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孙靖宇

来源:竞彩足球计算器 发布者:李梦溪发布时间:2019-03-28浏览次数:6884




靖宇,竞彩足球比分特聘教授,博士生导师。九三学社社员,四青人才,江苏省双创人才,《科学通报》编委。2008年本科毕业于浙江大学竺可桢学院,2013年于英国牛津大学获博士学位。2013-2015年、2015-2017年分别在北京大学和英国剑桥大学开展研究工作。2017年2月加盟苏州大学,2018年受聘北京石墨烯研究院兼职研究员。主要从事石墨烯的化学气相沉积可控制备、烯碳基可穿戴能源材料及打印器件研究。发展了低维碳材料直接生长的Direct-CVD技术,研究成果被 Nature Mater., Phys.org , 央广网,科学网等亮点报道。近年来在国内外期刊上共发表论文90余篇,其中通讯作者/第一作者论文逾50篇包括 Chem. Soc. Rev., Nature Commun., J. Am. Chem. Soc., Adv. Mater., Energy Environ. Sci., Adv. Energy Mater., Nano Lett., ACS Nano 等,总引用近3700次。加盟苏州大学近三年以来,以通讯作者(含共同)发表科研论文31篇(苏大均为第一完成单位)。


电子邮箱:sunjy86@suda.edu.cn


个人简历:

2018-至今兼职研究员、PI,北京石墨烯研究院

2017-至今特聘教授、博士生导师、PI,竞彩足球比分

2015-2017 博士后,英国剑桥大学 剑桥石墨烯中心,合作导师:Prof. Andrea C. Ferrari

2013-2015 博士后,北京大学 纳米化学研究中心,合作导师:刘忠范院士

  

2008-2013 博士,英国牛津大学 材料系,导师:Prof. Martin R. Castell, Prof. Nicole Grobert

2004-2008 学士,浙江大学 竺可桢学院混合班,导师:杨德仁院士

  

研究方向:

1、石墨烯材料的可控直接制备

2、烯碳基储能材料及其打印器件

3、可穿戴多场耦合一体化系统

  

个人荣誉及人才项目:

2019江苏省双创人才

2019江苏省双创团队 核心成员

2018江苏省“六大人才高峰”

2017年 入选国家四青人才

2016年 剑桥大学Wolfson College特别资助

2015年 北京大学优秀博士后奖

2011年 牛津大学Varsity Award

2008年 中国教育部-牛津大学共建奖学金

  

其他:

曾为浙江大学、牛津大学乒乓球校队成员,现为苏州大学教职工乒乓球队成员。

个人赛:获得2018年全国首届“教授杯”乒乓球赛男子青年组单打冠军/双打冠军、2019年全国第二届“教授杯”乒乓球赛男子青年组单打冠军、2015年全英华人乒乓球公开赛单打冠军、2017年苏州大学阳光体育节乒乓球高校邀请赛单打冠军、2019年中国联通乒乓球挑战赛苏州赛区亚军(男子31-45岁年龄组)、2018年苏州市“海信·日立杯”乒乓球单打公开赛亚军、2018年苏州市“汇邻乒乓大赛”公开组单打季军。

团体赛:获得2017-2019年在苏高校教职工乒乓球赛团体冠军 (苏州大学)、2019年苏州工业园区“慧湖杯”乒乓球邀请赛团体冠军 (苏州大学)、2019年苏州爱动俱乐部四周年邀请赛团体冠军、2015年北京大学“北大杯”团体冠军 (化学与分子工程学院)。

  


常年招收有志于从事可穿戴能源材料及打印器件、石墨烯可控制备研究的博士后、博士研究生和硕士研究生

  

  

代表性论文 (*通讯作者;1共同一作)

Upon arriving at SUDA:

2019

(1)慈海娜,孙靖宇*, 基于化学气相沉积技术的粉体石墨烯的制备及能源领域应用, 科学通报 2019, 64, 3327.

