张跃钢(ZHANG YUEGANG) 教授
北京市海淀区清华大学
纳米科技楼305室
北京 100084
电话:010-62788965
传真:010-62789851
yuegang.zhang@tsinghua.edu.cn
个人网页:http://info.phys.tsinghua.edu.cn/ygzhang/
个人简历 |
学习经历: |
1981年09月- 1986年07月 |
中国清华大学物理系 |
理学学士 |
1986年08月- 1989年06月 |
中国清华大学物理系 |
固体物理硕士 |
1993年10月- 1996年09月 |
日本东京大学工学院 |
材料科学博士 |
工作经历: |
1989年08月- 1993年09月 |
中国清华大学物理系 |
讲师 |
1996年09月- 2000年01月 |
日本电气基础研究所 |
研究员 |
2000年01月- 2002年07月 |
美国斯坦福大学 |
博士后研究员 |
2002年07月- 2008年08月 |
美国英特尔公司 |
资深研究员,碳纳米管战略研究项目领导人,半导体技术委员会存储器件战略研究分支主席 |
2008年08月- 2012年09月 |
美国伯克利国家实验室 |
终身研究员 |
2014年05月-2017年04月 2012年09月-2017年05月 |
中国清华大学物理系 中国科学院苏州纳米技术与纳米仿生研究所 |
双聘教授 研究员 |
2017年04月- 现在 |
中国清华大学物理系 |
长聘教授 |
主要学术成就 |
张跃钢博士现任清华大学物理系长聘教授;曾任日本NEC基础研究所研究员、美国英特尔公司资深研究员、美国伯克利国家实验室终身研究员,国际半导体技术规划(ITRS)新器件及新材料专家工作组成员,美国基础纳米科学年会自组装结构与器件分支主办委员会成员;现兼任“Scientific Reports”, “Graphene”, “Flexible Electronics”,“功能材料”等学术期刊编委;30多家国际学术杂志论文评审专家,美国布鲁克黑文国家实验室功能纳米材料中心评审委员,美国国家科学基金评审委员,美国Keck基金评审委员,法国-伯克利基金评审委员;美国材料学会,化学学会,电化学学会,及IEEE会员;中国化学会第29届理事会理事。 张跃钢博士先后在国际科学期刊上发表SCI论文180余篇,被引用次数超过21000次(h-index 72);授权专利60余项;为5部专著撰写有关章节;并受邀在40多个国际会议上作过特邀报告。其在国内外从事科学研究工作近20年期间,分别于日本电气基础研究所、斯坦福大学、英特尔公司、美国伯克利国家实验室等从事科学研究工作,先后承担了科研项目十多项,其中担任PI的6项,担任跨国公司研发大项目中小组领导人的3项。 在纳米材料合成与表征、纳米器件制造与测试方面的主要创新成果包括:合成了由纳米管和半导体纳米线组成的纳米同轴电缆结构(发表在Science杂志上);实现了单层碳纳米管与半导体或金属间的纳米异质结构(发表在Science杂志上),这个研究成果对改善碳纳米管器件的电学接触特性起了重要作用;发现了碳纳米管对光照有电学及力学反应,为以后纳米管人工肌肉的研究奠定了基础;用实验证明了用化学气相沉积法制备的碳纳米管半径与金属催化颗粒尺寸的对应关系,对碳纳米管生长机理的研究起了重要作用;运用电场对碳纳米管的排列效应实现了器件制备所要求的化学气相沉积纳米管的原位有序生长;用化学或生物分子对碳纳米管表面进行非共化键改性,非共化键改性不会影响碳纳米管的电学特性,但仍然可以用来在纳米管上安装蛋白质,纳米晶粒等,对化学或生物传感器至关重要,相关论文被应用次数超过2000次;实现了由单个纳米管与金属纳米颗粒组成的具有单电子灵敏度的纳米闪存器件;利用碳纳米管与SiO2组成的“纳米铅笔”核壳结构纳米探针在压电介质上实现了超高密度数字存储器件;首次提出和实现了用光学捕获方法操作与分离碳纳米管。