程春 副教授

    程春,博士,为南方科技大学材料科学与工程系独立课题组负责人、Tenure序列副教授(研究员),校本科教学指导委员会委员,国家重大研究计划纳米专项、深圳市孔雀团队等项目核心科学家。入选国家科技部重点领域创新团队“新型薄膜太阳电池基础及应用研究”成员,广东省“南粤优秀教师”,广东省“杰出青年”,广东省“优秀青年教师”,广东省“青年拔尖人才”及深圳市“优秀教师”,深圳市“孔雀计划”入选者(B类),国际材料学会会员(MRS),深圳市海外高层次人才联谊会、专家人才联合会发起人及理事,深圳市青年科技协会理事,南方科技大学校友会理事。

    在国际专业期刊发表SCI论文逾90篇(影响因子大于10的10余篇),引用逾千次,ESI高引论文1篇,封面文章2篇,他引次数超过100的2篇,引用次数超过10的文章40篇,H-index 23,其中包括Nat. Commun., Nano Lett.(3), ACS Nano (5), Adv. Mater., J. Am. Chem. Soc., J. Mater. Chem. A (3)等,获授权专利1项,申请专利10项;从2013年至今,获3项国家自然科学基金,1项国家科技部纳米专项,1项广东省杰出青年基金等10余项基金资助, 主持省部级及以上基金8项。作为评审专家审核国家自然科学基金项目以及广东省、深圳市各类科技类基金项目,是Nano Lett.,ACS Nano,Adv. Mater. 等期刊的长期审稿人,Elsevier – Journal of Science: Advanced Materials and Devices编委。目前正在筹建“普太光伏科技有限公司”,推动新型钙钛矿太阳能电池的研发与产业化,为公司的创始人之一。2016年荣获深圳市“青年科技奖”。


学习经历


博士(2004.09-2009.07) 纳米科学技术 香港科技大学

硕士(2002.09-2004.07) 凝聚态物理学 物理系, 华中师范大学

本科(1998.09-2002.07) 物理学 (国家基地班) 物理系, 华中师范大学



科研工作经历

2013.6-至今   副教授, 材料科学与工程系, 南方科技大学

2011.5-2013.3博士后雇员, 加州大学伯克利分校 &劳伦斯伯克利国家实验室材料科学分部 

导师: 吴军桥教授和Costas P. Grigoropoulos教授

2009.9-2011.4 博士后研究员, 物理系, 香港科技大学 导师:王宁教授

2006.9-2009.8 研究助理, 物理系, 香港科技大学 导师:王宁教授



学术任职


项目评审会审专家 行政职务和社会职务期刊审稿人
国家自然科学基金项目                         南方科技大学教授会常务委员

Elsevier -

Journal of Science: Advanced Materials and

Devices'  Member of the

Editorial Board 编委

(Associate Editor user role )

广东省杰出青年项目                   南方科技大学校“招生专家小组“成员  
广东省自然科学基金项目                南方科技大学校校系两级教学督导委员会成员
广东省博士后启动项目                        南方科技大学材料科学与工程系
深圳市基础研究项目                           “十三五规划调研小组”成员
深圳市协同创新计划项目          南方科技大学材料科学与工程系教学指导委员会委员
深圳市银政企合作项目      南方科技大学材料科学与工程系教学实验室管理工作组组长 

       南方科技大学材料科学与工程系教学科研楼设计小组 成员 
                          深圳市高层次人才联谊会理事
                             深圳市青年科技协会理事

      


 

获奖情况及人才培养资助


南方科技大学第一届青年教师教学竞赛优秀奖 ,2016年 

  南方科技大学“青年科研奖”,2016年  

深圳市“师德标兵”(南方科技大学提名推荐),2016年 

  Elsevier 出版社 “Valued Reviewer” Elsevier Reviewer Recognition,2015年  

广东省“杰出青年”人才培养计划项目资助, 2015.7.12  

广东省“优秀青年教师” 人才培养计划项目资助, 2015.12.9  

广东特支计划“科技创新青年拔尖人才”, 2015年 

  深圳市高层次海外引进人才“孔雀计划”B类,2013年  

首届深龙创业星ž训练营 唯一“优秀小组”称号,2015年  

国家长江学者-青年长江候选人推荐, 2015年  

广东省教育厅认定,获得“教师资格证书”, 2014年 

  南方科技大学“招生工作先进个人”,2015年 

  南方科技大学“招生工作优秀集体二等奖”,2014,2015年  

南方科技大学“招生工作优秀集体一等奖”,2013年 

  香港科技大学博士研究生全额奖学金, 2004-2009年  

湖北省优秀硕士毕业论文, 2004年  

华中师范大学优秀毕业生, 2004年  

华中师范大学研究生一等奖学金, 2002-2003, 2003-2004年  

湖北省大学生优秀研究成果一等奖, 2001年


研究兴趣

课题组目前主要研究方向包括智能材料、能源材料、二维无机柔性电子材料与器件等。主要包括:1)基于二氧化钒微纳材料相变的智能材料与结构:智能材料的制备、响应特性调节及特色应用如近场功率计、微型制动器、红外探测器、智能玻璃等; 2)能源材料:先进微纳功能材料在光分解水制氢、储能材料(锂离子电池及超级电容器)以及智能窗户节能材料等方面的应用;新型钙钛矿太阳能电池的研发与产业化; 3)二维材料:无机二维材料的规模制备(大面积单晶、层数可控、异质结构、低温柔性衬底直接生长等)、连续绿色转移技术及器件应用。近5年发表SCI论文30余篇, 系列工作被美国劳伦斯国家实验室LBNL NEWs Center高度评价,并被多家著名的网络科技媒体如Science Daily, PHYS.ORG, Materials Views, Materials360online等广泛报道,展现出年轻科研工作者优秀的科研水平和发展潜力。


研究工作

    一、纳米VO2结构可控制备、相变特性调控及新型器件研发:

‍‍    1. 高密度自立生长超长VO2纳米线‍‍

        与块材和薄膜相比,VO2微纳米线具有可控稳定的相变,是研究单畴相变物理的理想系统,在器件应用上具有更多的优势。采用低熔点蒸发源,结合氧化钒纳米线贴在衬底抛光表面生长的特点,在粗糙表面生长出高密度、超长(长达5mm)且自立纳米线(结果发表于Appl. Phys. Lett. 100(2012), 103111)。这个工作将VO2纳米线从衬底表面“解放”出来,方便纳米线转移与器件制作,为其在忆阻器、莫特晶体管、光学开关、应力和气体传感器等应用研究打下了基础。随后,我们进一步实现在较廉价的石英衬底上取向生长VO2微纳米线(Scientific Reports, 2014, in press)。

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     2. VO2纳米线梯度掺杂及应用拓展

        掺杂是调节相变温度,拓宽VO2应用的重要手段。我们首次实现纳米线轴向钨的梯度掺杂(发表于J. Am. Chem. Soc. 135 (2013) 4850) 。研究表明这种梯度掺杂纳米线具有随温度沿着轴向移动的高对比度相变畴界,我们基于此开发了光学可读取的纳米温度计,可实现对单个细胞的实时监测。掺杂纳米线高达15%/K的热阻系数以及较低的电阻率,可作为极好的远红外热辐射传感材料;梯度的结构相变也使得这种材料具有高幅度和宽温度响应的双晶片微致动器的应用前景。

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    3. 基于单畴相变的微纳尺度热输运测量平台

       VO2的单畴相变畴界能被光学读取,精确指示温度。基于此,我们首次利用氧化钒单晶微纳悬臂作为纳米温度计/功率计研究了纳米尺度下固体与气体界面的热传输。确定了热传输系数随气压和固体尺寸的规律,并指出气固界面的传热对考虑纳米器件的热耗散过程的重要性(结果发表在ACS Nano 5 (2011) 10102)。我们开发了基于VO2单畴相变的微纳尺度热输运测量平台,实现在单个纳米器件水平上定量测量纳米线的光吸收、热导率等基本的参数(Adv.Optic. Mat. (2014) accepted)。对于纳米尺度下新热物理学和能源的转化与热管理研究方面,此工作做出很大贡献。

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    4. 高性能VO2@Cr双晶片微纳致动器

       基于VO2@Cr的双晶片结构薄膜,利用先进微制造技术,我们设计并批量化制作了梳状、花状以及弹簧结构的微致动器阵列(结果发表于Nano Lett. 12 (2012) 6302 和 Adv.Mater. 26 (2014)1746 )。这些微致动器展现了极高的工作性能(0.63 J/cm3,6kHZ),良好的工作环境适应性(空气和液体中),激发源多样性(光、热、电等)以及多功能性(固体热机、机械手、接触感应器、忆阻器等)(结果发表于ACSNano, 7 (2013) 2266 和 Nano Lett. 13 (2013) 4685)。我们对VO2致动器的系统研究为开发新微机电与能量转化微器件做出了重要贡献。

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    二、电子透射显微术对低维纳米结构分析和无机纳米材料(特别是ZnO)的可控生长,性能调控以及器件应用等的研究

    1. 原位透射电镜研究纳米结构的转化与异质结的形成机制

       通过自制在高分辨透射电子显微镜中用于原位反应的加热台。Si纳米线和Ni反应形成单晶的NiSi2纳米线以及SiC包覆的硅化镍异质壳核结构的过程被实时观测研究。结果表明SiO2层在形成上述结构的过程中起着关键性的作用。对NiSi2形成机制的理解使得这种材料非常可能发展成为一种理想的用于Si纳米线器件电学连接材料(结果发表在ACS Nano 2010 4 (10), 5559-5564)。

