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個(gè)人簡介

2009年畢業(yè)于中山大學(xué)獲博士學(xué)位。2009 年7 月至今在華南師范大學(xué)生物光子學(xué)研究院工作。主要從事納米材料制備、腫瘤細(xì)胞檢測與腫瘤治療、納米材料與生物體相互作用機(jī)制等領(lǐng)域的研究工作。迄今為止,在Small,Nanoscale, Advanced Functional Materials, Applied Physics Letters,Physical Review B/E 等國際知名SCI學(xué)術(shù)刊物發(fā)表論文五十余篇。受邀為國際材料科學(xué)領(lǐng)域權(quán)威綜述刊物Progress in Materials Science撰寫一篇關(guān)于納米材料制備的綜述文章(X. L. Li et al., Progress in Materials Science, 64, 121 (2014))(影響因子31.56)。

2023年碩士研究生調(diào)劑信息

研究生階段主要從事圖像處理、圖像分析、機(jī)器學(xué)習(xí)研究工作。歡迎對圖像處理、圖像分析感興趣的物理、數(shù)學(xué)、光電信息工程等相關(guān)專業(yè)的考生申請調(diào)劑。

擬接收調(diào)劑專業(yè)包括:
1.學(xué)碩:070207 光學(xué),0702J1 生物醫(yī)學(xué)光子學(xué),080300 光學(xué)工程
2.專碩:085408 光電信息工程

請有意調(diào)劑到本課題組的同學(xué)將個(gè)人簡歷或情況介紹(個(gè)人基本信息(姓名、性別、聯(lián)系電話等)、考研成績(總分,考試科目及單科成績)、報(bào)考院校與報(bào)考專業(yè)、本科院校與專業(yè)、四六級成績、本科學(xué)習(xí)成績等內(nèi)容)發(fā)送至郵箱:xlli@scnu.edu.cn

郵件標(biāo)題請按“本科院校名稱-姓名-報(bào)考院校名稱-本科專業(yè)或報(bào)考專業(yè)-考研分?jǐn)?shù)”格式,如“山東大學(xué)-張三-北京大學(xué)-物理-320”

課題組介紹

    本課題組主要開展物理、生物、材料、化學(xué)、醫(yī)學(xué)等學(xué)科交叉的生物物理、生物醫(yī)學(xué)材料領(lǐng)域的理論與實(shí)驗(yàn)研究工作。目前本課題組主要研究方向有:

1、 納米材料與細(xì)胞相互作用機(jī)制研究;

2、 納米材料在腫瘤診斷和治療中的應(yīng)用;

3、細(xì)胞圖像分析處理與機(jī)器學(xué)習(xí)

目前本課題組在讀博士研究生1名,碩士研究生8名。本課題組已培養(yǎng)博士畢業(yè)生1名,碩士畢業(yè)生9名,均以優(yōu)異成績獲得學(xué)位,即:

明瑞琪 (2022屆 學(xué)碩,華南師大十佳學(xué)術(shù)論文,目前在北京理工大學(xué)攻讀博士學(xué)位)

發(fā)表一作SCI論文2篇:[1]   Ruiqi Ming, Ye Jiang, Jiaqi Fan, Chunchun An, Jinqi Li, Tongsheng Chen*, and Xinlei Li*, High-Efficiency Capture of Cells by Softening Cell Membrane, Small 18, 2106547 (2022). (影響因子 15.153)

[2] Ruiqi Ming, Senyu Yang, Ye Jiang, Chunchun An, Yuhua Yang, Dongfeng Diao, Yuanyuan Cao*, Tongsheng Chen, and Xinlei Li*, Capture and isolation of tumor cells by graphene intercalated carbon film, Applied Physics Letters 120, 063702 (2022). (影響因子 3.971)

申請國家發(fā)明專利1項(xiàng)。

鄒靜 (2022屆 學(xué)碩)

發(fā)表一作SCI論文2篇:[1]   Jing Zou, Kun Jin, Tongsheng Chen and Xinlei Li*, The effects of substrate morphology by regulating pseudopods formation on cell directional alignment and migration, Journal of Physics D: Applied Physics 55, 105401 (2022). 