2008年起在美国伯克利国家实验室开展了石墨烯材料的研究, 首创用化学气相沉积法直接在介电基底上形成单层石墨烯薄膜和纳米带场效应器件阵列;观察了单层石墨烯迪拉克点附近的反常噪声特性;研究了石墨烯纳米带器件的量子局限效应,揭示了石墨烯纳米带的宽度对其输运特性的影响。近年来在锂离子电池、锂硫电池、镁硫电池、超级电容器等电化学能量存储方面的研究也取得了突出进展,相关成果发表在Energy & Environmental Science, J. Am. Chem. Soc., Nano Letters等杂志上,同时应邀撰写了数篇专题综述文章;其中基于氮化石墨烯/硫复合电极材料所设计的锂硫电池循环寿命高达2000次,创造了当时该类型电池的最高纪录,其比容量、充放电速率也均居于世界领先水平,相关研究成果及论文被C&EN (美国化学学会会刊) 等科技媒体广泛报道(http://cen.acs.org/articles/91/web/2013/12/Three-Ways-Make-High-Energy.html;http://cen.acs.org/articles/92/web/2014/08/Nitrogen-Doped-Graphene-Boosts-Lifetimes.html)。最近,通过自主研发设计原位扫描/透射电镜电化学芯片,实现了其对电极充电过程的实时观测, 相关成果发表在Advanced Energy Materials和Advanced Materials杂志上,同时被Wiley online等科技媒体广泛报道(http://www.materialsviewschina.com/2015/10/lithium-sulfide-battery-by-in-situ-electron-microscopy-and-cycle-stability-control-made-significant-progress/)。 |
教学 |
1987年02月- 1989年07月:清华大学本科生“固体物理”课程,助教 1990年02月- 1993年05月:清华大学本科生“固体物理”课程,主讲老师,64学时/年 2020年09月- 至今:清华大学研究生“量子物理学与工业革命”课程,主讲老师,64学时/年 2021年09月- 至今:清华大学研究生“高能量密度锂电池:基础与前沿”课程,主讲老师,32学时/年 |
研究领域 |
1. 固态锂硫电池、镁金属电池、固态薄膜电池等新型电化学存储器件; 2. 低维电子器件、离子学神经形态器件; 3. 材料的第一性原理计算、分子动力学模拟; 4. 电化学过程及界面的原位表征技术。 |
奖励、荣誉和学术兼职 |
2012: 江苏省高层次创新创业人才 2012: 金鸡湖双百人才 2008: 英特尔公司器件研究部门奖。 2004/2005/2006:英特尔公司SRC指导项目奖。 1995/1996:日本学术振兴会特别研究员奖学金。 1995:日本金属学会暨国际先进材料与技术研讨会优秀展示奖。 1991:清华大学一二九青年教师奖。 |
论文目录
(1)J. Xiao, X. Zhang, H. Fan, Q. Lin, Z. S. Ng, W. Chen, and Y. Zhang*, “Releasing Free Anions by High Donor Number Cosolvent in Noncorrosive Electrolytes of Commercially Available Magnesium Salts,” ACS Applied Materials & Interfaces, 16, 14, 17673-17682 (2024).
(2))Q. Xu, X. Zhang, X. Yuan, W. Zhang, Y. Li, Y. Zhang, and J. Liu*, “A High-Capacity and High-Voltage Aqueous Zn-Polymer Battery with Self-Charging Function,” Advanced Energy Materials, 14, 8, 2303475 (2024).