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    2. 低维ZnO结构可控生长及光电性质调控

       a) 碳基薄膜辅助合成ZnO纳米线阵列:利用光刻胶及碳膜在硅片上实现低成本、大面积(晶片尺寸级别)、图案化合成高质量且竖直生长的ZnO纳米线阵列,与现有CMOS工艺兼容,为大规模器件应用铺平道路(结果发表于ACSNano 3 (2009) 53和AIP Advances 1 (2011) 032104)

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       b) 纳米ZnO材料光学及电学特性的调控:1.利用近场光学显微镜和透射电子显微镜研究并提出了纳米ZnO材料本征发光“尺寸效应”的“表面效应”机制及非本征发光的“结构缺陷”来源(结果发表在Nanotech. 19 (2008)405702和Appl. Phys. Lett. 95 (2009), 053113) 2.发展对纳米ZnO中的本征缺陷进行调节的后处理方法,改善材料的光学和电学性质(结果发表在Appl. Phys. Lett. 96,(2010) 223105和Solid State Communications, 160, (2013)41)

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    3. 纳米ZnO结构调控及增强性能应用

       a) 发展直接沉淀法以及定位生长技术,设计合成系列ZnO多级结构和TiO2/ZnO、Ag/ ZnO、Si/ZnO等功能异质结构,展示了结构调控对纳米材料在光催化,染料敏化电池等方面性能的增强(结果分别发表在J. Phys. Chem. C 115 (2007), 78;CrystalDesign & Growth 9 (2009), 3278;Crystal Design &Growth, 11 (2011), 147;Nanotech. 2011 21 (47), 475703; Phys. Chem. Chem. Phys. 13 (2011), 10631;J.Mater. Chem. 22 (2012) 13097;J. Nanomater. (2012)212653)。     

 

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      b) 我们的研究首次展示了纳米ZnO生物兼容性及纳米晶体极性方向确定的新方法(结果发表于Inorg.Chem. 47 (2008) 7868)。利用纳米线阵列以及多级结构比表面积大,易分离的特点,我们将表面进行功能化修饰的纳米结构应用于蛋白质的分离与提纯,与当前商业产品相比,其表现更加优异的纯化效率(300%)和活性(一年以上);选择吸附特定的蛋白酶,这些纳米结构用于血糖降解,为纳米材料在糖尿病治疗的医疗器械开发奠定了基础(结果发表于NANO,8, (2013) 1350029)

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代表性论文

1)     J. Wu, R. Shi; B. N Chandrashekar, Z. Zhu, A. Wang, C. Cheng, B. Xu*, H. Zhang* Nano-wire interlaced structured vanadium oxide and nano silicon composite as anode for advanced lithium ion battery, Electrochemistry Communications, 2017, reviewing

2)     Phosphorous doped graphitic-C3N4 hierarchical architecture for hydrogen production from water under visible light, Linfei Zhang#, Yi Zhang#, Run Shi, Shuhan Bao, Jingwei Wang, Abbas Amini, Bananakere Nanjegowda Chandrashekar, Chun Cheng* Materials Today Energy, 5 (2017) 91-98

3)     A. Hezam, K. Namratha, Q.A. Drmosh, B. N. Chandrashekar, Z. Yemani , C. Cheng * and  K. Byrappa,*Heterogeneous Growth Mechanism of Zinc Oxide  Flower-Like Structures and their Morphology Effect on Optical and Photocatalytic Properties, CrystEngCommaccepted

4)     Liu, Chang; Ding, Wenhui; Zhou, Xianyong; Gao, Jishu; Cheng, Chun; Zhao, Xing-Zhong; Xu, Baomin*, Efficient and Stable Perovskite Solar Cells Prepared in Ambient Air Based on Surface-Modified Perovskite, J. Phys. Chem. C, 121(2017), 65466553 2017-03-09

5)     K. Sadri, A. Amini*, C. Cheng, A new numerical method for delay and advanced integro-differential equations, Numerical Algorithms, (2017) 1-32 2017-04-05

6)     K. Sadri, A. Amini*, C. Cheng, Low cost numerical solution for three-dimensional linear and nonlinear integral equations via three-dimensional Jacobi polynomials, Journal of Computational and Applied Mathematics, 319(2017), 493–513 2017-08-01

7)     B.N. Chandrashekar, B.E. Kumara Swamy*, K.J. Gururaj, and C. Cheng, Simultaneous Determination of Epinephrine, Ascorbic acid and Folic acid using TX-100 Immobilized Modified Carbon Paste Electrode: A Cyclic Voltammetric Study, Journal of Molecular Liquids, 231 (2017) 379385 2017-04-01

8)     X. Yang,  L.Hu, H. Deng, K. Qiao, C. Hu, Z. Liu, S. Yuan, J. Khan, D. Li, J. Tang,  C. Cheng *, Haisheng Song* Improving the Performance of PbS Quantum Dot Solar Cells by Optimizing ZnO Window Layer, Nano-Micro Letters, 9 (2017) 24, pp 1-10 2017-01-04

9)     G. Zhang, J. Wang, Z. Wu, R. Shi, W. Ouyang, A. Amini, B.N. Chandrashekar, N.  Wang and C. Cheng*, Shape-Dependent Defect Structures in Monolayer MoS2 Crystals Grown by Chemical Vapor Deposition, ACS Appl. Mater. Interfaces, 2017, 9 (1), pp 763–770 2016-12-08

10)  S. Xu, Z. Wu, H. Lu, Y. Han, G. Long, X. Chen, T. Han, W. Ye, Y. WU, J. Lin, J. Shen, Y. Cai, Y. He, F. Zhang, R. Lortz, C. Cheng and N. Wang *, Universal low-temperature Ohmic contacts for quantum transport in transition metal dichalcogenides, 2D Mater.3 (2016)021007. 2016-04-22

11)  L. Zhang, M. Yang, Z. Wu, A.  Amini, W. Cao, J. Feng, X. FanR.  Shi, C. Huang, Z. Lu, N. Wang and C. Cheng* Carbon-coated V2O5/SnO2-x Nanocomposites as Multifunctional Materials for High Performance Lithium-ion Batteries and Visible-light Photocatalysts, Scientific Reports, 6 (2016) 33597 2016-09-28

12)  Y. Wu, X. Chen, Z. Wu, S. Xu, T. Han, J. Lin, B. Skinner, Y. Cai, Y. He, C. Cheng, and Ning Wang*, Negative compressibility in graphene-terminated black phosphorus heterostructures, Phys. Rev. B 93 (2016) 035455 2016-01-29

13)  Y. Shi, S. H. Bao, R. Shi, C. Z. Huang, A. Amini, Z. F. Wu, L. F. Zhang, N. Wang and C. Cheng*, Y-shaped ZnO Nanobelts Driven from Twinned Dislocations Scientific Reports, 6 (2016) 22494 2016-03-01

14)  R. Shi, C. Huang, L. Zhang, A. Amini, K. Liu, Y. Shi, S. Bao, N. Wang, C. Cheng*, Three Dimensional Sculpturing of Vertical Nanowire Arrays by Conventional Photolithography Scientific Reports, 6 (2016)18886 2016-01-05

15)  Z. Wu, Y. Guo, Y. Guo, R. Huang, S. Xu, J. Song, H. Lu, Z. Lin, Y. Han, H. Li, T. Han, J. Lin, Y. Wu, G. Long, Y. Cai, C. Cheng, D. Su, J. Robertson, and N. Wang, A fast transfer-free synthesis of high-quality monolayer graphene on insulating substrates by a simple rapid thermal treatment. Nanoscale, 8 2016 2594-2600 2015-10-09

16)  C. Huang, R. Shi, A. Amini, Z. Wu, S. Xu, L. Zhang, W. Cao, J. Feng,  H. Song, Y. Shi, N. Wang and C. Cheng*, Hierarchical ZnO Nanostructures with Blooming Flowers Driven by Screw Dislocations Scientific Reports, 5 (2015) 8266

17)  H. Guo, M. I. Khan, C. Cheng, W. Fan, C. Dames, J. Wu and A. M. Minor*, VO2 nanowire-based microthermometer for quantitative evaluation of electron beam heating, Nature Communication 5 2015 4986

18)  C. Cheng, D. Fu, K. Liu, H. Guo, S. Xu, S. Ryu, O. Ho, J. Zhou, W. Fan, W. Bao, M. Salmeron, N. Wang, C. P. Grigoropoulos, and J. Wu*, Directly metering light absorption and heat transfer in single nanowires using metal-insulator transition, Adv. Opt. Mater., 32015336Highlighted by MaterialsViews

19)  A. Amini*, C. Yang, C. Cheng, M. Naebe and Y. Xiang, Nanoscale variation in energy dissipation in austenitic shape memory alloys in ultimate loading cycles, Journal of Intelligent Material Systems and Structures, (2014) 1-7

20)  C. Cheng*, H. Guo, A. Amini, K. Liu, D. Fu, J. Zou, H. Song, Self-assembly and horizontal orientation growth of VO2 nanowires, Scientific Reports, 4 (2014) 5456

21)  C. Cheng*, A. Amini, C. Zhu, Z. Xu, H. Song, N. Wang*, Enhanced photocatalytic performance of TiO2-ZnO hybrid nanostructures, Scientific Reports, 4 20144181ESI highly cited paper

22)  A. Amini*, C. Cheng*, Q. Kan, M. Naebe, H. Song, Phase Transformation Evolution in NiTi Shape Memory Alloy under Cyclic Nanoindentation Loadings at Dissimilar Rates., Scientific Reports, 3 (2013) 3412 (Co-corresponding author)

23)  K. Liu, C. Cheng, J. Suh, R. Tang-Kong, D.Fu, S. Lee, J. Zhou, L. O. Chua, J. Wu, Powerful, Multifunctional Torsional Micro Muscles Activated by Phase Transition, Adv. Mater., (2014), 26, 1746.