(2)Z.N. Tian, X.L. Tong, G. Sheng, Y.L. Shao*, L.H. Yu, V. Tung, J.Y. Sun*, R.B. Kaner*, Z.F. Liu, Printable magnesium ion quasi-solid-state asymmetric supercapacitors for flexible solar-charging integrated units, Nature Commun. 2019, 10, 4913.

(3)Y.Z. Song, W.L. Cai, L. Kong, J.S. Cai, Q. Zhang*, J.Y. Sun*, Rationalizing electrocatalysis of Li–S chemistry by mediator design: progress and prospects, Adv. Energy Mater. 2019, in press, DOI: 10.1002/aenm.201901075.

(4)L.H. Yu, Z.D. Fan, Y.L. Shao*, Z.N. Tian, J.Y. Sun*, Z.F. Liu, Versatile N-doped MXene ink for printed electrochemical energy storage application, Adv. Energy Mater. 2019, 9, 1901839.

(5)Y.Y. Yi, Z.T. Sun, C. Li, Z.N. Tian, C. Lu, Y.L. Shao, J. Li*, J.Y. Sun*, Z.F. Liu, Designing 3D biomorphic nitrogen-doped MoSe2/graphene composites toward high-performance potassium-ion capacitors, Adv. Funct. Mater. 2019, in press, DOI: 10.1002/adfm.201903878.

(6)M.L. Wang, Y.Z. Song, Z.T. Sun, Y.L. Shao, C.H. Wei, Z. Xia, Z.N. Tian, Z.F. Liu*, J.Y. Sun*, Conductive and catalytic VTe2@MgO heterostructure as effective polysulfide promotor for lithium?sulfur batteries, ACS Nano 2019, 13, 13235.

(7)N. Wei, L.H. Yu, Z.T. Sun, Y.Z. Song, M.L. Wang, Z.N. Tian, Y. Xia, Y.Y. Li*, L. Zhao, Q.C. Li, M.H. Rümmeli, JY Sun*, ZF Liu*, Scalable salt-templated synthesis of nitrogen-doped graphene nanosheets toward printable energy storage, ACS Nano 2019, 13, 7517. | Highlighted by Phys.org

(8)N. Wei, J.S. Cai, R.C. Wang, M.L. Wang, W. Lv*, H.N. Ci, J.Y. Sun*, Z.F. Liu, Elevated polysulfide regulation by an ultralight all-CVD-built ReS2@N-Doped graphene heterostructure interlayer for lithium–sulfur batteries, Nano Energy 2019, 66, 104190.

(9)C. Li, S. Cong, Z.N. Tian, Y.Z. Song, L.H. Yu, C. Lu, Y.L. Shao, J. Li, G.F. Zou*, M.H. Rümmeli, S.X. Dou, J.Y. Sun*, Z.F. Liu*, Flexible perovskite solar cell-driven photo-rechargeable lithium-ion capacitor for self-powered wearable strain sensors, Nano Energy 2019, 60, 247.

(10)Z. Xia, H. Sun, X. He, Z.T. Sun, C. Lu, J. Li, Y. Peng*, S.X. Dou, J.Y. Sun*, Z.F. Liu, In situ construction of CoSe2@vertical-oriented graphene arrays as self-supporting electrodes for sodium-ion capacitors and electrocatalytic oxygen evolution, Nano Energy 2019, 60, 385.

(11)J.S. Cai, Y.Z. Song, X. Chen, Z.T. Sun, Y.Y. Yi, J.Y. Sun*, Q. Zhang*, MOF-derived conductive carbon nitrides for separator-modified Li–S batteries and flexible supercapacitors, J. Mater. Chem. A 2019, in press, DOI: 10.1039/C9TA11958B.

(12)Y.Z. Song, Z.T. Sun, J.S. Cai, N. Wei, M.L. Wang, Y.L. Shao, Z.F. Liu*, J.Y. Sun*, Accelerated Li–S chemistry at a cooperative interface built in situ, J. Mater. Chem. A 2019, 7, 20750.