(3))H. Liu, W. Jiang, W. Chen, Q. Lin, S. Ren, Y. Su, R. Tong, and Y. Zhang*, “Dendrite growth and inhibition in all-solid-state lithium metal batteries: in situ optical observation,” Joumal of Materials Chemistry A, 12, 6, 3575-3579 (2024)
(4)Y. Luo, Z. Fang, Z. Hong, S. Duan, H. Liu, H. Wu, Q. Li, Y. Zhang, S. Fan, W. Duan, and J. Wang*, “Influences of chemical reactions on polysulfide reduction reaction process on promotor surface in Li-S batteries,” Nano Research, 17, 4, 2712-2718 (2023).
(5)H. Zhang, Z. Bi, Z. Zhai, H. Gao, Y. Liu, M. Jin, M. Ye, X. Li, H. Liu, Y. Zhang, X. Li, H. Tan*, Y. Xu*, L. Yang*, “Revealing Unusual Bandgap Shifts with Temperature and Bandgap Renormalization Effect in Phase-Stabilized Metal Halide Perovskite Thin Films,” Advanced Functional Materials, 34, 9, 2302214 (2023).
(6)X. Lei, J. Wang, Y. Su, S. Guo, G. Li, P. Ji, X. Wang, L. Gu, C. Ge, Y. Zhang, and D. Su*, “Thermal-Induced Structure Evolution at the Interface between Cathode and Solid-State Electrolyte,” Small Structures, 5, 3, 2300342 (2023).
(7)X. Lei, Y. Wang*, J. Wang, Y. Su, P. Ji, X. Liu, S. Guo, X. Wang, Q. Hu, L. Gu, Y. Zhang, R. Yang, G. Zhou*, D. Su*, “Si-Based High-Entropy Anode for Lithium-Ion Batteries,” Small Methods, 8, 1, 2300754 (2023).
(8) X. Li, Y. Wei*, Z. Wang, Y. Kong, Y. Su, G. Lu, Z. Mei, Y. Su, G. Zhang, J. Xiao, L. Liang, J. Li, Q. Li, J. Zhang, S. Fan, and Y. Zhang*, “One-dimensional semimetal contacts to two-dimensional semiconductors,” Nature Communications, 14, 1, 111 (2023).
(9)Y. Luo, Z. Fang, S. Duan, H. Wu, H. Liu, Y. Zhao, K. Wang, Q. Li, S. Fan, Z. Zheng, W. Duan, Y. Zhang, and J. Wang*, “Direct Monitoring of Li2S2 Evolution and Its Influence on the Reversible Capacities of Lithium-Sulfur Batteries,” Angewandte Chemie-international Edition, 62, 11, e202215802 (2023).
(10)L. Ji, X. Wang, Y. Jia, X. Qin, Y. Sui, H. Yan, Z. Niu, J. Liu*, and Y. Zhang, “Oxygen and nitrogen tailoring carbon fiber aerogel with platinum electrocatalysis interfaced lithium/sulfur (Li/S) batteries,” Chinese Chemical Letters, 34, 1, 107123 (2023).
(11)X. Li, Y. Wei*, G. Lu, Z. Mei, G. Zhang, L. Liang, Q. Li, S. Fan, and Y. Zhang*, “Gate-tunable contact-induced Fermi-level shift in semimetal,” Proceedings of the National Academy of Sciences of the United States of America, 119, 17, e2119016119 (2023).
(12)G. Lu, Y. Wei*, X. Li, R. Peng, G. Zhang, Z. Mei, L. Liang, K. Liu, Q. Li, S. Fan, and Y. Zhang*, “Reconfigurable Carbon Nanotube Barristor,” Advanced Functional Materials, 32, 11, 2107475 (2022).
(13)Y. Zhao, X. Zhang, J. Xiao, H. Fan, J. Zhang, H. Liu, Y. Liu, H. Yuan, S. Fan, and Y. Zhang*, “Effect of Mg Cation Diffusion Coefficient on Mg Dendrite Formation,” ACS Applied Materials & Interfaces, 14, 5, 6499-6506 (2022).