(News release “A Micro-Muscular Break Through” in BERKELEY LAB News Center, also featured in DOE and NSF websites)

24)  P. Parikh, C. Chakraborty, A. Sebastian, S. Sengupta, C. Cheng, J. Wu, MM Deshmukh, Dynamically tracking the strain across the metal-insulator transition in VO2 measured using electromechanical resonators, Nano Lett. 13 (2013) 4685

25)  A. Amini*, C. Cheng*, Nature of hardness evolution in nanocrystalline NiTi shape memory alloys during solid-state phase transition, Scientific Reports 3 (2013) 2476 (Co-corresponding author)

26)  A. Amini, C. Cheng, M. Naebe, JS Church, N. Hameed, A. Asgari, F. Will, Temperature variations at nano-scale level in phase transformed nanocrystalline NiTi shape memory alloys adjacent to graphene layers, Nanoscale, 5, (2013), 6479

27)  A Amini, C Cheng, A Asgari, Combinational rate effects on the performance of nano-grained pseudoelastic Nitinols, Mater. Lett. 105 (2013) 98

28)  S Lee, C. Cheng, H. Guo, K. Hippalgaonkar, K. Wang, J. Suh, K. Liu, J. Wu, Axially engineered metal-insulator phase transition by graded doping vo2 nanowires, J. Am. Chem. Soc. 135 (2013) 4850

29)  S. Xu, C. Cheng, W. Guo, Y. He, R. Huang, S. Du, N. Wang, Tuning the optical and electrical properties of hydrothermally grown ZnO nanowires by sealed post annealing treatment, Solid State Communications, 160, (2013) 41

30)  Q. Hu*, C. Cheng*, W. Qin, Y.Q. Liu, S. Xu, B.Z. Tang, N. Wang, N. Li, Ni-NTA-coated nanowire materials for protein enrichment and the application in a medical device used for blood glucose degradation, NANO, 8, (2013) 1350029 (co-first author)

31)  A Amini, N Hameed, JS Church, C Cheng, A Asgari, F Will,Effect of graphene layers on the thermomechanical behaviour of a NiTi shape memory alloy during the nanoscale phase transition, Scripta Materialia, 68, (2013) 420

32)  K. X. Wang, C. Cheng, E. Cardona, J. Guan, K. Liu, J. Wu, Performance Limits of Microactuation with Vanadium Dioxide as a Solid Engine, Acs Nano, 7 (2013) 2266

33)  D. Fu*, K. Liu*, T. Tao, K. Lo, C. Cheng, B. Liu, R. Zhang, H. Bechtel, J. Wu, A Systematic, Comprehensive Study of Metal-Insulator Transition in Pulsed Laser Deposited Epitaxial VO2 Thin Films, J. Appl. Phys., 113, (2013) 043707

34)  C. Zhu, Y. Shi, C. Cheng, L. Wang, K. K. Fung, and N. Wang, Correlation between the morphology and performance enhancement of zno hierarchical flower photoanodes in quasi-solid dye-sensitized solar cells, J. Nanomater. (2012) 212653

35)  K. Liu, C. Cheng, Z. Cheng, K. Wang, R. Ramesh, J. Wu, Giant-Amplitude, High-Work Density Microactuators with Phase Transition Activated Nanolayer Bimorphs, Nano Lett., 12, (2012) 6302

(News release “Flexing fingers for micro-robotics” in BERKELEY LAB News Center, also featured in DOE and NSF websites)

36)  K. Liu, D. Fu, J. Cao, J. Suh, K. X. Wang, C. Cheng, D. F. Ogletree, H. Guo, S. Sengupta, A.Khan, C. W. Yeung, S. Salahuddin, M. M. Deshmukh, J. Wu, Dense Electron System from Gate-Controlled Surface Metal-Insulator Transition, Nano Lett., 12, (2012) 6272

37)  J. Zhou, M. Trassin, Qi. He, N. Tamura, M. Kunz, C. Cheng, J. Zhang, W. Liang, J. Seidel, C. Hsin, and J. Wu, Directed Assembly of Nano-scale Phase Variants in Highly Strained BiFeO3 Thin Films, J. Appl. Phys., 112 (2012) 064102.

38)  Y. Shi, C. Zhu, L. Wang, W. Li, C. Cheng, K. M. Ho, K. K. Fung, and N. Wang “Optimizing Nanosheet-based ZnO Hierarchical Structure through Ultrasonic-assisted Precipitation for Remarkable Photovoltaic Enhancement in Quasi-solid Dye-sensitized Solar Cells” J. Mater. Chem. 22 (2012)13097

39)  C. Cheng, K. Liu, B. Liu, J. Suh and J. Wu “Ultra-long, free-standing, single-crystalline vanadium dioxide micro/nanowires grown by simple thermal evaporation” Appl. Phys. Lett. 100 (2012) 103111

40)  C. Cheng, W. Fan, J. Cao, S.G. Ryu, J. Ji, G. P. Grigoropoulos and J. Wu “Heat Transfer across the Interface between Nanoscale Solids and Gas” ACS Nano 5 (2011) 10102

41)  C. Zhu, C. Cheng, Y.H. He, Lin W, T.L. Wong, K.K. Fung and N. Wang “A self-entanglement mechanism for continuous pulling of carbon nanotube yarns” Carbon 49 (2011) 4996

42)  C. Cheng, T.L. Wong, W. Le, C. Zhu, S.G. Xu, L. Wang, K. K. Fung, and N. Wang “Carbon-assisted nucleation and vertical growth of high-quality ZnO nanowire arrays” AIP Advances 1 (2011) 032104 Top 2 Most downloaded paper in Sept. 2011 and highlighted

43)  C. Cheng, Y. Shi, C. Zhu, W. Li, L. Wang, K. K. Fung and N. Wang “ZnO Hierarchical Structures for Efficient Quasi-solid Dye-sensitized Solar Cells”, Phys. Chem. Chem. Phys. 13 (2011)10631

44)  T. L. Wong, G. W. She, C. Cheng, W. Li, W. S. Shi, X. H. Zhang, and N. Wang, “Fabrication and structure characterization of Te butterfly nanostructures”, J. Nanosci. Nanotech. 11 (2011) 11037

45)  C. Cheng, W. Li, T. L. Wang, K. M. Ho, and N. Wang, “Zn2TiO4/ZnO Axial Nanowire Heterostructures by Unilateral Diffusion” J. Phys. Chem. C 115 (2011) 78

46)  H. S. Song, W. J. Zhang, C. Cheng, Y. B. Tang,L. B. Luo, X. Chen,C. Y. Luan, X. M. Meng, J. A. Zapien, N. Wang, C. S. Lee, I. Bello, and S. T. Lee “Controllable Fabrication of Three-Dimensional Radial ZnO Nanowire/Silicon Microrod Hybrid Architectures” Crystal Growth & Design 11, (2011) 147

47)  B. D. Yao , L. Feng , C. Cheng , M. M. T. Loyand N. Wang, “Tailoring the Luminescence Emission of ZnO Nanostructures by Hydrothermal Post-Treatment in Water” Appl. Phys. Lett. 96, (2010) 223105

48)  C. Cheng, T. L. Wang, L. Feng, W. Li, K. M. Ho, M. M. T. Loy, K. K. Fung and N. Wang “Vertically Aligned ZnO/Amorphous-Si Core-shell Heterojunction Nanowire Arrays”, Nanotechnology 21 (2010) 475703

49)  T. L. Wong, C. Cheng, W. Li, K. K. Fung and N. Wang, “Nano Structural Transformation and Formation of Heterojunctions from Si Nanowires” ACS Nano 10 (2010) 5559

50)  C. Cheng, M. Lei, L. Feng, T. L. Wong, K. M. Ho, K. K. Fung, M. M. T. Loy, D. Yu, and N. Wang, “High-Quality ZnO Nanowire Arrays Directly Fabricated from Photoresists”, ACS Nano 3 (2009) 53

51)  C. D. Gu, C. Cheng, H. Huang, T. L. Wang, N. Wang, and T. Y. Zhang, “Growth and Photocatalytic Activity of Dendrite-like ZnO@Ag Heterostructure Nanocrystals”, Crystal Growth & Design 9 (2009) 3278

52)  L Feng, C. Cheng, B. D. Yao, N. Wang and M. M. T. Loy “Photoluminescence Study of Single ZnO Nanostructures: Size Effect”, Appl. Phys. Lett. 95 (2009) 053113 Top 6 most downloaded paper in Aug. 2009

53)  L. Feng, C. Cheng, M. Lei, N. Wang, and M. M. T. Loy “Spatially Resolved Photoluminescence Study of Single ZnO Tetrapods”, Nanotechnology 19 (2008) 405702

