ma, H. H. Hng, and L. Wei, Mechanically durable and flexible thermoelectric films from PEDOT:PSS/PVA/Bi0.5Sb1.5Te3 nanocomposites, Advanced Electronic Materials 3, 1600554 (2017).
16. S. Wang, T. Zhang, K. Li, S. Ma, M. Chen, P. Lu, and L. Wei, Flexible piezoelectric fibers for acoustic sensing and positioning, Advanced Electronic Materials 3, 1600449 (2017).
17. K. Li, T. Zhang, N. Zhang, M. Zhang, J. Zhang, T. Wu, S. Ma, J. Wu, M. Chen, Y. He, and L. Wei, Integrated liquid crystal photonic bandgap fiber devices, Frontiers of Optoelectronics 9, 466-482 (2016).