[2] Jing Zou, Jinqi Li, Tongsheng Chen and Xinlei Li*, Penetration mechanism of cells by vertical nanostructures, Physical Review E 102, 052401 (2020). 

楊森宇 (2022屆 專碩)

發(fā)表共同一作SCI論文1篇:Ruiqi Ming, Senyu Yang, Ye Jiang, Chunchun An, Yuhua Yang, Dongfeng Diao, Yuanyuan Cao*, Tongsheng Chen, and Xinlei Li*, Capture and isolation of tumor cells by graphene intercalated carbon film, Applied Physics Letters 120, 063702 (2022). (影響因子 3.971)

申請國家發(fā)明專利1項(xiàng)。

黨澤春 (2021屆 博士)

發(fā)表SCI論文1篇:Zechun Dang, Jizheng Sun, Jiaqi Fan, Jinqi Li, Xinlei Li*, and Tongsheng Chen*, Zinc oxide spiky nanoparticles: A promising nanomaterial for killing tumor cells, Materials Science & Engineering C 124, 112071 (2021). (影響因子 7.328)

范佳琪 (2021屆)

發(fā)表SCI論文1篇:Jiaqi Fan, Zechun Dang, Ting Lu, Jinqi Li, Tongsheng Chen, Yuhua Yang, and Xinlei Li*, Local release and isolation of circulating tumor cells captured by the nano-morphologic substrate coated with gelatin under near-infrared light, Journal of Materials Science, 56, 16634 (2021). 

申請國家發(fā)明專利1項(xiàng)。

盧汀 (2021屆)

發(fā)表SCI論文1篇:Ting Lu, Senyu Yang, Bingqi Zhang, Xinlei Li*, and Tongsheng Chen*, Graphene oxide-doped photothermal heater in microchannel for thermophoretically shifting micro- and nano-particles, Journal of Applied Physics 130, 244901 (2021).

陳華東 (2020屆,2019年獲研究生國家獎(jiǎng)學(xué)金)

發(fā)表SCI論文1篇:Huadong Chen, Hang Zang, Xinlei Li*, and Yanping Zhao*, Toward a Better Understanding of Hemiwicking: A Simple Model to Comprehensive Prediction, Langmuir, 35, 2854 (2019). 

周靜 (2019屆,2018年獲研究生國家獎(jiǎng)學(xué)金)

發(fā)表SCI論文2篇:(1)J. Zhou, Y. Xiong, Z. C. Dang, J. Q. Li, Xinlei Li*, Y. H. Yang*, and Tongsheng Chen*, Origin of efficiency enhancement in cell capture on nanostructured arrays, Journal of Materials Science, 54, 4236 (2019). 

(2)Jing Zhou, Xiaowei Zhang, Jizheng Sun, Zechun Dang, Jinqi Li, Xinlei Li* and Tongsheng Chen*, The effects of surface topography of nanostructure arrays on cell adhesion, Physical Chemistry Chemical Physics, 20, 22946 (2018). 

臧航 (2019屆)

發(fā)表SCI論文2篇:(1)Hang Zang,and Xinlei Li*, Physical understanding of the bending of nanostructures caused by cellular force, Physical Review E 101, 032406 (2020). 

(2)Hang Zang,Huadong Chen, Xinlei Li*, and Yanping Zhao*, An analytical model for the bending of radial nanowire heterostructures, Physical Chemistry Chemical Physics, 21, 9477 (2019). 

肖克 (2017屆,畢業(yè)后在廈門大學(xué)攻讀博士學(xué)位)

發(fā)表SCI論文2篇:(1)K. Xiao, Y. P. Zhao, G. Ouyang, and X. L. Li*, Modeling the effects of nanopatterned surfaces on wetting states of droplets, Nanoscale Research Letters, 12, 309 (2017). 

