一、基本信息

吕天帅 (Lyu Tianshuai)

福建省境外引进高层次人才C类，厦门市高层次人才C类，厦门市高层次留学人才。

华侨大学发光材料与信息显示研究院，长聘副教授，硕士生导师，邮箱：lv_tianshuai@126.com

吕天帅课题组主页:

ResearchGate个人主页：

二、教育和工作经历

10/2016-9/2020, 荷兰代尔夫特理工大学 (Delft University of Technology, The Netherlands), 博士(导师：Pieter Dorenbos教授)。

9/2012—6/2015, 昆明理工大学, 硕士 (导师：邱建备教授；徐旭辉教授)

9/2008—7/2012, 天津理工大学, 学士 (导师：王达健教授)

2021.3-至今, 华侨大学发光材料与信息显示研究院，材料科学与工程学院

三、研究方向

基于可控电子或空穴迁移的新型发光材料的研究，具体包括如下方向:

1). 稀土离子，过渡金属离子，ns²np电子组态的Bi²⁺, Bi³⁺, Tl⁺, Pb²⁺掺杂长余辉发光材料与信息存储材料的理论设计及发光机理研究。

2). 应力发光材料及其在新型显示应用的研究。

四、研究基金

1).国家自然科学基金青年项目，主持，在研，2022.01-2024.12

2).福建省自然科学基金面上项目，主持，在研，2023.08-2026.08

3).国家自然科学基金青年项目-华侨大学配套经费，主持，在研，2022.01-2024.12

4).华侨大学中青年教师科技创新资助计划,主持，在研，2022.05-2026.5

5).华侨大学引进人才启动经费项目，主持，在研，2022.01-2024.12

6).国家级大学生创新创业训练计划项目，指导老师，在研，2023.06-2024.06 在研

7).国家级大学生创新创业训练计划项目，指导老师，在研，2022.06-2023.06 结题

8).国家级大学生创新创业训练计划项目，指导老师，在研，2021.06-2022.06 结题

参与项目：

1).国家自然科学基金-地区科学基金项目(NO.61565009)，“光肥”用长余辉发光材料在缺陷态协助下的光转换过程研究，参与，结题。

2).国家自然科学基金-地区科学基金项目(NO.61368007)，贵金属-氟化物微晶协同增强稀土掺杂玻璃上转换发光，参与，结题。

3).国家自然科学基金青年项目(NO.61307111)，微观结构调控对铋离子掺杂玻璃的超宽带近红外发光的影响及其机理研究，参与，结题。

五、招生招聘

欢迎有志于科学研究的研究生报考。吕老师与荷兰代尔夫特理工大学(Delft University of Technology, The Netherlands，QS2023 排名47名)有合作关系，表现优秀的学生，可推荐到荷兰代尔夫特理工大学攻读博士学位。欢迎本科生加入吕老师课题组开展科创研究。联系方式：微信号：570607709；邮箱：lv_tianshuai@126.com。

TU Delft library and RID faculty

六、部分研究成果 

第一作者兼通讯作者发表高质量学术论文30余篇：

[24] T. Lyu*, P. Dorenbos, Z. Wei, Indirect evidence of Bi3+ valence change and dual role of Bi3+ in trapping electrons and holes for multimode X-ray imaging, anti-counterfeiting, and non-real-time force sensing. Acta Materialia, 119953 (2024).

https://www.sciencedirect.com/science/article/pii/S1359645424003057?via%3Dihub

[23] T. Lyu*, P. Dorenbos, Charge carrier trapping management in Bi3+ and lanthanides doped Li(Sc,Lu)GeO4 for x-ray imaging, anti-counterfeiting, and force recording, Applied Physics Reviews 11(1) (2024). (入选Featured article，在期刊封面进行推广)

https://pubs.aip.org/aip/apr/article/11/1/011415/3266830/Charge-carrier-trapping-management-in-Bi3-and

[22] T. Lyu*, P. Dorenbos, Z. Wei, Versatile and High-Performance LiTaO3:Tb3+, Gd3+ Perovskite for Multimode Anti-counterfeiting, Flexible X-Ray Imaging, Continuous Stress Sensing, and Non-Real-Time Recording, Laser & Photonics Reviews 17(11) (2023) 2300323.

https://onlinelibrary.wiley.com/doi/10.1002/lpor.202300323

        [21] T. Lyu*, P. Dorenbos, Vacuum-Referred Binding Energies of Bismuth and Lanthanide Levels in LiTaO3 Perovskite: Toward Designing Energy Storage Phosphor for Anti-Counterfeiting, X-Ray Imaging, and Mechanoluminescence, Laser & Photonics Reviews n/a (2022) 2200304.

  https://onlinelibrary.wiley.com/doi/10.1002/lpor.202200304

[20] T. Lyu*, P. Dorenbos, P. Xiong, Z. Wei, LiTaO3:Bi3+,Tb3+,Ga3+,Ge4+: A Smart Perovskite with High Charge Carrier Storage Capacity for X-Ray Imaging, Stress Sensing, and Non-Real-Time Recording, Advanced Functional Materials n/a (2022) 2206024.

  https://onlinelibrary.wiley.com/doi/10.1002/adfm.202206024

[19]. T. Lyu* et al. Designing LiTaO3:Ln3+,Eu3+ (Ln = Tb or Pr) perovskite dosimeter with excellent charge carrier storage capacity and stability for anti-counterfeiting and flexible X-ray imaging, Chemical Engineering Journal  (2023) 141685. https://doi.org/10.1016/j.cej.2023.141685.