(13)N. Wei, Q.C. Li, S. Cong, H.N. Ci, Y.Z. Song, Q.F. Yang, C. Lu, C. Li, G.F. Zou, J.Y. Sun*, Y.F. Zhang*, Z.F. Liu*, Direct synthesis of flexible graphene glass with macroscopic uniformity enabled by copper-foam-assisted PECVD, J. Mater. Chem. A 2019, 7, 4813.

(14)Y.Z. Song, S.Y. Zhao, Y.R. Chen, J.S. Cai, J. Li*, Q.H. Yang*, J.Y. Sun*, Z.F. Liu, Enhanced sulfur redox and polysulfide regulation via porous VN-modified separator for Li?S batteries, ACS Appl. Mater. Interfaces 2019, 11, 5687.

(15)C. Lu, Z.Z. Li, Z. Xia, H.N. Ci, J.S. Cai, Y.Z. Song, L.H. Yu, W.J. Yin, S.X. Dou, J.Y. Sun*, Z.F. Liu*, Confining MOF-derived SnSe nanoplatelets in nitrogen-doped graphene cages via direct CVD for durable sodium ion storage, Nano Res. 2019, 12, 3051.

(16)L.H. Yu, Y.Y. Yi, T. Yao, Y.Z. Song, Y.R. Chen, Q.C. Li, Z. Xia, N. Wei, Z.N. Tian, B.Q. Nie, L. Zhang, Z.F. Liu*, J.Y. Sun*, All VN-graphene architecture derived self-powered wearable sensors for ultrasensitive health monitoring, Nano Res. 2019, 12, 331.

(17)Z.N. Tian, C. Li, J.S. Cai, L. Zhang*, C. Lu, Y.Z. Song, T. Jiang, J.Y. Sun*, S.X. Dou, Solar-driven capacity enhancement of aqueous redox batteries with a vertically oriented tin disulfide array as both the photo-cathode and battery-anode, Chem. Commun. 2019, 55, 1291.

(18)Z.L. Hu, Z.Z. Li, Z. Xia, T. Jiang, G.L. Wang, J.Y. Sun*, P.F. Sun, C.L. Yan*, L. Zhang*, PECVD-derived graphene nanowall/lithium composite anodes towards highly stable lithium metal batteries, Energy Storage Mater. 2019, 22, 29.

(19)L.N. Tie, S.Y. Yang, C.F. Yu*, H. Chen, Y. Liu, S.Y. Dong, J.Y. Sun*, J.H. Sun*, In situ decoration of ZnS nanoparticles with Ti3C2 MXene nanosheets for efficient photocatalytic hydrogen evolution, J. Colloid Interface Sci. 2019, 545, 63. | Front Cover

(20)L.N. Tie, N. Li*, C.F. Yu, Y.M. Liu, S.Y. Yang, H. Chen, S.Y. Dong, J.Y. Sun*, S.X. Dou, J.H. Sun*, Self-supported nonprecious MXene/Ni3S2 electrocatalysts for efficient hydrogen generation in alkaline media, ACS Appl. Energy Mater. 2019, 2, 6931.

(21)L. Lin, J.C. Zhang, H.S. Su, J.Y. Li, L.Z. Sun, S. Lopatin, Y.H. Zhu, K.C. Jia, S.L. Chen, D.R. Rui, J.Y. Sun, R.W. Xue, P. Gao, N. Kang, Y. Han, H.Q. Xu, Z.Q. Tian, B. Ren, H.L. Peng*, Z.F. Liu*. Towards super-clean graphene, Nature Commun. 2019, 10, 1912.

(22)J.S. Cai, J.Y. Huang, S.C. Wang, J. Iocozzia, Z.T. Sun, J.Y. Sun, Y.K. Yang, Y.K. Lai*, Z.Q. Lin*, Crafting mussel-inspired metal nanoparticle-decorated ultrathin graphitic carbon nitride for the degradation of chemical pollutants and production of chemical resources, Adv. Mater. 2019, 31, 1806314.

2018

(23)J.Y. Sun*, C. Lu, Y.Z. Song, Q.Q. Ji, X.J. Song, Q.C. Li, Y.F. Zhang, L. Zhang*, J. Kong, Z.F. Liu*, Recent progress in tailored growth of two-dimensional hexagonal boron nitride via chemical vapour deposition, Chem. Soc. Rev. 2018, 47, 4242.

(24)Y.Z. Song, W. Zhao, L. Kong, L. Zhang*, X.Y. Zhu, Y.L. Shao, F. Ding, Q. Zhang*, J.Y. Sun*, Z.F. Liu, Synchronous immobilization and conversion of polysulfides on a VO2-VN binary host targeting high sulfur load Li–S batteries, Energy Environ. Sci. 2018, 11, 2620.

(25)X.G. Wang, Q.C. Li, L. Zhang*, Z.L. Hu, L.H. Yu, T. Jiang, C. Lu, C.L. Yan, J.Y. Sun*, Z.F. Liu, Caging Nb2O5 nanowires in PECVD-derived graphene capsules toward bendable sodium-ion hybrid supercapacitors, Adv. Mater. 2018, 30, 1800963.

(26)Y.Y. Yi, L.H. Yu, Z.N. Tian, Y.Z. Song, Y.L. Shao, L.J. Gao, J.Y. Sun*, Z.F. Liu*, Biotemplated synthesis of transition metal nitride architectures for flexible printed circuits and wearable energy storages, Adv. Funct. Mater. 2018, 28, 1805510.

(27)X.Y. Zhu, F. Zhang, L. Zhang*, L.Y. Zhang, Y.Z. Song, T. Jiang, S. Sayed, C. Lu, X.G. Wang, J.Y. Sun*, Z.F. Liu*, A highly stretchable cross-linked polyacrylamide hydrogel as an effective binder for silicon and sulfur electrodes toward durable Li-ion storage, Adv. Funct. Mater. 2018, 28, 1705015.

(28)X.Y. Zhu, W. Zhao, Y.Z. Song, Q.C. Li, F. Ding, J.Y. Sun*, L. Zhang*, Z.F. Liu, In situ assembly of 2D conductive VS2 with graphene as a high-sulfur-loading host for lithium?sulfur batteries, Adv. Energy Mater. 2018, 8, 1800201.

(29)Z.L. Hu, S. Sayed, T. Jiang, X.Y. Zhu, C. Lu, G.L. Wang, J.Y. Sun*, A. Rashid, C.L. Yan, L. Zhang*, Z.F. Liu, Self-assembled binary organic granules with multiple lithium uptake mechanisms toward high-energy flexible lithium-ion hybrid supercapacitors, Adv. Energy Mater. 2018, 8, 1802273.

(30)Q.C. Li, Y.Z. Song, R.Z. Xu, L. Zhang*, J. Gao, Z. Xia, Z.N. Tian, N. Wei, M.H. Rümmeli, X.L. Zou, J.Y. Sun*, Z.F. Liu*, Bio-templating growth of nepenthes-like N-doped graphene as a bifunctional polysulfide scavenger for Li?S batteries, ACS Nano 2018, 12, 10240.

(31)Y.Z. Song, W. Zhao, N. Wei, L. Zhang, F. Ding, Z.F. Liu, J.Y. Sun*, In-situ PECVD-enabled graphene-V2O3 hybrid host for lithium–sulfur batteries, Nano Energy 2018, 53, 432.

(32)Y.Z. Song, W. Zhao, X.Y. Zhu, L. Zhang*, Q.C. Li, F. Ding, Z.F. Liu, J.Y. Sun*, Vanadium dioxide-graphene composite with ultrafast anchoring behavior of polysulfides for lithium–sulfur batteries, ACS Appl. Mater. Interfaces 2018, 10, 15733.

(33)C. Lu, Z.Z. Li, L.H. Yu, L. Zhang*, Z. Xia, T. Jiang, W.J. Yin, S.X. Dou, Z.F. Liu, J.Y. Sun*, Nanostructured Bi2S3 encapsulated within three-dimensional N-doped graphene as active and flexible anodes for Na-ion batteries, Nano Res. 2018, 11, 4614.

