中山大学材料科学与工程学院石磊

zilv

石磊，2018年中山大学 “百人计划”入选者，受聘为材料科学与工程学院副教授。研究方向独树一帜：一维原子碳链的制备与性能研究。在nature mater., acs nano, phys. rev. materials, app. phys. lett., nano research, nanoscale, nano lett. phys. rev. b, adv. mater., adv. funct. mater., chem. mater., carbon等期刊发表论文20余篇；其中第一作者发表在nature materials上的论文报道了世界上最长碳链的成功制备和性能研究，受到了审稿人的极高评价和科学界极大的关注（上百家国内外媒体报道，如sciencedaily, c&en, mrs, maildaily，科技日报的头版头条和主编点评，等等），被acs central sciences评为2016年度化学界的五大世界纪录之一，目前是所在碳链领域三篇高被引论文之一。
石磊


个人基本简介:
职称：副教授
学位：自然科学博士
毕业学校：维也纳大学
电子邮件：shilei26@mail.sysu.edu.cn
通讯地址：广东省广州市海珠区新港西路135号中山大学551栋物理楼306




主要经历:
2020.04-至今  中山大学 光电材料与技术国家重点实验室 固定成员
2018.10-至今  中山大学 百人计划 副教授
2015.04-2018.10 维也纳大学 博士后
2011.10-2015.03 维也纳大学 自然科学博士
2008.09-2011.07 上海大学 理学硕士
2004.09-2008.06 河北科技大学 理学学士


学科方向:
本课题组为“一维纳米碳”实验室，英文为“1D NanoCarbons”，隶属于杨国伟教授团队，旨在推动一维纳米碳材料在国内外的发展，着眼于研究碳链、碳纳米管和石墨烯纳米带等的制备、性能与应用研究。欢迎具有物理、材料和化学背景的学生加入课题组一起推动一维纳米碳材料的研究和发展。