(2)K. Xiao, Y. P. Zhao, G. Ouyang, and X. L. Li*, An analytical model of nanopatterned superhydrophobic surfaces, Journal of Coatings Technology and Research, 14, 1297 (2017).  

教育背景

2009 年6 月畢業(yè)于中山大學(xué)物理科學(xué)與工程技術(shù)學(xué)院,獲材料物理與化學(xué)專業(yè)博士學(xué)位09/2005-06/2009 PHD in Materials Physics and Chemistry, Sun Yat-sen University, Guangzhou, P. R. ChinaThesis: Thermodynamic and kinetic theories of self-assembly of quantum dots and quantum rings Advisor: Prof. Guowei Yang

工作經(jīng)歷

2009年7月至今 華南師范大學(xué)生物光子學(xué)研究院/激光生命科學(xué)教育部重點(diǎn)實(shí)驗(yàn)室 07/2009-Present, College of Biophotonics, South China Normal University, P. R. China

研究興趣

細(xì)胞與納米結(jié)構(gòu)相互作用機(jī)制、腫瘤細(xì)胞檢測與分離、腫瘤治療、圖像分析與處理、機(jī)器學(xué)習(xí)

主要論文

(*Corresponding author)

主要論著目錄:

(*Corresponding author)

[1]      Jinqi Li, Xinlei Li*, Yangfeng Zhang, Kun Jin, Ye Yuan, Ruiqi Ming, Yuhua Yang, and Tongsheng Chen*, An intravascular needle coated by ZnO nanoflowers for in vivo elimination of circulating tumor cells, Nano Research 16, 873 (2023). (影響因子 10.269)

[2]      Nanxin Li, Kun Jin, Tongsheng Chen*, and Xinlei Li*, A static force model to analyze the nuclear deformation on cell adhesion to vertical nanostructures, Soft Matter 18, 6638-6644 (2022).

[3]      Ruiqi Ming, Ye Jiang, Jiaqi Fan, Chunchun An, Jinqi Li, Tongsheng Chen*, and Xinlei Li*, High-Efficiency Capture of Cells by Softening Cell Membrane, Small 18, 2106547 (2022). (影響因子 15.153)

[4]      Ruiqi Ming, Senyu Yang, Ye Jiang, Chunchun An, Yuhua Yang, Dongfeng Diao, Yuanyuan Cao*, Tongsheng Chen, and Xinlei Li*, Capture and isolation of tumor cells by graphene intercalated carbon film, Applied Physics Letters 120, 063702 (2022). 

[5]      Jing Zou, Kun Jin, Tongsheng Chen and Xinlei Li*, The effects of substrate morphology by regulating pseudopods formation on cell directional alignment and migration, Journal of Physics D: Applied Physics 55, 105401 (2022). 

[6]      Ting Lu, Senyu Yang, Bingqi Zhang, Xinlei Li*, and Tongsheng Chen*, Graphene oxide-doped photothermal heater in microchannel for thermophoretically shifting micro- and nano-particles, Journal of Applied Physics 130, 244901 (2021). 

[7]      Zechun Dang, Jizheng Sun, Jiaqi Fan, Jinqi Li, Xinlei Li*, and Tongsheng Chen*, Zinc oxide spiky nanoparticles: A promising nanomaterial for killing tumor cells, Materials Science & Engineering C 124, 112071 (2021). 

[8]      Jiaqi Fan, Zechun Dang, Ting Lu, Jinqi Li, Tongsheng Chen, Yuhua Yang, and Xinlei Li*, Local release and isolation of circulating tumor cells captured by the nano-morphologic substrate coated with gelatin under near-infrared light, Journal of Materials Science, 56, 16634 (2021). 

[9]      Xinlei Li*, The structural symmetry of nanoholes upon droplet epitaxy, Nanotechnology 32, 225602 (2021). 

[10]   Qingyun Jiang, Xinlei Li, and Chenping Yin*, A Study on Improving the Efficacy of Nanoparticle-Based Photothermal Therapy: From Nanoscale to Micron Scale to Millimeter Scale, Materials 14, 2407 (2021). 