54)  C. Cheng, R. Xin, Y. Leng, D. Yu, and N. Wang, “Chemical Stability of ZnO Nanostructures in Simulated Physiological Environments and Its Application in Determining Polar Directions”, Inorg. Chem. 47 (2008) 7868

55)  C. Cheng, and N. Wang, “Synthesis, Characterization and Growth Mechanism of ZnO/TiO2 Nanohybrid Arrays”, Mater. Res. Soc. Symp. Proc. 1035 (2008) 1035-L02-11

56)  C. Cheng, K. F. Yu, Y. Cai, K. K. Fung, and N. Wang, “Site-Specific Deposition of Titanium Oxide on Zinc Oxide Nanorods” J. Phys. Chem. C 111 (2007)16712

57)  J. Ling, C. Cheng*, J. Zhang, Y. Huang, F. J. Shi, X. X. Ding, C. Tang, and S. R. Qi, “Controllable Growth of Zinc Oxide Micro- and Nanocrystals by Oxidization of Zn-Cu Alloy”, J. Solid State Chem. 178 (2005) 819 Corresponding author

58)  J. Lin, Y. Huang, X.X. Ding, C. Cheng, C. Tang, and S. R. Qi, “Metal Oxide Coating on Carbon Nanotubes by a Methanol-Thermal Method”, J. Nanosci. Nanotech. 5 (2005) 932

59)  C. Cheng, X.X. Ding, F.J. Shi, Y. Cheng, X.T. Huang, S. R. Qi, C. Tang “Preparation of Aluminum Borate Nanowires” J. Crystal Growth. 263 (2004) 600

60)  C. Cheng, F. J Shi, Y. Cheng, X. X Ding, C.C. Tang, S. R Qi “The Effects of Samarium-Doping Catalyst on the Growth of Carbon Nanotubes” Huazhong Shifan Daxue Xuebao (Ziran Kexue Ban) 38 (2004) 36

61)  F.J Shi, C. Cheng, X.X Ding, S.R Qi, C. Tang “Catalytic Synthesis of Bamboo-Shaped Carbon Nanotubes by Ferrocene” Huazhong Shifan Daxue Xuebao (Ziran Kexue Ban) 38 (2004) 40

62)  Z. W. Gan, X. X. Ding, Z. X. Huang, X. T. Huang, C. Cheng, C. Tang, and S. R. Qi “Growth of Boron Nitride Nanotube Film in Situ” Appl. Phys. A 81 (2004) 527

63)  X. X. Ding, Z. X. Huang, X.T. Huang, Z.W. Gan, C. Cheng, C. Tang, and S.R. Qi “Synthesis of Gallium Borate Nanowires” J. Crystal Growth. 263 (2004) 504

64)  C. Cheng, C. Tang , X.X. Ding , X.T. Huang, Z.X. Huang, S.R. Qi, Long Hu, and Y.X. Li “Catalytic Synthesis of Aluminum Borate Nanowires” Chem. Phys. Lett. 373 (2003) 626 


联系我们


Chun CHENG(程春) Ph.D

Associate Professor
Department of Materials Science and Engineering
South University of Science and Technology of China
Address: Scientific research building II, Room 423;Tangchang Rd.,Xili,Nanshan District(南山区西丽塘长路),Shenzhen,Guandong,P.R. China,518055
Tel (Office): +86 0755-88018568
Email: chengc@sustc.edu.cn 



鸣谢



国家自然基金委

国家科技部


国家教育部

广东省科技厅

深圳市科创委

南方科技大学校长基金

南方科技大学副校长基金


招聘信息



实验室长期招聘博士后和助理研究员,我们也接收来自国内外大学的优秀访问学者和访问博士生,欢迎随时与我们联系洽谈合作事宜(纳米、二维材料、太阳能方向)。

一、课题组研究方向:

(a) 二氧化钒微纳米线制备、器件及应用研究 (制动器、纳米热输运、智能窗等);(b) 二维材料与器件;(c) 钙钛矿太阳能电池。

二、博士后招聘要求(长期有效,名额不限):

(a) 博士毕业或即将毕业,年龄小于35周岁;(b) 物理、化学及材料相关专业;(c) 对科研工作有兴趣、有热情,做事态度积极主动。

三、博士后岗位待遇:

1. 年薪近30万元,其中深圳市财政以生活补贴支持12万元/年 (免税)(包括住房补贴、五险一金、过节费、餐补等福利待遇);2. 出站留深工作,符合深圳市后备级或孔雀计划人才条件的可获160-200万元的住房补贴; 3. 出站留深进行科研工作的具有海外留学经历的,可申请获得300-500万的孔雀计划科研启动经费。

四、应聘流程:

1. 申请人将详细的申请材料发送到程春教授邮箱:chengc@sustc.edu.cn ,邮件标题请注明“姓名+博士(硕士)毕业学校+应聘职位” 申请材料需包括:(1) 详细的个人简历;(2) 代表论文原文;2. 通过简历初步遴选者,将在一周内获得电话面试或视频面试通知;3. 通过电话面试者将被邀请到南科大现场面试,通过现场面试者将依照相关程序办理博士后入站手续。


Postdoctoral Positions Available in AMRAL lab (2D materials, VO2 Nanomaterials, Solar Cells)

The Advanced Materials- Micro/nano Structure Regulation and Application Lab (AMRAL) releases several postdoctoral positions in the fields of 2D materials, VO2Nanomaterials and Pervorskite Solar Cells. We invite applications from creative, passionate, and motivated postdoctoral researchers join our creative, productive, social, and friendly research group!

 Please visit http://www.sustc.edu.cn/en/mse_04/f/Cheng_Chun for more information on the current research in the AMRAL lab.

 The candidate will be offered an attractive annual salary (about 300,000.0 RMB before tax).

 Please send your CV (should include research accomplishments and interests, as well as list of publications) to chengc@sustc.edu.cn. The positions will remain open until filled.


  • 1

    A Universal Stamping Method of Graphene Transfer for Conducting Flexible and Transparent Polymers 2018

    Bananakere Nanjegowda Chandrashekar, Yingchun Wu, Nianduo Cai, Yunlong Li, Ziyu Huang, Ankanahalli Shankaregowda Smitha, Wang Weijun, Run Shi, Jingwei Wang, Shiyuan Liu, Fei Wang*, Chun Cheng* Carbon, submitted

  • 2

    Effect of sintering temperature on structural, electrical, and ferroelectric properties of lanthanum and sodium co-substituted barium titanate ceramics 2018

    Mahmoud S. Alkathya, Abdo Hezamb, K.S.D. Manojaa, Jingwei Wangc, Chun Chengc, K. Byrappab, K.C. James Rajua, Journal of Alloys and Compounds, 2018, accepted.

  • 3

    Strain Enhanced Lithium Storage and Diffusion on the Monolayer Graphyne as the Anode Material in the Li-ion Battery 2018

    PCCP, submitted

     

  • 4

    Fluctuation-induced tunneling conduction in iodine-doped bilayer graphene 2018

    Zefei Wu, Xiaolong Chen, Mingwei Zhang, Lin Wang, Yu Han, Shuigang Xu, Tianyi Han, Jiangxiazi Lin, Liheng An, Jingwei Wang, Xiangbin Cai, Run Shi, Chun Cheng, and Ning Wang, JAP, submitted

  • 5

    Efficiency and Stability Enhancement of Perovskite Solar Cells by Introducing CsPbI3 Quantum Dots as Interface Engineering Layer 2018

    NPG Asia Materials, Accepted.

  • 6

    PEDOT:PSS/Graphene Quantum Dots Films with Enhanced Thermoelectric Properties via Strong Interfacial Interaction and Phase Separation 2018

    Fei-Peng Du, Nan-Nan Cao, Yun-Fei Zhang, Ping Fu, Yan-Guang Wu, Zhi-Dong Lin, Run Shi, Abbas AmimiChun Cheng*  Scientific Reports, 2018,8,6441.

  • 7

    A new Effective Approach to Prevent the Degradation of Black Phosphorus: the Sc Transition Metal Doping 2018

    Wang, Xinbo ; Tang, Chunmei*; Zhu, Weihua; Zhou, Xiaofeng; Zhou, Qionghua; Cheng, Chun*, JPCC Accepted.