(34)S.D. Luo, S.Y. Dong, C. Lu, C.F. Yu, Y. Ou, L. Luo, J.Y. Sun*, J.H. Sun*, Rational and green synthesis of novel two-dimensional WS2/MoS2 heterojunction via direct exfoliation in ethanol-water targeting advanced visible-light-responsive photocatalytic performance, J. Colloid Interface Sci. 2018, 513, 389.

(35)K. Chen1, F. Zhang1, J.Y. Sun1, Z.Z. Li, L. Zhang, A. Bachmatiuk, Z.Y. Zou, Z.L. Chen, L.Y. Zhang, M.H. Rümmeli, Z.F. Liu*, Growth of defect-engineered graphene on manganese oxides for Li-ion storage, Energy Storage Mater. 2018, 12, 110.

(36)L. Lin, B. Deng, J.Y. Sun, H.L. Peng*, Z.F. Liu*, Bridging the gap between reality and ideal in chemical vapor deposition growth of graphene, Chem. Rev. 2018, 118, 9281.

(37)Y.L. Shao, M.F. EI-Kady, J.Y. Sun, Y.G. Li, Q.H. Zhang, M.F. Zhu, H.Z. Wang*, B. Dunn*, R.B. Kaner*, Design and mechanisms of asymmetric supercapacitors, Chem. Rev. 2018, 118, 9233.

(38)Y. Qi, B. Deng, X. Guo, S. Chen, J. Gao, T.R. Li, Z.P. Dou, H.N. Ci, J.Y. Sun, Z.L. Chen, R.Y. Wang, L.Z. Cui, X.D. Chen, K. Chen, H.H. Wang, S. Wang, P. Gao, M.H. Rümmeli, H.L. Peng, Y.F. Zhang*, Z.F. Liu*, Switching vertical to horizontal graphene growth using Faraday cage-assisted PECVD approach for high-performance transparent heating device, Adv. Mater. 2018, 30, 1704839.

(39)Q.C. Li, Q.Q. Wu, J. Gao, T.B. Wei, J.Y. Sun, H. Hong, Z.P. Dou, Z.P. Zhang, M.H. Rümmeli, P. Gao, J.C. Yan*, J.X. Wang, J.M. Li, Y.F. Zhang*, Z.F. Liu*, Direct growth of 5 in. uniform hexagonal boron nitride on glass for high-performance deep-ultraviolet light-emitting diodes, Adv. Mater. Interfaces 2018, 5, 1800662.

(40)R.G. Mendes, P.S. Wróbel, A. Bachmatiuk, J.Y. Sun, T. Gemming, Z.F. Liu, M.H. Rümmeli*, Carbon nanostructures as a multi-functional platform for sensing applications, Chemosensors 2018, 6, 60.

From Postdoc and PhD work:

(1)J.Y. Sun, Y.B. Chen, M.K. Priydarshi, T. Gao, X.J. Song, Y.F. Zhang*, Z.F. Liu*, Graphene glass from direct CVD routes: Production and applications, Adv. Mater. 2016, 28, 10333.

(2)Y.B. Chen1, J.Y. Sun1,*, Y.F. Zhang*, Z.F. Liu*, et al. Growing uniform graphene disks and films on molten glass for heating devices and cell culture, Adv. Mater. 2015, 27, 7839 | This paper has been highlighted in Nature Materials | Research Highlights: J. Plummer, Molten bed, Nature Materials 2015, 14, 1186.

(3)J.Y. Sun, T. Gao, X.J. Song, Y.F. Zhao, Y.W. Lin, H.C. Wang, D.L. Ma, Y.B. Chen, W.F. Xiang, J. Wang, Y.F. Zhang*, Z.F. Liu*, Direct growth of high-quality graphene on high-κ dielectric SrTiO3 substrates, J. Am. Chem. Soc. 2014, 136, 6574.

(4)J.Y. Sun, Y.B. Chen, M.K. Priydarshi, Z. Chen, A. Bachmatiuk, Z.Y. Zou, Z.L. Chen, X.J. Song, Y.F. Gao, M.H. Rümmeli, Y.F. Zhang*, Z.F. Liu*, Direct chemical vapor deposition-derived graphene glasses targeting wide ranged applications, Nano Lett. 2015, 15, 5846.

(5)J.Y. Sun, Z.L. Chen, L. Yuan, Y.B. Chen, J. Ning, S. Liu, D.L. Ma, X.J. Song, M. Priydarshi, A. Bachmatiuk, M.H. Rümmeli, T.B. Ma, L.J. Zhi, L.B. Huang, Y.F. Zhang*, Z.F. Liu*, Direct-CVD-fabricated, large-scale graphene glass with high carrier mobility and uniformity for touch panel applications, ACS Nano 2016, 10, 11136.

(6)X.J. Song1, J.Y. Sun1, Y. Qi1, T. Gao, Y.F. Zhang*, Z.F. Liu*, Graphene/h-BN heterostructures: Recent advances in controllable preparation and functional applications, Adv. Energy Mater. 2016, 6, 1600541.

(7)S.Y. Dong, J.L. Feng, Y.K. Li, L.M. Hu, M.L. Liu, Y.F. Wang, Y.Q. Pi, J.Y. Sun*, J.H. Sun*, Shape-controlled synthesis of BiVO4 hierarchical structures with unique natural-sunlight-driven photocatalytic activity, Appl. Catal. B: Environ. 2014, 152-153, 413.

(8)J.Y. Sun, Y.B. Chen, X. Cai, B.J. Ma, Z.L. Chen, M.K. Priydarshi, K. Chen, T. Gao, X.J. Song, Q.Q. Ji, X.F. Guo, D.C. Zou, Y.F. Zhang*, Z.F. Liu*, Direct low-temperature synthesis of graphene on various glasses by plasma-enhanced chemical vapor deposition for versatile, cost-effective electrodes, Nano Res. 2015, 8, 3496.

(9)J.Y. Sun, F. Dillon, C. Wu, J. Jiang, K. Jurkschat, A.A. Koós, A. Crossley, N. Grobert*, M.R. Castell*, Metal-free chemical vapor deposition growth of graphitic tubular structures on engineered perovskite oxide substrates, Carbon 2016, 99, 591.

(10)J.Y. Sun, C. Wu, F. Silly, A.A. Koós, F. Dillon, N. Grobert, M.R. Castell*, Controlled growth of Ni nanocrystals on SrTiO3 and their application in the catalytic synthesis of carbon nanotubes, Chem. Commun. 2013, 49, 3748.

(11)J.Y. Sun, A.A. Koós, F. Dillon, K. Jurkschat, M.R. Castell, N. Grobert*, Synthesis of carbon nanocoil forests on BaSrTiO3 substrates with the aid of a Sn catalyst, Carbon 2013, 60, 5.

(12)J.Y. Sun, Y.F. Zhang*, Z.F. Liu*, Direct chemical vapor deposition growth of graphene on insulating substrates, ChemNanoMat 2016, 2, 9. | Inside Front Cover

(13)Q.Q. Ji1, Y. Zhang1, J.P. Shi1, J.Y. Sun, Y.F. Zhang*, Z.F. Liu*, Morphological engineering of CVD-grown transition metal dichalcogenides for efficient electrochemical hydrogen evolution, Adv. Mater. 2016, 28, 6207.

(14)X.J. Song1, T. Gao1, Y.F. Nie1, J.N. Zhuang, J.Y. Sun, D.L. Ma, J.P. Shi, Y.W. Lin, F. Ding, Y.F. Zhang, Z.F. Liu*, Seed-assisted growth of single-crystalline patterned graphene domains on hexagonal Boron Nitride by chemical vapor deposition, Nano Lett. 2016, 16, 6109.

(15)T. Gao, X.J. Song, H.W. Du, Y.F. Nie, Y.B. Chen, Q.Q. Ji, J.Y. Sun, Y.L. Yang, Y.F. Zhang*, Z.F. Liu*, Temperature-triggered chemical switching growth of in-plane and vertically stacked graphene-boron nitride heterostructures, Nature Commun. 2015, 6, 6835.