[11]   Jing Zou, Jinqi Li, Tongsheng Chen and Xinlei Li*, Penetration mechanism of cells by vertical nanostructures, Physical Review E 102, 052401 (2020). (SCI indexed, IF 2.296) 

[12]   Hang Zang,and Xinlei Li*, Physical understanding of the bending of nanostructures caused by cellular force, Physical Review E 101, 032406 (2020). (SCI indexed, IF 2.296) 

[13]   Jinqi Li, Jizheng Sun, Tongsheng Chen and Xinlei Li*, Towards a better understanding of the effects of the magnetic nanoparticles size and magnetic field on cellular endocytosis, Journal of Physics D: Applied Physics 53, 175401 (2020). (SCI indexed, IF 3.196) 

[14]   Hang Zang,Huadong Chen, Xinlei Li*, and Yanping Zhao*, An analytical model for the bending of radial nanowire heterostructures, Physical Chemistry Chemical Physics, 21, 9477 (2019). (SCI indexed, IF 3.567) 

[15]   Huadong Chen, Hang Zang, Xinlei Li*, and Yanping Zhao*, Toward a Better Understanding of Hemiwicking: A Simple Model to Comprehensive Prediction, Langmuir, 35, 2854 (2019). (SCI indexed, IF 3.683)

[16]   J. Zhou, Y. Xiong, Z. C. Dang, J. Q. Li, Xinlei Li*, Y. H. Yang*, and Tongsheng Chen*, Origin of efficiency enhancement in cell capture on nanostructured arrays, Journal of Materials Science, 54, 4236 (2019). (SCI indexed, IF 3.442) 

[17]   Zhiqin Zhong, Xinlei Li, Jiang Wu, Cheng Li, Ruo Bing Xie, Xiaoming Yuan, Xiaobin Niu, Wenhao Wang, Xiaorong Luo, Guojun Zhang, Zhiming M. Wang, Hark Hoe Tan, and Chennupati Jagadish, Wavelength-tunable InAsP quantum dots in InP nanowires, Applied Physics Letters, 115, 053101 (2019). 

[18]   Jing Zhou, Xiaowei Zhang, Jizheng Sun, Zechun Dang, Jinqi Li, Xinlei Li* and Tongsheng Chen*, The effects of surface topography of nanostructure arrays on cell adhesion, Physical Chemistry Chemical Physics, 20, 22946 (2018). (SCI indexed, IF 3.906)

[19]   X. P. Meng and X. L. Li*, Size Limit and Energy Analysis of Nanoparticles during Wrapping Process by Membrane, Nanomaterials, 8, 899 (2018). (SCI indexed, IF 3.504) 

[20]   X. L. Li, J. Ni, and R. Q. Zhang*, A Thermodynamic Model of Diameter- and Temperature-dependent Semiconductor Nanowire Growth, Scientific Reports, 7, 15029 (2017). (SCI indexed, IF 4.122) 

[21]   K. Xiao, Y. P. Zhao, G. Ouyang, and X. L. Li*, Modeling the effects of nanopatterned surfaces on wetting states of droplets, Nanoscale Research Letters, 12, 309 (2017). (SCI indexed, IF 3.125) 

[22]   K. Xiao, Y. P. Zhao, G. Ouyang, and X. L. Li*, An analytical model of nanopatterned superhydrophobic surfaces, Journal of Coatings Technology and Research, 14, 1297 (2017). (SCI indexed, IF 1.619)  

[23]   Jiang Wu, Zhiming M. Wang, Xinlei Li, Yuriy I. Mazurand Gregory J. Salamo, Fabrication of ultralow-density quantum dots by droplet etching epitaxy, Journal of Materials Research, 32, 4095 (2017). 