  • 8

    Thermally Sensitive N-Type Thermoelectric Aniline Oligomer-Block-Polyethylene Glycol-Block-Aniline Oligomer ABA Triblock Copolymers 2018

    Xiang-Le Cheng, Yun-Fei Zhang, Yan-Guang Wu ,Ping Fu, Zhi-Dong Lin, Fei-Peng Du ,Chun ChengMacromol. Chem.  Phys. 2018, 1700635

     

  • 9

    Electronically Semitransparent ZnO Nanorods with Superior Electron Transport Ability for DSSCs and Solar Photocatalysis 2018

    Hezam, Abdo; K, Namratha; Drmosh, Q; Chandrashekar, Bananakere Nanjegowda ; Kudur Jayaprakash, Gururaj; Cheng, Chun; Byrappa, Kullaiah, Ceramics International 2018 44 (6), 7202-7208


  • 10

    Crystallization Manipulation and Morphology Evolution for Highly Efficient Perovskite Solar Cell Fabrication via Hydration Water Induced Intermediate Phase Formation under Heat Assisted Spin-Coating 2018

    Xianyong Zhou, Yong Zhang,  Weiguang Kong,  Manman Hu,  Luozheng Zhang,  Chang Liu,  Xiangnan Li,  Chunyue Pan,*  Guipeng Yu,  Chun Cheng*  and  Baomin Xu*

  • 11

    Proton Conducting Polyoxometalate/polypyrrole Films and Their Humidity Sensing Performance 2018

    Jun Miao, Yulong Chen, Yiwen Li, Jiaji Cheng, Qingyin Wu, Kar Wei Ng, Xin Cheng, Rui Chen, Chun Cheng*, Zikang Tang* ACS Appl. Nano Mater. 2018,1, 2, 564-571

  • 12

    Fabricating High-Efficient Blade-Coated Perovskite Solar Cells under Ambient Condition Using Lead Acetate Trihydrate 2018

    Weiguang Kong, Guoliang Wang, Jiming Zheng, Hong Chen, Yunlong Li, Manman Hu, Xianyong Zhou, Chang Liu, Bananakere Nanjegowda Chandrashekar, Abbas Amini, Jianbo Wang, Baomin Xu,* Chun Cheng* Sol. RRL 2018, 1700214 Selected as Front cover page and the No.1 most read paper on March, 2018

  • 13

    Twin Defect Derived Growth of Atomically Thin MoS2 Dendrites 2018

    Wang, Jingwei; Cai, Xiangbin; Shi, Run; Wu, Zefei; Wang, Weijun; Long, Gen; Tang, Yongjian; Cai, Nianduo; Ouyang, Wenkai; Geng, Pai; Chandrashekar, Bananakere Nanjegowda ; Amini, Abbas; Wang, Ning*; Cheng, Chun*, ACS Nano2018, 12 (1), pp 635–643. Top 20 Most Read Articles in December, 2017 at ACS Nano (>2000).

  • 14

    Superhigh strength of geopolymer with the addition of polyphosphate 2018

    Yan-Guang Wu, Sui-Sui Xie, Yun-Fei Zhang,,Fei-Peng Du, Chun Cheng Ceramics International, 44 (2018) 2578-2583

  • 15

    Gate-tunable strong-weak localization transition in few-layer black phosphorus. 2018

    Gen Long, Shuigang Xu , Xiangbin Cai , Zefei Wu , Tianyi Han, Jiangxiazi Lin , Chun Cheng , Yuan Cai , Xinran Wang , Ning Wang* , Nanotechnology,   29 (2018) 035204

  • 16

    A new operational method to solve Abel’s and generalized Abel’s integral equations 2018

    K. Sadri, A. Amini*, C. Cheng, Applied Mathematics and Computation, 317 (2018) 49–67

  • 17

    Krishnaveni Effect of Gamma irradiation on Electrical Properties of CdTe/CdS Solar Cells 2018

    Santosh Kumar,  M Vinay Kumar,  Manjunatha Pattabi,  Asokan K,  Xavier,  Nini,  Martin , B. N. Chandrashekare , Cheng Chun  &  S Materials Today: Proceedings 00 (2017)

  • 18

    Ambipolar quantum transport in few-layer black phosphorus 2018

    Gen Long, Denis Maryenko, Sergio Pezzini, Shuigang Xu, Zefei Wu, Tianyi Han, Jiangxiazi Lin, Chun Cheng, Yuan Cai, Uli Zeitler, Ning Wang, Phys. Rev. B, 96 (2017) 155448 1-7

  • 19

    Axially modulation of metal-insulator phase transition of VO2 nanowires by doping engineering for optically readable micro/nano thermometers 2018

    Run Shi, Jingwei Wang, Xiangbin Cai, Linfei Zhang, Pengcheng Chen, Shiyuan Liu, Liang Zhang, Wenkai Ouyang, Ning Wang and Chun Cheng* J. Phys. Chem. C, 121 (2017), 24877-24885

  • 20

    Influence of High Dose Gamma Irradiation on Electrical Characteristics of Si Photo Detectors 2018

    M. Vinay Kumar, Santosh Kumar, Chun Cheng, K. Asokan, Ashish Kumar,V. Shobha, S. P. Karanth, and S. Krishnaveni, ECS Journal of Solid State Science and Technology, 6 (10) Q132-135 (2017)

  • 21

    A Laser Irradiation Synthesis of Strongly-coupled VOx-reduced Graphene Oxide Composites as Enhanced Performance Supercapacitor Electrodes, 2018

    L. Zhang#, Jun Tang#, S. Liu, O. Peng, R. Shi, B. N. Chandrashekar, Y. Li, X. Li, X.Li, B.Xu*, C. Cheng* Materials Today Energy,  5 (2017) 222-229

  • 22

    Phosphorous doped graphitic-C3N4 hierarchical architecture for hydrogen production from water under visible light 2018

    L. Zhang#, Y. Zhang#, R. Shi, S. Bao, J. Wang, A. Amini, B. N. Chandrashekar, C. Cheng*, Materials Today Energy, 5 (2017) 91-98

  • 23

    High-Performance Multifunctional V2O5@Ni3S2 H 2018

    Xiongwei Zhong+, , Linfei Zhang+, , Jianwei Chai, Jingchen Xu, Ming Yang, Jun Tang, Weiguang Kong, Nianduo Cai, Shijie Wang, Chun Cheng*, Baomin Xu*,, and Hui Pan*, J. Mater. Chem. A, 5, 2017, 17954-17962.

  • 24

    Low Temperature-processed SnO2-Cl for Efficient PbS quantum-dot solar cells via defect passivation 2018

    Jahangeer Khan,  Xiaokun Yang, Keke Qiao, Hui Deng, Jian Zhang , Zhiyong Liu , Waqar Ahmad, Jihong Zhang , Dengbing Li , Huan Liu , Haisheng Song*, Chun Cheng*, Jiang Tang, ,  J. Mater. Chem. A, 5, 2017, 17240-17247

  • 25

    Heterogeneous Growth Mechanism of Zinc Oxide Flower-Like Structures and their Morphology Effect on Optical and Photocatalytic Properties 2018

    A. Hezam, K. Namratha, Q.A. Drmosh, B. N. Chandrashekar, Z. Yemani , C. Cheng and  K. Byrappa,* CrystEngComm19, (2017) 3299-3312

  • 26

    Efficient and Stable Perovskite Solar Cells Prepared in Ambient Air Based on Surface-Modified Perovskite 2018

    Liu, Chang; Ding, Wenhui; Zhou, Xianyong; Gao, Jishu; Cheng, Chun; Zhao, Xing-Zhong; Xu, Baomin*, J. Phys. Chem. C, 121(2017), 65466553 2017-03-09

  • 27

    A new numerical method for delay and advanced integro-differential equations 2018

    Sadri, A. Amini*, C. Cheng, Numerical Algorithms, (2017) 1-32

  • 28

    Low cost numerical solution for three-dimensional linear and nonlinear integral equations via three-dimensional Jacobi polynomials 2018

    K. Sadri, A. Amini*, C. Cheng, Journal of Computational and Applied Mathematics, 319(2017), 493–513

  • 29

    Simultaneous Determination of Epinephrine, Ascorbic acid and Folic acid using TX-100 Immobilized Modified Carbon Paste Electrode: A Cyclic Voltammetric Study 2018

    B.N. Chandrashekar, B.E. Kumara Swamy*, K.J. Gururaj, and C. Cheng, , Journal of Molecular Liquids, 231 (2017) 379385

  • 30

    Improving the Performance of PbS Quantum Dot Solar Cells by Optimizing ZnO Window Layer 2018

    X. Yang,  L.Hu, H. Deng, K. Qiao, C. Hu, Z. Liu, S. Yuan, J. Khan, D. Li, J. Tang,  C. Cheng *, Haisheng Song*, Nano-Micro Letters, 9 (2017) 24, pp 1-10

  • 31

    Shape-Dependent Defect Structures in Monolayer MoS2 Crystals Grown by Chemical Vapor Deposition 2018

    Guozhu Zhang, Jingwei Wang, Zefei Wu, Run Shi, Wenkai Ouyang, Abbas Amini, B. N. Chandrashekar, Ning Wang , and Chun Cheng*, ACS Appl. Mater. Interfaces, 2017, 9 (1), pp 763–770

  • 32

    Universal low-temperature Ohmic contacts for quantum transport in transition metal dichalcogenides 2018

    S. Xu, Z. Wu, H. Lu, Y. Han, G. Long, X. Chen, T. Han, W. Ye, Y. WU, J. Lin, J. Shen, Y. Cai, Y. He, F. Zhang, R. Lortz, C. Cheng and N. Wang *, 2D Mater.3 (2016)021007. 2016-04-22

  • 33

    Carbon-coated V2O5/SnO2-x Nanocomposites as Multifunctional Materials for High Performance Lithium-ion Batteries and Visible-light Photocatalysts 2018

    L. Zhang, M. Yang, Z. Wu, A.  Amini, W. Cao, J. Feng, X. FanR.  Shi, C. Huang, Z. Lu, N. Wang and C. Cheng*, Scientific Reports, 6 (2016) 33597 2016-09-28

  • 34

    Negative compressibility in graphene-terminated black phosphorus heterostructures 2018

    Y. Wu, X. Chen, Z. Wu, S. Xu, T. Han, J. Lin, B. Skinner, Y. Cai, Y. He, C. Cheng, and Ning Wang*, Phys. Rev. B 93 (2016) 035455 2016-01-29