https://www.sciencedirect.com/science/article/pii/S1385894723004163?via%3Dihub

[18]. T. Lyu* et al. High charge carrier storage capacity and wide range X-ray to infrared photon sensing in LiLuGeO4:Bi3+,Ln3+ (Ln=Pr, Tb, or Dy) for anti-counterfeiting and information storage applications. Materials Chemistry Frontiers, 2022. DOI: 10.1039/D2QM01098D.

https://pubs.rsc.org/en/Content/ArticleLanding/2022/QM/D2QM01098D

[17] T. Lyu*, P. Dorenbos, L. Canhua, W. Zhanhua, Wide range X-ray to infrared photon detection and energy storage in LiTaO3:Bi3+,Dy3+ perovskite, Laser & Photonics Reviews, DOI: 10.1002/lpor.202200055 (2022).

        https://onlinelibrary.wiley.com/doi/10.1002/lpor.202200055 

[16] 如何利用真空标度(VRBE)能级图理性设计与探索长余辉发光与光存储材料，发光学报，2022，DOI：10.37188/CJL.20220123

   https://cjl.lightpublishing.cn/thesisDetails#10.37188/CJL.20220123&lang=zh

[15] T. Lyu*, P. Dorenbos, C. Li, S. Li, J. Xu, Z. Wei, Unraveling electron liberation from Bi2+ for designing Bi3+-based afterglow phosphor for anti-counterfeiting and flexible X-ray imaging, Chemical Engineering Journal 435 (2022) 135038. 

https://www.sciencedirect.com/science/article/abs/pii/S1385894722005447?via%3Dihub

[14] 吕天帅博士论文：Rational Design of Afterglow and Storage Phosphors

      链接：Rational Design of Afterglow and Storage Phosphors | TU Delft Repositories

[13] T. Lyu*, P. Dorenbos, Towards information storage by designing both electron and hole detrapping processes in bismuth and lanthanide-doped LiRE(Si,Ge)O₄ (RE=Y, Lu) with high charge carrier storage capacity, Chemical Engineering Journal (2020), 124776, DOI: https://doi.org/10.1016/j.cej.2020.124776.

[12] T. Lyu*, P. Dorenbos, Vacuum referred binding energies of bismuth and lanthanide levels in ARE(Si,Ge)O₄ (A=Li, Na; RE=Y, Lu); towards designing charge carrier trapping processes for energy storage, Chemistry of Materials 32 (2020) 1192-1209.

https://doi.org/10.1021/acs.chemmater.9b04341

[11] T. Lyu*, P. Dorenbos, Designing thermally stimulated 1.06 µm Nd³⁺ emission for the second bio-imaging window demonstrated by energy transfer from Bi³⁺ in La-, Gd-, Y-, and LuPO₄, Chemical Engineering Journal 372 (2019) 978-991.

[10] T. Lyu*, P. Dorenbos, Bi³⁺ acting both as an electron and as a hole trap in La-, Y-, and LuPO₄, Journal of Materials Chemistry C 6 (2018) 6240-6249.

[9] T. Lyu*, P. Dorenbos, Charge carrier trapping processes in lanthanide doped LaPO₄, GdPO₄, YPO₄, and LuPO₄, Journal of Materials Chemistry C 6 (2018) 369-379.

[8] T.-S. Lv, X.-H. Xu, X. Yu, J.-B. Qiu, Evolution in the Oxidation Valences and Sensitization Effect of Copper Through Modifying Glass Structure and Sn²⁺/Si Codoping, Journal of the American Ceramic Society 98 (2015) 2078-2085.

[7] T. Lv, X. Xu, D. Zhou, J. Qiu, Influence of Cu⁺ cations on photoluminescence properties of Tb³⁺ in Cu⁺–Na⁺ ion-exchanged sodium-borosilicate glasses, Journal of Non-Crystalline Solids 409 (2015) 14-19.

[6] T. Lv, X. Xu, X. Yu, D. Zhou, J. Qiu, Multi-wavelength-driven solar spectral conversion in P₂O₅-ZnO-Li₂O glasses for improving greenhouse photosynthetic activity, Ceramics International 41 (2015) 645-650.

[5] T.-S. Lv, X.-H. Xu, D.-C. Zhou, H.-L. Yu, J.-B. Qiu, Efficient multi-wavelength-driven spectral conversion from ultraviolet to visible in transparent borosilicate glasses, Ceramics International 40 (2014) 12367-12373.

[4] T. Lv, X. Xu, X. Yu, H. Yu, D. Zhou, J. Qiu, Tunable Mission and Trichromatic White-Emitting in Oxyfluoride Glasses by Utilization of Cu⁺ Ions as Multiple Energy-Transfer Creators, Journal of the American Ceramic Society 97 (2014) 2897-2902.

[3] T.-S. Lv, X.-H. Xu, D.-J. Wang, L. Sun, J.-B. Qiu, Fabrication, structure and photoluminescence properties of Eu³⁺-activated red-emitting Ba₂Gd₂Si₄O₁₃ phosphors for solid-state lighting, Optoelectronics Letters 10 (2014) 106-110.

[2] T.-S. Lv, X.-H. Xu, X. Yu, H.-L. Yu, D.-J. Wang, D.-C. Zhou, J.-B. Qiu, Tunable full-color emitting borosilicate glasses via utilization of Ce³⁺ ions as multiple energy transfer contributors, Journal of Non-Crystalline Solids 385 (2014) 163-168.

[1] T.S. Lv, X.H. Xu, D.C. Zhou, J.B. Qiu, Deep-UV-Driven Emission-Tailorable Borosilicate Glasses by Utilization of Sn²⁺ Cations as Versatile Energy-Transfer Establishers, ECS Journal of Solid State Science and Technology 3 (2014) R89-R94.