[24]   X. L. Li*, Bactericidal mechanism of nanopatterned surfaces, Physical Chemistry Chemical Physics, 18, 1311 (2016). (SCI indexed, IF 3.906) 

[25]   X. L. Li* and T. S. Chen, Enhancement and suppression effects of a nanopatterned surface on bacterial adhesion, Physical Review E 93, 052419 (2016). (SCI indexed, IF 2.284) 

[26]   X. L. Li, C. X. Wang, and G. W. Yang*, Thermodynamic theory of growth of nanostructures, Progress in Materials Science, 64, 121 (2014). (SCI indexed, IF 27.417)

[27]   X. L. Li,* J. Wu, Z. M. Wang,* B. L. Liang, J. H. Lee, E. S. Kim, and G. J. Salamo. Origin of nanohole formation by etching based on droplet epitaxy, Nanoscale, 6, 2675 (2014). (SCI indexed, IF 7.394) 

[28]   J. Wu#, Y. Hirono#, X. L. Li#, Z. M. Wang*, J. H. Lee, M. Benamara, S. Luo, Y. I. Mazur, E. S. Kim, and G. J. Salamo. Self-Assembly of Multiple Stacked Nanorings by Vertically Correlated Droplet Epitaxy, Advanced Functional Materials 24, 530 (2014).  (# These authors contributed equally/同等貢獻(xiàn)) (SCI indexed, IF 11.805) 

[29]   X. L. Li* and G. W. Yang, Modification of Stranski-Krastanov growth on the surface of nanowires,Nanotechnology, 25, 435605 (2014). (SCI indexed, IF 3.821) 

[30]   X. L. Li,* Modeling the size- and shape-dependent cohesive energy of nanomaterials and its applications in heterogeneous systems, Nanotechnology, 25, 185702 (2014). (SCI indexed, IF 3.821)

[31]   X. L. Li*, Selective formation mechanisms of quantum dots on patterned substrates, Physical Chemistry Chemical Physics, 15, 5238 (2013). (SCI indexed, IF 4.493) 

[32]   X. L. Li*, Theory of controllable shape of quantum structures upon droplet epitaxy, Journal of Crystal Growth, 377, 59 (2013). (SCI indexed, IF 1.698)

[33]   X. L. Li*, Size effects of carbon nanotubes and graphene on cellular uptake, EPL 100, 46002 (2012). (SCI indexed, IF 2.095)

[34]   X. L. Li*, The influence of the atomic interactions in out-of-plane on surface energy and its applications in nanostructures, Journal of Applied Physics 112, 013524 (2012). (SCI indexed, IF 2.183) 

[35]   X. L. Li*, Size and shape effects on receptor-mediated endocytosis of nanoparticles, Journal of Applied Physics 111, 024702 (2012). (SCI indexed, IF 2.183) 

[36]   X. L. Li* and G. Ouyang, Thermodynamic theory of controlled formation of strained quantum dots on hole-patterned substrates, Journal of Applied Physics 109, 093508 (2011). (SCI indexed, IF 2.183) 

[37]   X. L. Li*, G. Ouyang and X. Tan, Thermodynamic stability of quantum dots on strained substrates, Physica E 43, 1755 (2011). (SCI indexed, IF 2.0)

[38]   X. L. Li* and D. Xing, A simple method to evaluate the optimal size of nanoparticles for endocytosis based on kinetic diffusion of receptors, Applied Physics Letters 97, 153704 (2010). (SCI indexed, IF 3.302)

[39]   X. L. Li*, Y. Y. Cao and G. W. Yang, Thermodynamic theory of two-dimensional to three-dimensional growth transition in quantum dots self-assembly, Physical Chemistry Chemical Physics 12, 4768 (2010). (SCI indexed, IF 4.493) 

[40]   X. L. Li*, Formation Mechanisms of Multiple Concentric Nanoring Structures upon Droplet Epitaxy, Journal of Physical Chemistry C 114, 15343 (2010). (SCI indexed, IF 4.772)

[41]   X. L. Li*, Thermodynamic Theory of quantum dot self-assembly on strained substrates, Journal of Physical Chemistry C 114, 2018 (2010). (SCI indexed, IF 4.772) 