35. Isotopic labeling of confined carbyne. Angewandte Chemie-International Edition; https://doi.org/10.1002/anie.202017356 (2021) W. Cui, L. Shi*, K. Cao, K. Ute, T. Saito, P. Ayala, T. Pichler*.
34. Pressure-Tailored Synthesis of Confined Linear Carbon Chains. Journal of Applied Physics (invited) 129, 064302 (2021) X. Li, Y. Zhang, Y. Wu, L. Shi*.
33. Toward Confined Carbyne with Tailored Properties​. Nano Letters 21, 1096–1101 (2021).  L. Shi*, Ryosuke Senga, Kazu Suenaga, Hiromichi Kataura, Takeshi Saito, Alejandro Perez Paz*, Angel Rubio*, P. Ayala, T. Pichler*.
32. 一维新型碳的同素异形体：碳链 (One-Dimensional New Carbon allotrope: Carbon Chain). 化学进展 (Progress in Chemistry​)，已接收; (2021). 靳钧, 林梓恒, 石磊
31. Well-defined sub-nanometer graphene ribbons synthesized inside carbon nanotubes. Carbon 171, 221-229; (2021) Hans Kuzmany#*, Lei Shi#*, Miles Martinati, Sofie Cambré, Wim Wenseleers, Jeno Kürti, János Koltai, Gergo Kukucska, Kecheng Cao, Ute Kaiser, Takeshi Saito, and Thomas Pichler. https://doi.org/10.1016/j.carbon.2020.08.065
30. Raman Scattering Cross Section of Confined Carbyne. Nano Letters; 20, 6750–6755; (2020). Cla Duri Tschannen, Georgy Gordeev, Stephanie Reich, Lei Shi, Thomas Pichler, Martin Frimmer, Lukas Novotny, and Sebastian Heeg*. https://doi.org/10.1021/acs.nanolett.0c02632
29. A review of linear carbon chains. Chinese Chemistry Letters; 31, 1746–1756; (2020) Kan Zhang#, Yifan Zhang#, Lei Shi*. https://authors.elsevier.com/a/1bOZK3Zojpt1TC
28. Band-Gap Engineering and Structure Evolution of Confined Linear Carbon Chains@Double-Walled Carbon Nanotubes under Pressure. Carbon; 159, 266–272; (2020) Xigui Yang#, Chaofan Lv#, Zhen Yao, Mingguang Yao*, Jinxu Qin, Xing Li, Lei Shi*, Mingrun Du, Bingbing Liu, and Chong-Xin Shan*.
27. Oxidation stability of confined linear carbon chains, carbon nanotubes, and graphene nanoribbons as 1D nanocarbons.  Nanoscale; 11, 15253–15258 (2019) Weili Cui, Takeshi Saito, Paola Ayala, Thomas Pichler, Lei Shi*.
26. Towards controllable inner chirality in double-walled carbon nanotubes. Applied Physics Letters; 115, 103102 (2019). Johnny Chimborazo, T. Saito, T. Pichler, L. Shi*, P. Ayala*.
25. Wall- and hybridisation- selective synthesis of nitrogen-doped double-walled carbon nanotubes. Angewandte Chemie International Edition; 30, 10276–10280 (2019) ​Marco Carini, L. Shi, T. W. Chamberlain, M. Liu, G. Valenti, M. Melle-Franco, F. Paolucci, A. Khlobystov,* T. Pichler,* and A. Mateo-Alonso*.
24. Towards a predominant substitutional bonding environment in B-doped single-walled carbon nanotubes. ACS Omega; 4, 1941–1946 (2019); C. Reinoso, C. Berkmann, L. Shi, A. Debut, K. Yanagi, T. Pichler, P. Ayala*.
23. Templated Direct growth of ultra-thin double-walled carbon nanotubes. Nanoscale; 10, 21254–21261(2018); L. Shi*, J. Q. Wei, T. Saito, K. C. Cao, U. Kaiser, P. Ayala, T. Pichler.
22. Very-high boron-doping on single-walled carbon nanotubes from a solid precursor. Carbon; 140, 259–264 (2018); C. Reinoso, L. Shi, O. Domanov, P. Rohringer, T. Pichler, P. Ayala*.
21. Carbon nanotube chirality determines properties of encapsulated linear carbon chains. Nano Letters; 18, 5426–5431 (2018); S. Heeg, L. Shi, L. V. Poulikakos, T. Pichler, and L. Novotny*.  
20. Extracting linear carbon chains to unravel the role of host carbon nanotubes. ACS Nano; 12, 8477–8484 (2018); L. Shi, K. Yanagi, K. C. Cao, U. Kaiser, P. Ayala, T. Pichler*.
19. Raman resonance profile of an individual confined linear carbon chain. Carbon; 139, 581–585 (2018); S. Heeg, L. Shi, L. V. Poulikakos, T. Pichler, and L. Novotny*.
18. Unravel the Active Site in Nitrogen-Doped Double-Walled Carbon Nanotubes for Nitrogen Dioxide Gas Sensor. Physica Status Solidi (a); 1800004 (2018);W. Muangrat, W. Wongwiriyapan, V. Yordsri, T. Chobsilp, S. Inpaeng, C. Issro, O. Domanov, P. Ayala, T. Pichler, and L. Shi*.  
17. Isotope effect on the quantum thermal transport of carbyne. Applied Physics Letters; 112 (9), 091906; (2018); Y. Wu, J. Zhao, G. Sun, L. Shi*.