  • 35

    Y-shaped ZnO Nanobelts Driven from Twinned Dislocations 2018

    Y. Shi, S. H. Bao, R. Shi, C. Z. Huang, A. Amini, Z. F. Wu, L. F. Zhang, N. Wang and C. Cheng*, 6 (2016) 22494 2016-03-01 Scientific Reports

     

  • 36

    Three Dimensional Sculpturing of Vertical Nanowire Arrays by Conventional Photolithography 2018

    R. Shi, C. Huang, L. Zhang, A. Amini, K. Liu, Y. Shi, S. Bao, N. Wang, C. Cheng*, Scientific Reports, 6 (2016)18886 2016-01-05

  • 37

    A fast transfer-free synthesis of high-quality monolayer graphene on insulating substrates by a simple rapid thermal treatment 2018

    Z. Wu, Y. Guo, Y. Guo, R. Huang, S. Xu, J. Song, H. Lu, Z. Lin, Y. Han, H. Li, T. Han, J. Lin, Y. Wu, G. Long, Y. Cai, C. Cheng, D. Su, J. Robertson, and N. Wang, Nanoscale, 8 2016 2594-2600 2015-10-09

  • 38

    Hierarchical ZnO Nanostructures with Blooming Flowers Driven by Screw Dislocations 2018

    C. Huang, R. Shi, A. Amini, Z. Wu, S. Xu, L. Zhang, W. Cao, J. Feng,    H. Song, Y. Shi, N. Wang and C. Cheng*, Scientific Reports, 5 (2015) 8266

  • 39

    VO2 nanowire-based microthermometer for quantitative evaluation of electron beam heating 2018

    H. Guo, M. I. Khan, C. Cheng, W. Fan, C. Dames, J. Wu and A. M. Minor*, Nature Communication 5 2015 4986

  • 40

    Directly metering light absorption and heat transfer in single nanowires using metal-insulator transition 2018

    C. Cheng, D. Fu, K. Liu, H. Guo, S. Xu, S. Ryu, O. Ho, J. Zhou, W. Fan, W. Bao, M. Salmeron, N. Wang, C. P. Grigoropoulos, and J. Wu* , Adv. Opt. Mater., 32015336Highlighted by MaterialsViews

  • 41

    Nanoscale variation in energy dissipation in austenitic shape memory alloys in ultimate loading cycles 2018

    A. Amini*, C. Yang, C. Cheng, M. Naebe and Y. Xiang, Journal of Intelligent Material Systems and Structures, (2014) 1-7

  • 42

    Self-assembly and horizontal orientation growth of VO2 nanowires 2018

    C. Cheng*, H. Guo, A. Amini, K. Liu, D. Fu, J. Zou, H. Song, Scientific Reports, 4 (2014) 5456

  • 43

    Enhanced photocatalytic performance of TiO2-ZnO hybrid nanostructures 2018

    C. Cheng*, A. Amini, C. Zhu, Z. Xu, H. Song, N. Wang*, Scientific Reports, 4 20144181ESI highly cited paper

  • 44

    Phase Transformation Evolution in NiTi Shape Memory Alloy under Cyclic Nano indentation Loadings at Dissimilar Rates 2018

    A. Amini*, C. Cheng*, Q. Kan, M. Naebe, H. Song, Scientific Reports, 3 (2013) 3412 (Co-corresponding author)

  • 45

    Powerful, Multifunctional Torsional Micro Muscles Activated by Phase Transition 2018

    K. Liu, C. Cheng, J. Suh, R. Tang-Kong, D.Fu, S. Lee, J. Zhou, L. O. Chua, J. Wu, Adv. Mater., (2014), 26, 1746.

    (News release “A Micro-Muscular Break Through” in BERKELEY LAB News Center, also featured in DOE and NSF websites)

  • 46

    Dynamically tracking the strain across the metal-insulator transition in VO2 measured using electromechanical resonators 2018

    P. Parikh, C. Chakraborty, A. Sebastian, S. Sengupta, C. Cheng, J. Wu, MM Deshmukh, Nano Lett. 13 (2013) 4685

  • 47

    Nature of hardness evolution in nanocrystalline NiTi shape memory alloys during solid-state phase transition 2018

    A. Amini*, C. Cheng*, Scientific Reports 3 (2013) 2476 (Co-corresponding author)

  • 48

    Temperature variations at nano-scale level in phase transformed nanocrystalline NiTi shape memory alloys adjacent to graphene layers 2018

    A. Amini, C. Cheng, M. Naebe, JS Church, N. Hameed, A. Asgari, F. Will, Nanoscale, 5, (2013), 6479

  • 49

    Combinational rate effects on the performance of nano-grained pseudoelastic Nitinols 2018

    A Amini, C Cheng, A Asgari, Mater. Lett. 105 (2013) 98

  • 50

    Axially engineered metal-insulator phase transition by graded doping vo2 nanowires 2018

    S Lee, C. Cheng, H. Guo, K. Hippalgaonkar, K. Wang, J. Suh, K. Liu, J. Wu, J. Am. Chem. Soc. 135 (2013) 4850

  • 52

    Ni-NTA-coated nanowire materials for protein enrichment and the application in a medical device used for blood glucose​ degradation 2018

    Q. Hu#, C. Cheng#, W. Qin, Y.Q. Liu, S. Xu, B.Z. Tang, N. Wang, N. Li*, NANO, 8, (2013) 1350029 (co-first author)

  • 53

    Effect of graphene layers on the thermomechanical behaviour of a NiTi shape memory alloy during the nanoscale phase transition 2018

    A Amini, N Hameed, JS Church, C Cheng, A Asgari, F Will, Scripta Materialia, 68, (2013) 420

  • 54

    Performance Limits of Microactuation with Vanadium Dioxide as a Solid Engine 2018

    K. X. Wang, C. Cheng, E. Cardona, J. Guan, K. Liu, J. Wu, Acs Nano, 7 (2013) 2266

  • 55

    Comprehensive Study of Metal-Insulator Transition in Pulsed Laser Deposited Epitaxial VO2 Thin Films 2018

    D. Fu*, K. Liu*, T. Tao, K. Lo, C. Cheng, B. Liu, R. Zhang, H. Bechtel, J. Wu, A Systematic, J. Appl. Phys. 113, (2013) 043707

  • 56

    Correlation between the morphology and performance enhancement of zno hierarchical flower photoanodes in quasi-solid dye-sensitized solar cells 2018

    C. Zhu, Y. Shi, C. Cheng, L. Wang, K. K. Fung, and N. Wang, J. Nanomater. (2012) 212653

  • 57

    Giant-Amplitude, High-Work Density Microactuators with Phase Transition Activated Nanolayer Bimorphs 2018

    K. Liu, C. Cheng, Z. Cheng, K. Wang, R. Ramesh, J. Wu, Nano Lett.12, (2012) 6302 (News release “Flexing fingers for micro-robotics” in BERKELEY LAB News Center, also featured in DOE and NSF websites)

     

  • 58

    Dense Electron System from Gate-Controlled Surface Metal-Insulator Transition 2018

    K. Liu, D. Fu, J. Cao, J. Suh, K. X. Wang, C. Cheng, D. F. Ogletree, H. Guo, S. Sengupta, A.Khan, C. W. Yeung, S. Salahuddin, M. M. Deshmukh, J. Wu, Nano Lett., 12, (2012) 6272

  • 59

    Directed Assembly of Nano-scale Phase Variants in Highly Strained BiFeO3 Thin Films 2018

    J. Zhou, M. Trassin, Qi. He, N. Tamura, M. Kunz, C. Cheng, J. Zhang, W. Liang, J. Seidel, C. Hsin, and J. Wu, J. Appl. Phys. 112 (2012) 064102.

  • 60

    Optimizing Nanosheet-based ZnO Hierarchical Structure through Ultrasonic-assisted Precipitation for Remarkable Photovoltaic Enhancement in Quasi-solid Dye-sensitized Solar Cells 2018

    Y. Shi, C. Zhu, L. Wang, W. Li, C. Cheng, K. M. Ho, K. K. Fung, and N. Wang  J. Mater. Chem. 22 (2012)13097

  • 61

    Ultra-long, free-standing, single-crystalline vanadium dioxide micro/nanowires grown by simple thermal evaporation 2018

    C. Cheng, K. Liu, B. Liu, J. Suh and J. Wu  Appl. Phys. Lett. 100 (2012) 103111

  • 62

    Heat Transfer across the Interface between Nanoscale Solids and Gas 2018

    C. Cheng#, W. Fan#, J. Cao, S.G. Ryu, J. Ji, G. P. Grigoropoulos and J. Wu*  ACS Nano 5 (2011) 10102

  • 63

    A self-entanglement mechanism for continuous pulling of carbon nanotube yarns 2018

    C. Zhu, C. Cheng, Y.H. He, Lin W, T.L. Wong, K.K. Fung and N. Wang Carbon 49 (2011) 4996

  • 64

    Carbon-assisted nucleation and vertical growth of high-quality ZnO nanowire arrays 2018

    C. Cheng, T.L. Wong, W. Le, C. Zhu, S.G. Xu, L. Wang, K. K. Fung, and N. Wang*  AIP Advances 1 (2011) 032104 Top 2 Most downloaded paper in Sept. 2011 and highlighted

  • 65

    ZnO Hierarchical Structures for Efficient Quasi-solid Dye-sensitized Solar Cells 2018

    C. Cheng#, Y. Shi#, C. Zhu, W. Li, L. Wang, K. K. Fung and N. Wang*, Phys. Chem. Chem. Phys. 13 (2011)10631

  • 66

    Fabrication and structure characterization of Te butterfly nanostructures 2018

    T. L. Wong, G. W. She, C. Cheng, W. Li, W. S. Shi, X. H. Zhang, and N. Wang, , J. Nanosci. Nanotech. 11 (2011) 11037

  • 67

    Zn2TiO4/ZnO Axial Nanowire Heterostructures by Unilateral Diffusion 2018

    C. Cheng, W. Li, T. L. Wang, K. M. Ho, and N. Wang*,  J. Phys. Chem. C 115 (2011) 78

  • 68

    Controllable Fabrication of Three-Dimensional Radial ZnO Nanowire/Silicon Microrod Hybrid Architectures 2018

    H. S. Song, W. J. Zhang, C. Cheng, Y. B. Tang,L. B. Luo, X. Chen,C. Y. Luan, X. M. Meng, J. A. Zapien, N. Wang, C. S. Lee, I. Bello, and S. T. Lee  Crystal Growth & Design 11, (2011) 147

  • 69

    Tailoring the Luminescence Emission of ZnO Nanostructures by Hydrothermal Post-Treatment in Water 2018

    B. D. Yao , L. Feng , C. Cheng , M. M. T. Loyand N. Wang, Appl. Phys. Lett. 96, (2010) 223105

  • 70

    Vertically Aligned ZnO/Amorphous-Si Core-shell Heterojunction Nanowire Arrays 2018

    C. Cheng, T. L. Wang, L. Feng, W. Li, K. M. Ho, M. M. T. Loy, K. K. Fung and N. Wang*, Nanotechnology 21 (2010) 475703

  • 71

    Nano Structural Transformation and Formation of Heterojunctions from Si Nanowires 2018

    T. L. Wong, C. Cheng, W. Li, K. K. Fung and N. Wang, ACS Nano 10 (2010) 5559


  • 72

    High-Quality ZnO Nanowire Arrays Directly Fabricated from Photoresists 2018

    C. Cheng, M. Lei, L. Feng, T. L. Wong, K. M. Ho, K. K. Fung, M. M. T. Loy, D. Yu, and N. Wang*, ACS Nano 3 (2009) 53

  • 73

    Growth and Photocatalytic Activity of Dendrite-like ZnO@Ag Heterostructure Nanocrystals 2018

    C. D. Gu, C. Cheng, H. Huang, T. L. Wang, N. Wang, and T. Y. Zhang*, , Crystal Growth & Design 9 (2009) 3278

  • 74

    Photoluminescence Study of Single ZnO Nanostructures: Size Effect 2018

    1. L Feng, C. Cheng, B. D. Yao, N. Wang and M. M. T. Loy*, Appl. Phys. Lett. 95 (2009) 053113 Top 6 most downloaded paper in Aug. 2009


  • 75

    Spatially Resolved Photoluminescence Study of Single ZnO Tetrapods 2018

    L. Feng, C. Cheng, M. Lei, N. Wang, and M. M. T. Loy*, Nanotechnology 19 (2008) 405702

  • 76

    Chemical Stability of ZnO Nanostructures in Simulated Physiological Environments and Its Application in Determining Polar Directions 2018

    C. Cheng, R. Xin, Y. Leng, D. Yu, and N. Wang*, , Inorg. Chem. 47 (2008) 7868

  • 77

    Synthesis, Characterization and Growth Mechanism of ZnO/TiO2 Nanohybrid Arrays 2018

    C. Cheng, and N. Wang, Mater. Res. Soc. Symp. Proc. 1035 (2008) 1035-L02-11

  • 78

    Site-Specific Deposition of Titanium Oxide on Zinc Oxide Nanorods 2018

    C. Cheng, K. F. Yu, Y. Cai, K. K. Fung, and N. Wang, J. Phys. Chem. C 111 (2007)16712

  • 79

    Controllable Growth of Zinc Oxide Micro- and Nanocrystals by Oxidization of Zn-Cu Alloy 2018

    J. Ling, C. Cheng*, J. Zhang, Y. Huang, F. J. Shi, X. X. Ding, C. Tang, and S. R. Qi, , J. Solid State Chem. 178 (2005) 819 Corresponding author

  • 80

    Metal Oxide Coating on Carbon Nanotubes by a Methanol-Thermal Method 2018

    J. Lin, Y. Huang, X.X. Ding, C. Cheng, C. Tang, and S. R. Qi, , J. Nanosci. Nanotech. 5 (2005) 932

  • 81

    Preparation of Aluminum Borate Nanowires 2018

    C. Cheng, X.X. Ding, F.J. Shi, Y. Cheng, X.T. Huang, S. R. Qi, C. Tang  J. Crystal Growth. 263 (2004) 600

  • 82

    The Effects of Samarium-Doping Catalyst on the Growth of Carbon Nanotubes 2018

    C. Cheng, F. J Shi, Y. Cheng, X. X Ding, C.C. Tang, S. R Qi  Huazhong Shifan Daxue Xuebao (Ziran Kexue Ban) 38 (2004) 36

  • 83

    Catalytic Synthesis of Bamboo-Shaped Carbon Nanotubes by Ferrocene 2018

    F.J Shi, C. Cheng, X.X Ding, S.R Qi, C. Tang  Huazhong Shifan Daxue Xuebao (Ziran Kexue Ban) 38 (2004) 40

  • 84

    Growth of Boron Nitride Nanotube Film in Situ 2018

    Z. W. Gan, X. X. Ding, Z. X. Huang, X. T. Huang, C. Cheng, C. Tang, and S. R. Qi  Appl. Phys. A 81 (2004) 527

  • 85

    Synthesis of Gallium Borate Nanowires 2018

    X. X. Ding, Z. X. Huang, X.T. Huang, Z.W. Gan, C. Cheng, C. Tang, and S.R. Qi  J. Crystal Growth. 263 (2004) 504

  • 86

    Catalytic Synthesis of Aluminum Borate Nanowires 2018

    C. Cheng, C. Tang , X.X. Ding , X.T. Huang, Z.X. Huang, S.R. Qi, Long Hu, and Y.X. Li  Chem. Phys. Lett. 373 (2003) 626

  • 87

    Efficiency and stability enhancement of perovskite solar cells by introducing CsPbI3 quantum dots as an interface engineering layer 2018

    Y.F Zhou, Q. Liu, Y. Tang, and C. Cheng “Erraticity in the Random-Cascading a Model” Chin. Phys. Lett. 18(2001) 1179

  • 88

    - 2018

    Chang Liu, Manman Hu, Xianyong Zhou, Jianchang Wu, Luozheng Zhang, Weiguang Kong, Xiangnan Li, Xingzhong Zhao, Songyuan Dai, Baomin Xu* & Chun Cheng* , NPG Asia Materials (2018) accepted and featured article

     

博士后

实验员

张林飞

研究方向:二维纳米材料在能源存储及电子器件中的应用研究,相关研究成果分别发表在Angew. Chem. Int. Ed., Small, Nanoscale, Scientific Reports, J. Phys. Chem. C, Dalton Trans.等国际知名期刊上。在Angew. Chem. Int. Ed.上发表的文章被选为“Back Cover”“Hot Paper”;发表在Small上的文章被Materials Views (中国,http://www.materialsviewschina.com) 报道。参加工作以后申请获批国自然青年基金一项,深圳市基础研究两项。


研究方向:二维纳米材料在能源存储及电子器件中的应用研究,相关研究成果分别发表在Angew. Chem. Int. Ed., Small, Nanoscale, Scientific Reports, J. Phys. Chem. C, Dalton Trans.等国际知名期刊上。在Angew. Chem. Int. Ed.上发表的文章被选为“Back Cover”“Hot Paper”;发表在Small上的文章被Materials Views (中国,http://www.materialsviewschina.com) 报道。参加工作以后申请获批国自然青年基金一项,深圳市基础研究两项。


研究助理

石润

2016年7月本科毕业于南方科技大学材料科学与工程系获学士学位,2014年起从事一维氧化钒功能纳米材料的制备、表征与器件制备工作,研究兴趣还包含金属氧化物纳米结构的形貌调控与智能材料的相关应用。 


2016年7月本科毕业于南方科技大学材料科学与工程系获学士学位,2014年起从事一维氧化钒功能纳米材料的制备、表征与器件制备工作,研究兴趣还包含金属氧化物纳米结构的形貌调控与智能材料的相关应用。 


王经纬

PhD candidate,

joined Prof. Cheng’s group since October 2015 and mainly focus on the growth of 1D and 2D nano-materials as well as device fabrication. 


PhD candidate,

joined Prof. Cheng’s group since October 2015 and mainly focus on the growth of 1D and 2D nano-materials as well as device fabrication. 


本科生

鲍书涵

Undergraduate, senior

Work on the growth 2D materials and functional vanadium oxide materials.

Undergraduate, senior

Work on the growth 2D materials and functional vanadium oxide materials.

姜峥岩

材料系本科生

材料系本科生

孔德俊

材料系本科生

材料系本科生

彭鸥文

undergraduate, study the fabrication, characterization and application of nanomaterials in the laboratory at the SUSTECH

undergraduate, study the fabrication, characterization and application of nanomaterials in the laboratory at the SUSTECH

张翊

主要从事非金属光催化材料和二维材料的制备与应用研究

主要从事非金属光催化材料和二维材料的制备与应用研究

A
2016-08-04 20:52:00

研究兴趣


课题组主要研究方向包括智能材料、能源材料、二维无机柔性电子材料与器件等:1)基于二氧化钒微纳材料相变的智能材料与结构:智能材料的制备、响应特性调节及特色应用如近场功率计、微型制动器、红外探测器、智能玻璃等; 2)能源材料:先进微纳功能材料在光分解水制氢、储能材料(锂离子电池及超级电容器)以及智能窗户节能材料等方面的应用;新型钙钛矿太阳能电池的研发与产业化; 3)二维材料:无机二维材料的规模制备(大面积单晶、层数可控、异质结构、低温柔性衬底直接生长等)、连续绿色转移技术及器件应用。近5年发表SCI论文50余篇, 系列工作被美国劳伦斯国家实验室LBNL NEWs Center高度评价,并被多家著名的网络科技媒体如Science Daily, PHYS.ORG, Materials Views, Materials360online,材料人,X-More等广泛报道。

研究工作



    一、纳米VO2结构可控制备、相变特性调控及新型器件研发:

‍‍    1. 高密度自立生长超长VO2纳米线‍‍

        与块材和薄膜相比,VO2微纳米线具有可控稳定的相变,是研究单畴相变物理的理想系统,在器件应用上具有更多的优势。采用低熔点蒸发源,结合氧化钒纳米线贴在衬底抛光表面生长的特点,在粗糙表面生长出高密度、超长(长达5mm)且自立纳米线(结果发表于Appl. Phys. Lett. 100(2012), 103111)。这个工作将VO2纳米线从衬底表面“解放”出来,方便纳米线转移与器件制作,为其在忆阻器、莫特晶体管、光学开关、应力和气体传感器等应用研究打下了基础。随后,我们进一步实现在较廉价的石英衬底上取向生长VO2微纳米线(Scientific Reports, 2014, in press)。

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     2. VO2纳米线梯度掺杂及应用拓展

        掺杂是调节相变温度,拓宽VO2应用的重要手段。我们首次实现纳米线轴向钨的梯度掺杂(发表于J. Am. Chem. Soc. 135 (2013) 4850) 。研究表明这种梯度掺杂纳米线具有随温度沿着轴向移动的高对比度相变畴界,我们基于此开发了光学可读取的纳米温度计,可实现对单个细胞的实时监测。掺杂纳米线高达15%/K的热阻系数以及较低的电阻率,可作为极好的远红外热辐射传感材料;梯度的结构相变也使得这种材料具有高幅度和宽温度响应的双晶片微致动器的应用前景。

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    3. 基于单畴相变的微纳尺度热输运测量平台

       VO2的单畴相变畴界能被光学读取,精确指示温度。基于此,我们首次利用氧化钒单晶微纳悬臂作为纳米温度计/功率计研究了纳米尺度下固体与气体界面的热传输。确定了热传输系数随气压和固体尺寸的规律,并指出气固界面的传热对考虑纳米器件的热耗散过程的重要性(结果发表在ACS Nano 5 (2011) 10102)。我们开发了基于VO2单畴相变的微纳尺度热输运测量平台,实现在单个纳米器件水平上定量测量纳米线的光吸收、热导率等基本的参数(Adv.Optic. Mat. (2014) accepted)。对于纳米尺度下新热物理学和能源的转化与热管理研究方面,此工作做出很大贡献。

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    4. 高性能VO2@Cr双晶片微纳致动器

       基于VO2@Cr的双晶片结构薄膜,利用先进微制造技术,我们设计并批量化制作了梳状、花状以及弹簧结构的微致动器阵列(结果发表于Nano Lett. 12 (2012) 6302 和 Adv.Mater. 26 (2014)1746 )。这些微致动器展现了极高的工作性能(0.63 J/cm3,6kHZ),良好的工作环境适应性(空气和液体中),激发源多样性(光、热、电等)以及多功能性(固体热机、机械手、接触感应器、忆阻器等)(结果发表于ACSNano, 7 (2013) 2266 和 Nano Lett. 13 (2013) 4685)。我们对VO2致动器的系统研究为开发新微机电与能量转化微器件做出了重要贡献。

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    二、电子透射显微术对低维纳米结构分析和无机纳米材料(特别是ZnO)的可控生长,性能调控以及器件应用等的研究

    1. 原位透射电镜研究纳米结构的转化与异质结的形成机制

       通过自制在高分辨透射电子显微镜中用于原位反应的加热台。Si纳米线和Ni反应形成单晶的NiSi2纳米线以及SiC包覆的硅化镍异质壳核结构的过程被实时观测研究。结果表明SiO2层在形成上述结构的过程中起着关键性的作用。对NiSi2形成机制的理解使得这种材料非常可能发展成为一种理想的用于Si纳米线器件电学连接材料(结果发表在ACS Nano 2010 4 (10), 5559-5564)。

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    2. 低维ZnO结构可控生长及光电性质调控

       a) 碳基薄膜辅助合成ZnO纳米线阵列:利用光刻胶及碳膜在硅片上实现低成本、大面积(晶片尺寸级别)、图案化合成高质量且竖直生长的ZnO纳米线阵列,与现有CMOS工艺兼容,为大规模器件应用铺平道路(结果发表于ACSNano 3 (2009) 53和AIP Advances 1 (2011) 032104)

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       b) 纳米ZnO材料光学及电学特性的调控:1.利用近场光学显微镜和透射电子显微镜研究并提出了纳米ZnO材料本征发光“尺寸效应”的“表面效应”机制及非本征发光的“结构缺陷”来源(结果发表在Nanotech. 19 (2008)405702和Appl. Phys. Lett. 95 (2009), 053113) 2.发展对纳米ZnO中的本征缺陷进行调节的后处理方法,改善材料的光学和电学性质(结果发表在Appl. Phys. Lett. 96,(2010) 223105和Solid State Communications, 160, (2013)41)

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    3. 纳米ZnO结构调控及增强性能应用

       a) 发展直接沉淀法以及定位生长技术,设计合成系列ZnO多级结构和TiO2/ZnO、Ag/ ZnO、Si/ZnO等功能异质结构,展示了结构调控对纳米材料在光催化,染料敏化电池等方面性能的增强(结果分别发表在J. Phys. Chem. C 115 (2007), 78;CrystalDesign & Growth 9 (2009), 3278;Crystal Design &Growth, 11 (2011), 147;Nanotech. 2011 21 (47), 475703; Phys. Chem. Chem. Phys. 13 (2011), 10631;J.Mater. Chem. 22 (2012) 13097;J. Nanomater. (2012)212653)。     

 

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      b) 我们的研究首次展示了纳米ZnO生物兼容性及纳米晶体极性方向确定的新方法(结果发表于Inorg.Chem. 47 (2008) 7868)。利用纳米线阵列以及多级结构比表面积大,易分离的特点,我们将表面进行功能化修饰的纳米结构应用于蛋白质的分离与提纯,与当前商业产品相比,其表现更加优异的纯化效率(300%)和活性(一年以上);选择吸附特定的蛋白酶,这些纳米结构用于血糖降解,为纳米材料在糖尿病治疗的医疗器械开发奠定了基础(结果发表于NANO,8, (2013) 1350029)

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科研项目



    程春副教授入职以来主持(11项,省部级以上7项)及主研主研国家,省部级,市校级各类基金项目十余项,项目金额总额超过6500万元,其中课题组经费近1800万元


1.国家自然科学基金青年项目 (2014-2017)

    基于VO2纳米线单畴相变的近场光吸收测量与界面热输运研究(主持)

2.多级g-C3N4/Carbon复合物的合成及可见光光催化研究(第二负责人, 指导老师)

3.国家重点研发计划纳米科技重点专项(2017-2020)

    钙钛矿电池关键材料设计制备及高性能柔性器件 (主研)

4.教育部留学回国人员启动基金项目(2014-2017)

    原位研究二氧化钒微纳米线生长及其超顺排阵列制备(主持)

5.广东省科技发展专项资金(前沿与关键技术创新方向)项目(2016-2017)粤港创新领域 用于柔性电子的二维材料制备技术与器件研究(主持)

6.广东省自然科学基金“杰出青年”项目(2016-2019),工材组第一名

    宏量制备VO2纳米线及其在热致微驱动器上的应用研究(主持)

7.广东省教育厅“优秀青年教师”项目(2016-2018)(主持)

8.广东省特支计划项目“科技创新青年拔尖人才” (2016-2019)(主持)

9.广东省2015年度高等教育教学改革项目(2015-2017)

    开放式研究性教学模式的研究与实践 (主持)

10.深圳市孔雀计划启动项目(2014-2016)

    可控合成二氧化钒微纳米线及其应用研究(主持)

11.深圳市孔雀团队项目 (2015-2019)

    新型钙钛矿太阳能电池研发与产业化 (主研)

12.深圳市基础研究项目 (2016-2018)

    超薄钒氧化物二维材料的制备及其在柔性储能器件上的研究 (主持)

13.深圳市科技研发项目(2015-2017)

    深圳市纳米压印技术重点实验室(主研)

14. 南方科技大学校长基金项目(2015-2017)

    纳米线热导的应变效应研究(主持)

15. 南方科技大学网络课程建设项目(2016-2017)

    “晶体学”(主持)

16.作为科研导师指导大学生科研项目10项,其中国家级大创1项,省级大创1项,广东省大学生科技创新重点项目 3项,大学生创新创业训练计划立项项目 5项。