(14)G. Xu, Q. Wang, Y. Su, M. Liu, Q. Li, and Y. Zhang*, “Revealing Electrochemical Sodiation Mechanism of Orthogonal-Nb2O5 Nanosheets by In Situ Transmission Electron Microscopy,” Acta Physico-chimica Sinica, 38, 8, 2009073 (2022).
(15)J. Xiao, X. Zhang, H. Fan, Y. Zhao, Y. Su, H. Liu, X. Li, Y. Su, H. Yuan, T. Pan, Q. Lin, L. Pan, and Y. Zhang*, “Stable Solid Electrolyte Interphase In Situ Formed on Magnesium-Metal Anode by using a Perfluorinated Alkoxide-Based All-Magnesium Salt Electrolyte,” Advanced Materials, 34, 30, 2203783 (2022).
(16)J. Xiao, X. Zhang, H. Fan, Q. Lin, L. Pan, H. Liu, Y. Su, X. Li, Y. Su, S. Ren, Y. Lin, and Y. Zhang*, “Cosolvent-Assisted Formation of Charged Ion-Solvent Clusters and Solid Electrolyte Interphase for High-Performance Magnesium Metal Batteries,” Advanced Energy Materials, 12, 47, 2202602 (2022).
(17)J. Wang*, H. Hu, S. Duan, Q. Xiao, J. Zhang, H. Liu, Q. Kang, L. Jia, J. Yang, W. Xu, H. Fei, S. Cheng, L. Li, M. Liu*, H. Lin, and Y. Zhang*, “Construction of Moisture-Stable Lithium Diffusion-Controlling Layer toward High Performance Dendrite-Free Lithium Anode,” Advanced Functional Materials, 32, 12, 2110468 (2022).
(18)S. Tang, G. Lu, Y. Su, G. Wang, X. Li, G. Zhang, Y. Wei*, and Y. Zhang*, “Raman Mapping of Lithiation Process on Graphene,” Acta Physico-chimica Sinica, 38, 3, 2001007 (2022).
(19)H. Liu, J. Zhang, Y. Liu, Y. Wei, S. Ren, L. Pan, Y. Su, J. Xiao, H. Fan, Y. Lin, Y. Su, and Y. Zhang*, “A flexible artificial solid-electrolyte interlayer supported by compactness-tailored carbon nanotube network for dendrite-free lithium metal anode,” Journal of Energy Chemistry, 69, 421-427 (2022).
(20)X. Li, Q. Liu, X. Wang, J. Liu, M. Cheng, J. Hu, T. Wei, W. Li*, Y. Ling, B. Chen, Z. Pan, W. Ma, B. Liu*, Z. Wu, J. Liu, and Y. Zhang*, “A facile in situ Mg surface chemistry strategy for conditioning-free Mg [AlCl4]2 electrolytes,” Electrochimica Acta, 414, 140213 (2022).
(21)Z. Fang, Z. Hong, Y. Luo, Y. Liu, H. Wu, H. Tian, F. Zhao, Y. Zhang, Q. Li, S. Fan, and J. Wang*, “Systematic study and effective improvement of voltammetry for accurate electrochemical window measurement of solid electrolytes,” Electrochimica Acta, 414, 140210 (2022).
(22)H. Fan, X. Zhang, Y. Zhao, J. Xiao, H. Yuan, G. Wang, Y. Lin, J. Zhang, L. Pan, T. Pan, Y. Liu, and Y. Zhang*, “Tailoring Mg2+ Solvation Structure in a Facile All-Inorganic [MgxLiyCl2x+y ·nTHF] Complex Electrolyte for High Rate and Long Cycle-Life Mg Battery,” Energy & Environmental Materials, 6, 2, e12327 (2022).
(23)J. Wang*, J. Zhang, S. Duan, L. Jia, Q. Xiao, H. Liu, H. Hu, S. Cheng, Z. Zhang, L. Li, W. Duan, Y. Zhang*, and H. Lin*, “Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode,” Nano Letters, 22, 19, 8008–8017 (2022).