16. Electronic band gaps of confined linear carbon chains ranging from polyyne to carbyne; Physical Review Materials; 1, 075601; (2017); L. Shi, P. Rohringer, M. Wanko, A. Rubio, S. Wasserroth, S. Reich, S. Cambré, W. Wenseleers, P. Ayala, T. Pichler*.
15. The growth of new extended carbon nanophases from ferrocene inside single-walled carbon nanotubes; physica statussolidi (RRL) - Rapid Research Letters; 8, 1700158 (2017); H. Kuzmany*, L. Shi*, J. Kürti, J. Koltai,A. L. Chuvilin, T. Saito, T. Pichler.
14. 2D-Heterostructures Derived from MoS2-Templated, Cobalt-Containing Conjugated Microporous Polymer Sandwiches for Oxygen Reduction Reaction and Electrochemical Energy Storage; ChemElectroChem; 4, 709–715; (2017) K. Yuan, X. Zhuang, T. Hu, L. Shi, S. Sfaelou, U. Polnick, M. Forster, T. Pichler, T. Riedl, X. L. Feng, Y. W. Chen*, U. Scherf*.
13.Nitrogen-doped Porous Carbon/Graphene Nanosheets Derived from Two-Dimensional Conjugated Microporous Polymer Sandwiches with Promising Capacitive Performance; Materials Chemistry Frontiers; 1, 278–285; (2017)  K. Yuan, T. Hu, Y. Z. Xu, R. Graf, L. Shi, M. Forster, T. Pichler, T. Riedl, Y. W. Chen*, U. Scherf*.
12.Polyyne electronic and vibrational properties under environmental interactions; Physical Review B; 94, 195422; (2016)  M. Wanko, S. Cahangirov, L. Shi, P. Rohringer, Z. J. Lapin, L. Novotny, P. Ayala, T. Pichler, A. Rubio*.
11. Confined linear carbon chains as a route to bulk carbyne; Nature Materials; 15, 634–639; (2016) L. Shi, P. Rohringer,K. Suenaga, Y. Niimi, J. Kotakoski, J. C. Meyer, H. Peterlik, M. Wanko, S. Cahangirov, A. Rubio,Z. J. Lapin, L. Novotny, P. Ayala,T. Pichler*. (ESI: Highly cited paper)
10.Selective enhancement of inner tube photoluminescence in filled double-walled carbon nanotubes; Advanced Functional Materials; 26, 4874–4881; (2016) P. Rohringer, L. Shi, P. Ayala, T. Pichler*.
9. Straightforward generation of pillared, microporous graphene frameworks for use in supercapacitors; Advanced Materials; 27, 6714–6721; (2015) K. Yuan, Y. Xu, J. Uihlein, G. Brunklaus, L. Shi, R. Heiderhoff, M. Que, M. Forster, T. Chassé, T. Pichler, T. Riedl, Y. W. Chen*, U. Scherf*.
8. Nanofibrous and graphene-templated conjugated microporous polymer materials for flexible chemosensors and supercapacitors; Chemistry of Materials; 27, 7403–7411; (2015) K. Yuan, P. Guo-Wang, T. Hu, L. Shi, R. Zeng, M. Forster, T. Pichler, Y. W. Chen*, U. Scherf*.
7.Raman and XPS analyses of pristine and annealed N-doped double-walled carbon nanotubes; Physica Status Solidi (b); 252, 2558–2563; (2015) L. Shi*, M. Sauer, O. Domanov, P. Rohringer, P. Ayala, T. Pichler.
6. The origin of nondispersive Raman lines in the D‐band region for ferrocene@ HiPco SWCNTs transformed at high temperatures; Physica Status Solidi (b); 252, 2530–2535; (2015) H Kuzmany*, L Shi, T Pichler, J Kürti, J Koltai, F Hof, T Saito.
5. Purification, separation and extraction of inner tubes from double-walled carbon nanotubes by tailoring density gradient ultracentrifugation using optical probes; Carbon; 74, 282–290; (2014) P. Rohringer, L. Shi, X. Liu, K. Yanagi, T. Pichler*.
4. Nondispersive Raman lines in the D-band region for ferrocene functionalized carbon nanotubes; Physica Status Solidi (b); 251, 2457–2460; (2014) H. Kuzmany*, L. Shi, T. Pichler, C. Kramberger, A. Chernov, X. Liu.
3.Carbon nanotubes from enhanced direct injection pyrolytic synthesis as templates for long linear carbon chain formation; Physica Status Solidi (b); 250, 2611–2615; (2013) L. Shi*, P. Rohringer, P. Ayala, T. Saito, T. Pichler.
2. Ultra-thin double-walled carbon nanotubes: A novel nanocontainer for preparing atomic wires; Nano Research; 4, 759–766; (2011) L. Shi, L. Sheng*, L. Yu, K. An, Y. Ando, X. Zhao*.
1. Effective and efficient purification of single-wall carbon nanotubes based on hydrogen treatment;  Chemical Physics Letters; 502, 101–106; (2011) L. Sheng, L. Shi, K. An, L. Yu, Y. Ando, X. Zhao*.