[42]   X. L. Li*, Thermodynamic analysis on the stability and evolution mechanism of self-assembled quantum dots, Applied Surface Science 256, 4023 (2010). (SCI indexed, IF 2.711)

[43]   X. L. Li*, Surface chemical potential in multilayered Stranski-Krastanow systems: An analytic study and anticipated applications, Journal of Applied Physics 106, 113520 (2009). (SCI indexed, IF 2.183) 

[44]   X. L. Li and G. W. Yang, On the physical understanding of quantum rings self-assembly upon droplet epitaxy, Journal of Applied Physics 105, 103507 (2009). (SCI indexed, IF 2.183) 

[45]   X. L. Li and G. W. Yang, Thermodynamic theory of shape evolution induced by Si capping in Ge quantum dots self-assembly, Journal of Applied Physics 105, 013510 (2009). (SCI indexed, IF 2.183) 

[46]   X. L. Li and G. W. Yang, Strain self-releasing mechanism in heteroepitaxy on nanowire, Journal of Physical Chemistry C 113, 12402 (2009). (SCI indexed, IF 4.772) 

[47]   X. L. Li and G. W. Yang, Theoretical determination of contact angle in quantum dot self-assembly, Applied Physics Letters 92, 171902 (2008). (SCI indexed, IF 3.302) 

[48]   X. L. Li and G. W. Yang, Growth mechanisms of quantum ring self-assembly upon droplet epitaxy, Journal of Physical Chemistry C 112, 7693 (2008). (SCI indexed, IF 4.772) 

[49]   X. L. Li, G. Ouyang and G. W. Yang, A thermodynamic theory of the self-assembly of quantum dots, New Journal of Physics 10, 043007 (2008). (SCI indexed, IF 3.558)

[50]   X. L. Li, G. Ouyang and G. W. Yang, Surface Alloying at the Nanoscale: Mo on Au Nanocrystalline Films, Nanotechnology 19, 505303 (2008). (SCI indexed, IF 3.821) 

[51]   X. L. Li, G. Ouyang and G. W. Yang, Thermodynamic model of metal-induced self-assembly of Ge quantum dots on Si substrates, European Physical Journal B 62, 295 (2008). (SCI indexed, IF 1.345)

[52]   X. L. Li, G. Ouyang and G. W. Yang, Thermodynamic theory of nucleation and shape transition of strained quantum dots,Physical Review B 75, 245428 (2007). (SCI indexed, IF 3.736) 

[53]   Y. Y. Cao, X. L. Li and G. W. Yang, Physical mechanism of quantum dot to quantum ring transformation upon capping process,  Journal of Applied Physics 109, 083542 (2011). 

[54]   Y. Y. Cao, X. L. Li and G. W. Yang, Wetting layer evolution upon quantum dots self-assembly, Applied Physics Letters 95, 231902 (2009). 

[55]   G. Ouyang, X. L. Li and G. W. Yang, Superheating and melting of nanocavities, Applied Physics Letters 92, 051902 (2008). 

[56]   X. Tan, X. L. Li and G. W. Yang, Theoretical strategy for self-assembly of quantum rings, Physical Review B 77, 245322 (2008). 

[57]   G. Ouyang, X. L. Li, X. Tan and G. W. Yang, Surface free energy of nanowires, Nanotechnology 19, 045709 (2008). 

[58]   G. Ouyang, X. L. Li and G. W. Yang, Sink-effect of nanocavities: Thermodynamics and kinetic approach, Applied Physics Letters 91, 051901 (2007). 

[59]   G. Ouyang, X. L. Li, X. Tan and G. W. Yang, Anomalous Young’s modulus of a nanotube, Physical Review B 76, 193406 (2007). 

[60]   G. Ouyang, X. L. Li, X. Tan and G. W. Yang, Size-induced strain and stiffness of nanocrystals, Applied Physics Letters 89, 031904 (2006). 

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