(24)J. Wang, H. Liu, H. Wu, Q. Li, Y. Zhang, S. Fan, and J. Wang*, “Self-standing carbon nanotube aerogels with amorphous carbon coating as stable host for lithium anodes,” Carbon, 177, 181-188 (2021).
(25)Y. Tan, G. Lu, J. Zheng, F. Zhou, M. Chen, T. Ma, L. Lu, Y. Song, Y. Guan, J. Wang, Z. Liang*, W. Xu, Y. Zhang*, X. Tao*, and H. Yao*, “Lithium Fluoride in Electrolyte for Stable and Safe Lithium-Metal Batteries,” Advanced Materials, 33, 42, 2102134 (2021).
(26)Y. Liu, H. Liu, Y. Lin, Y. Zhao, H. Yuan, Y. Su, J. Zhang, S. Ren, H. Fan, and Y. Zhang*, “Mechanistic Investigation of Polymer-Based All-Solid-State Lithium/Sulfur Battery,” Advanced Functional Materials, 31, 41, 2104863 (2021).
(27)W. Li*, X. Li, H. Fan, J. Xiao, Q. Liu, M. Cheng, J. Hu, T. Wei, Z. Wu, Y. Ling, B. Liu, and Y. Zhang*, “Progress of Non-Nucleophilic Electrolytes for Magnesium/Sulfur Battery,” Acta Chimica Sinica, 79, 5, 628-641 (2021).
(28)G. Lu, Y. Wei, X. Li, G. Zhang, G. Wang, L. Liang, Q. Li, S. Fan, Y.Zhang*, “Reconfigurable Tunneling Transistors Heterostructured by an Individual Carbon Nanotube and MoS2,” Nano Letters, 21, 16, 6843-6850 (2021).
(29)J. Zhang, Q. Lin, Z. Wang, H. Liu, X. Li and Y. Zhang*. “Identifying Water Oxidation Mechanisms at Pure and Titanium-Doped Hematite-Based Photoanodes with Spectroelectrochemistry,” Small Methods, 5, 12, 2100976 (2021).
(30)L. Ji, Y. Jia, X. Wang, L. Duan, W. Li*, J. Liu*, Y. Zhang*, “Strong adsorption, catalysis and lithiophilic modulation of carbon nitride for lithium/sulfur battery,” Nanotechnology, 32, 19, 192002 (2021).
(31)W. Ma, W. Li*, M. Li, Q. Mao, Z. Pan, J. Hu, X. Li, M. Zhu*, Y. Zhang*, “Unzipped Carbon Nanotube/Graphene Hybrid Fiber with Less "Dead Volume" for Ultrahigh Volumetric Energy Density Supercapacitors,” Advanced Functional Materials, 31, 19, 2100195 (2021).
(32)L. Jia, J. Wang, S. Ren, G. Ren, X. Jin, L. Kao, X. Feng, F. Yang, Q. Wang, L. Pan, Q. Li, Y.-s. Liu, Y. Wu, G. Liu, J. Feng, S. Fa[1]n, Y. Ye*, J. Guo*, and Y. Zhang*, “Unraveling Shuttle Effect and Suppression Strategy in Lithium/Sulfur Cells by In Situ/Operando X-ray Absorption Spectroscopic Characterization,” Energy & Environmental Materials, 4, 2, 222-228 (2020).
(33) W. Ma, W. Li, M. Li, Q. Mao, Z. Pan, M. Zhu*, and Y. Zhang*, “Scalable microgel spinning of a three-dimensional porous graphene fiber for high-performance flexible supercapacitors,” Journal of Materials Chemistry A, 8, 47, 25355-25362 (2020).
(34)J. Wang, J. Yang, Q. Xiao, J. Zhang, T. Li, L. Jia, Z. Wang, S. Cheng, L. Li, M. Liu, H. Liu, (35)H. Lin*, and Y. Zhang*, “In Situ Self-Assembly of Ordered Organic/Inorganic Dual-Layered Interphase for Achieving Long-Life Dendrite-Free Li Metal Anodes in LiFSI-Based Electrolyte,” Advanced Functional Materials, 31, 7, 200743 (2020).
(36)J. Zhang, Y. Su, and Y. Zhang*, “Recent advances in research on anodes for safe and efficient lithium-metal batteries,” Nanoscale, 12, 29, 15528-15559 (2020).
J. Wang, L. Jia, H. Lin, and Y. Zhang*, “Single-Atomic Catalysts Embedded on Nanocarbon Supports for High Energy Density Lithium-Sulfur Batteries,” Chemsuschem, 13, 13, 3404-3411 (2020).
(37)H. Fan, Z. Zheng, L. Zhao, W. Li, J. Wang, M. Dai, Y. Zhao, J. Xiao, G. Wang, X. Ding, H. Xiao, J. Li, Y. Wu*, and Y. Zhang*, “Extending Cycle Life of Mg/S Battery by Activation of Mg Anode/Electrolyte Interface through an LiCl-Assisted MgCl2 Solubilization Mechanism,” Advanced Functional Materials, 30, 9, 1909370 (2020).
(38)H. Fan, Y. Zhao, J. Xiao, J. Zhang, M. Wang, and Y. Zhang*, “A non-nucleophilic gel polymer magnesium electrolyte compatible with sulfur cathode,” Nano Research, 13, 10, 2749-2754 (2020).
(39)M. Dai, J. Wang, L. Li, Q. Wang, M. Liu*, and Y. Zhang*, “High-performance Oxygen Evolution Catalyst Enabled by Interfacial Effect between CeO2 and FeNi Metal-organic Framework,” Acta Chimica Sinica, 78, 4, 355-362 (2020).
(40)L. Ji, X. Wang, Y. Jia, Q. Hu, L. Duan, Z. Geng, Z. Niu, W. Li*, J. Liu*, Y. Zhang*, and S. Feng, “Flexible Electrocatalytic Nanofiber Membrane Reactor for Lithium/Sulfur Conversion Chemistry,” Advanced Functional Materials, 30, 28, 1910533 (2020).
(41)L. Li, M. Wang, J. Wang, F. Ye, S. Wang, Y. Xu, J. Liu, G. Xu, Y. Zhang, Y. Zhang, C. Yan, N. V. Medhekar, M. Liu*, and Y. Zhang, “Asymmetric gel polymer electrolyte with high lithium ion conductivity for dendrite-free lithium metal batteries,” Journal of Materials Chemistry A, 8, 16, 8033-804 (2020).
(42)J. Wang, L. Jia, S. Duan, H. Liu, Q. Xiao, T. Li, H. Fan, K. Feng, J. Yang, Q. Wang, M. Liu, J. Zhong, W. Duan, H. Lin*, and Y. Zhang*, “Single atomic cobalt catalyst significantly accelerates lithium ion diffusion in high mass loading Li2S cathode,” Energy Storage Materials, 28, 375-382 (2020).
(43)J. Wang, L. Jia, H. Liu, C. Wang, J. Zhong, Q. Xiao, J. Yang, S. Duan, K. Feng, N. Liu, W. Duan, H. Lin, and Y. Zhang*, “Multi-ion Modulated Single-Step Synthesis of a Nanocarbon Embedded with a Defect-Rich Nanoparticle Catalyst for a High Loading Sulfur Cathode,” Acs Applied Materials & Interfaces, 12, 11, 12727-12735 (2020).
(44) Q. Xu, X. Yang, M. Rao, D. Lin, K. Yan, R. Du, J. Xu, Y. Zhang, D. Ye, S. Yang, G. Zhou, Y. Lu*, and Y. Qiu*, “High energy density lithium metal batteries enabled by a porous graphene/MgF2 framework,” Energy Storage Materials, 26, 73-82 (2020).
(45)H. Yuan, G. