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教师个人主页 - 宋宏伟
发布人:  韩咏梅  发布时间:  2025-03-03  浏览量:   关闭

姓名:

宋宏伟

职称:

教授

博导/硕导:

硕导/博导

通讯地址

上海市宝山区上大路99号上海大学理学院物理系

联系电话

13756189863

E-mail

songhw@jlu.edu.cn, songhw@shu.edu.cn

从事专业

物理学,光学

研究方向

主要从事稀土纳米发光及应用、钙钛矿光电材料与器件(太阳能电池、光电探测器和 LED 器件)应用研究,在稀土发光材料与光电材料和器件结合以及利用局域场效应进行发光调控方面做出了开拓性工作。

讲授主要课程

纳米材料、结构与发光调控,原子分子光谱学

参加学术团体、任何职务

“稀土新材料”(2021 年度),“纳米前沿”(2023 年度)重点专项指南撰写专家

国家自然科学奖会评专家/教育部自然科学奖会评专家

中国稀土学会理事

中国颗粒学会发光专业委员会副主任

中国光学学会光与物质相互作用委员会副主任

中国物理学会发光分会委员

中国稀土学会发光专业委员会委员

吉林省物理学会理事

Nanomaterials 、Scientific report,Journal of Nanoscience Research and reports,

Curent Chinese Science,发光学报等中外期刊编委会成员。

学习与工作简历

1985.09-1989.06 吉林大学物理系 学士(理论物理)

1991.09-1996.06 原中科院长春物理所 博士(凝聚态物理)

1996.08-1998.07 中科院物理所(北京) 博士后(光学)

1998.07-1999.10 日本名古屋工业大学材料工学科 博士后(材料学)

1999. 10-2000.09 美国伯克利加州大学化学系 博士后(物理化学)

2000.10-2007.04 中科院长春光机与物理所 研究员/百人计划学者

2007.05-2025.01 吉林大学电子科学与工程学院 教授,杰青

2025.02-迄今   上海大学理学院物理系 教授, 杰青

代表性成果(论文、论著、申请专利、荣誉奖励等)

研究成果:

(1)在国际上最早实现了铅卤化物钙钛矿中稀土离子的掺杂,发现 CsPbCl3:Yb3+中的量子剪裁发光现象,并成功将其应用于提升晶硅电池的效率 (PCE 提升高达 3.8%),被 Science评价为“近年来最令人振奋的结果之一”。

(2)在国际上最早报道了 CsPbCl3:Sm3+, CsPbCl3:Eu3+ 和 CsPbCl3:Er3+等材料的电致发光,实现了单一基质的高效白光发射,成功将钙钛矿的电致发光波长拓展到 1.54 微米光通讯窗口区域。

(3)采取稀土纳米材料荧光上、下转换和有机异质结-钙钛矿叠层结构等策略拓展钙钛矿电池的光伏响应范围,同时采取多种界面修饰策略提高载流子输运与提取能力,报道最优器件光电转换效率超过 25%, 长时稳定性超过 5000 小时。

(4)研制了基于稀土离子和钙钛矿纳米晶复合的新型光电探测器,实现了多种高性能的窄谱带光电探测(248nm, 365nm, 808nm, 980nm, 1540nm)和200-1000nm的宽光谱探测。

(5)在局域场调控上转换发光方面,提出了光子晶体-贵金属级联调控策略和半导体表面等离子体调控策略,使上转换材料发光强度提高达2-4个数量级,大大降低了其工作阈值,并成功应用于太阳电池、光电探测和生物传感等领域。

迄今为止共发表 SCI 论文 480 余篇,授权发明专利 30 多项。作为责任作者在国际顶尖和高水平学术期刊发表论文情况:Chemical Society Review(1 篇), Advanced Material(5 篇),Light Science and Application (5 篇),Advanced Energy Material (8 篇),Advanced Function Material (10 篇),Nano Energy (18 篇),ACS Energy Letter (1 篇),Advanced Science(3 篇),Nano Today (2篇),ACS Nano(1 篇),Nano Letters (2 篇),Small(4 篇),Small Method(1 篇),Biomaterials (3 篇),Chemistry of Materials (4 篇),Journal of Material Chemistry A(2 篇),Laser and Photonic Review (4篇),Advanced Optical Material(5 篇), Chemical Engineering Journal (13 篇)。 论文累计被 SCI 引用近23000 次。

代表性论文:

[1]Bottom-Up Defect Modification Through Oily-Allicin Modified Buried Interface Achieving Highly Efficient and Stable Perovskite Solar Cells. Zhuang X, Zhou D*,… Song H*. Adv Mater 36, doi:10.1002/adma.202403257 (2024).

[2]Efficient and Stable Multicolor Emissions of the Coumarin-Modified Cs3LnCl6 Lead-Free Perovskite Nanocrystals and LED Application. Sun L, Dong B*, … Song H*. Adv Mater 36, doi:10.1002/adma.202310065 (2024).

[3]Engineering of Hole Transporting Interface by Incorporating the Atomic-Precision Ag6 Nanoclusters for High-Efficiency Blue Perovskite Light-Emitting Diodes. Zhang F, Gao Y, …Song H* and Bai X*. Nano Lett 23, 1582-1590, doi:10.1021/acs.nanolett.3c00068 (2023).

[4]Full-Spectral Response Perovskite Solar Cells Through Integration of MXene Modified Near-Infrared Organic Heterojunction and Waveguide-Structure Quantum-Cutting Down-Converter. Shi Z, Zhou D*,… Song H*. Adv Energy Mater 14, doi:10.1002/aenm.202303735 (2024).

[5]Gas Molecule Assisted All-Inorganic Dual-Interface Passivation Strategy for High-Performance Perovskite Solar Cells. Zeng F, Xu L,…Song H*. Advanced Science 11, doi:10.1002/advs.202404444 (2024).

[6]High-Performance Blue Perovskite Light-Emitting Diodes Enabled by Synergistic Effect of Additives. Zhang F, Yang Y, … Song H* and Bai X*. Nano Lett 24, 1268-1276, doi:10.1021/acs.nanolett.3c04267 (2024).

[7]A multiband NIR upconversion core-shell design for enhanced light harvesting of silicon solar cells. Wang Y, Xu W*, … Song H*. Light-Sci Appl 13, doi:10.1038/s41377-024-01661-5 (2024)

[8]Perovskite Solar Cells with Extremely High 24.63% Efficiency through Design of Double Electron Transport Layers and Double Luminescent Converter Layers. Liu B, Wang Y, … Song H*. Adv Funct Mater 34, doi:10.1002/adfm.202401007 (2024).

[9]Realization of 1.54-μm Light-Emitting Diodes Based on Er3+/Yb3+Co-Doped CsPbCl3 Films. Li H, Liu X, …Song H*. Adv Mater 35, doi:10.1002/adma.202300118 (2023).

[10]Synergetic Excess PbI2 and Reduced Pb Leakage Management Strategy for 24.28% Efficient, Stable and Eco-Friendly Perovskite Solar Cells. Zhang Y, Xu L, … Song H*. Adv Funct Mater 33, doi:10.1002/adfm.202214102 (2023).

[11]Trivalent Europium-Doped CsCl Quantum Dots for MA-Free Perovskite Solar Cells with Inherent Bandgap through Lattice Strain Compensation. Zhuang X, Zhou D*, …Song H*. Adv Mater 35, doi:10.1002/adma.202302393 (2023).

[12]A Wearable Healthcare Platform Integrated with Biomimetical Ions Conducted Metal-Organic Framework Composites for Gas and Strain Sensing in Non-Overlapping Mode. Zhou Q, Geng Z,…Song H* and Ren L. Advanced Science 10, doi:10.1002/advs.202207663 (2023).

[13]Efficient single-component white light emitting diodes enabled by lanthanide ions doped lead halide perovskites via controlling Forster energy transfer and specific defect clearance Sun. R, Zhou. DL*,... Song. HW*,Light.Sci&Appl.,11, DOI10.1038/s41377-022-01027-9,2022.

[14]Vitamin Natural Molecule Enabled Highly Efficient and Stable Planar n-p Homojunction Perovskite Solar Cells with Efficiency Exceeding 24.2% Liu. B, Wang. YQ*, ... Song, HW*, Adv.Energy.Mater.13,2203352, 2022

[15]24.11% High Performance Perovskite Solar Cells by Dual Interfacial Carrier Mobility Enhancement and Charge-Carrier Transport Balance Zhang.YH, Xu, L*; ... Song, HW*, Adv.Energy.Mater.12,2201269,2203352, 2022

[16]Light Management through Organic Bulk Heterojunction and Carrier Interfacial Engineering for Perovskite Solar Cells with 23.5% Efficiency Shi. ZC; Zhou. DL*; ... Song. HW*, Adv. Funct Mater. 32, 202203873,[5] 2022

[17]Learning From Plants: Lycopene Additive Passivation toward Efficient and "Fresh" Perovskite Solar Cells with Oxygen and Ultraviolet Resistance Zhuang. XM, Zhou. DL*,... Song. HW*,Adv.Energy.Mater.12, 202200614,2022

[18]A novel approach for designing efficient broadband photodetectors expanding from deep ultraviolet to near infrared Ding. N, Xu. W* ... Song, HW*, Light.Sci&Appl.11,Doi.org10.1038/s41377-022-00777-w,2022.

[19]Toward Broad Spectral Response Inverted Perovskite Solar Cells: Insulating QuantumCutting Perovskite Nanophosphors and Multifunctional Ternary Organic Bulk-Heterojunction Wu. YJ; Ding, N,... Song, HW*, Adv.Energy.Mater.12,202200005, 2022

[20][20] Dual Modification Engineering via Lanthanide-Based Halide Quantum Dots and Black Phosphorus Enabled Efficient Perovskite Solar Cells with High Open-Voltage of 1.235 V Liu. SN, Lyu., JK, ... Song, HW*, Adv. Funct Mater.32, 202112647, 2022.

[21][21] Synergistic Effects of Multifunctional Lanthanides Doped CsPbBrCl2 Quantum Dots for Efficient and Stable MAPbI3 Perovskite Solar Cells Zhuang. XM. Sun. R, ...; Song, HW*, Adv. Funct Mater.32, 202110346, 2022.

[22][22] Enhanced Photoluminescence and Photoresponsiveness of Eu3+ Ions-Doped CsPbCl3 Perovskite Quantum Dots under High Pressure Jing. XL. Zhou. DL*, ... Song HW*, Adv. Funct Mater.31, 20210930, 2021.

[23]Photon management to reduce energy loss in perovskite solar cells Chen. C, Zheng. SJ and Song. HW*, Chem.Soc.Rev.50, pp.7250-7329,2021.

[24]Huge upconversion luminescence enhancement by a cascade optical field modulation strategy facilitating selective multispectral narrow-band near-infrared photodetection, Ji.YN,Xu.W*, ... Song HW*, Light.Sci&Appl.9,doi.org/10.1038/s41377-020-00418,2020

[25]Samarium-Doped Metal Halide Perovskite Nanocrystals for Single-Component Electroluminescent White Light-Emitting Diodes Sun. R, Lu.P,... Song, HW*, ACS Ener. Lett. 5, pp.2131-2139,2020.

[26]Dual Interfacial Modification Engineering with 2D MXene Quantum Dots and Copper Sulphide Nanocrystals Enabled High-Performance Perovskite Solar Cells Chen. X, Xu. W,... Song, HW*, Adv. Funct Mater.30, 202003295, 22020.

[27]Impact of Host Composition, Codoping, or Tridoping on Quantum-Cutting Emission of Ytterbium in Halide Perovskite Quantum Dots and Solar Cell Applications Zhou. DL,Sun.R, ... Song, HW*, Nano Lett. 19, pp.6904-6913, 2019.

[28]Interfacial Engineering and Photon Downshifting of CsPbBr3 Nanocrystals for Efficient, Stable, and Colorful Vapor Phase Perovskite Solar Cells Chen. C, Wu. YJ, ... Song, HW*, Adv.Sci.6, 201802046, 2019.

[29]Plasmonic Photonic Crystals Induced Two-Order Fluorescence Enhancement of Blue Perovskite Nanocrystals and Its Application for High-Performance Flexible Ultraviolet  Photodetectors Li.DY, Zhou, DL, ... Song, HW*, Adv. Funct Mater.28, 201804429, 2018.

[30]Carrier Interfacial Engineering by Bismuth Modification for Efficient and Thermoresistant Perovskite Solar Cells Chen. C, Liu. DL, ... Song, HW*,Adv.Energy.Mater.8, 201703659, 2018.

[31][31] Doping Lanthanide into Perovskite Nanocrystals: Highly Improved and Expanded Optical Properties Pan. GC, Bai, X, ... Song, HW*, Nano.Lett.12, pp.8005-8011,2017.

[32]Cerium and Ytterbium Codoped Halide Perovskite Quantum Dots: A Novel and Efficient Downconverter for Improving the Performance of Silicon Solar CellsZhou. DL, Liu.DL, ... Song, HW*, Adv.Mater.29, 101704149, 2017.

[33]Long-Lasting Nanophosphors Applied to UV-Resistant and Energy Storage Perovskite Solar Cells Chen. C, Li. H,... SongHW*,Adv.Energy.Mater.7, 201700758,2017.

[34]Observation of Considerable Upconversion Enhancement Induced by Cu2-xS Plasmon Nanoparticles Zhou.DL. Liu. DL, ... Song, HW*, ACS Nano 10 , pp.5169-5179, 2016.

[35]Local Field Modulation Induced Three-Order Upconversion Enhancement: Combining Surface Plasmon Effect and Photonic Crystal Effect Yin. Z, Li. H,... Song, HW*, Adv.Mater.28, , p2518, 2016.

[36]Large Upconversion Enhancement in the "Islands" Au-Ag Alloy/NaYF4: Yb3+, Tm3+/Er3+ Composite Films, and Fingerprint Identification Chen. X, Xu. W*, ... Song, HW*, Adv.Funct.Mater.25, pp.5462-5471, 2015.

[37]320-fold luminescence enhancement of [Ru(dpp)(3)]Cl-2 dispersed on PMMA opal photonic crystals and highly improved oxygen sensing performanceZhou. PW, Zhou. DL, ... Song. HW*, Light.Sci.&Appl.3, e209, 2014.

荣誉与获奖

中科院“百人计划”(2000)

日本陶瓷协会仓田国际交流奖(2005)

高等学校优秀科研成果奖自然科学二等奖(2008,排名第一)

国家杰出青年基金(2009)

吉林省科技进步一等奖(2010, 排名第二)

国家自然科学二等奖(2011, 排名第二)

第三批吉林省管高级专家(2013)

科技部重点领域创新团队负责人 (2017)

万人计划科技创新领军人才(2018)

国务院政府特殊津贴(2019)

吉林省自然科学一等奖(2020 排名第一)

入选 Light 人物(2021)

2014-2022 连续入选爱尔斯维尔中国高被引学者榜单(材料学)

2021-2022 全球学者学术影响力排行榜(2022 世界 No11962,中国 No715)

代表性科研项目

[1] 科技部国家重点研发计划 2024.11.22-2029.11.30,1500万,项目负责人

[2] 国家自然科学基金原创类项目 2023.12.20-2026.12.31,273万,项目负责人

[3] 国家自然科学基金面上项目 2023.09.21-2027.12.31,52 万,项目负责人

[4] 国家自然科学基金重点联合基金 2019.01.01-2022.12.31,255 万,项目负责人

[5] 国家自然科学基金面上项目 2019.01.01-2022.12.31,64 万,项目负责人

[6] 国家自然科学基金面上项目 2017.01.01-2020.12.31,70 万,项目负责人

[7] 国家自然科学基金面上项目 2014.01.01-2017.12.31,89 万,项目负责人

[8] 国家杰出青年基金,2010.01.01-2013.12.31,200 万,项目负责人

[9] 吉林省省校共建项目,2017.01.01-2020.12.31,300 万,项目负责人

[10] 国家“973”计划项目, 2014.01.01-2017.12.31,1506 万, 课题骨干

[11] 国家“863”计划项目,2008.01.01-2010.12.31,98 万,项目负责人

[12] 国家自然科学基金面上项目,2008.01.01-2010.12.31,32 万,项目负责人

[13] 国家自然科学基金面上项目, 2004-01.01-2006.12.31 , 27 万,项目负责人

[14] 中科院百人计划项目,2001.01-2003.12.31,200 万,项目负责人

更新于2025.3.3

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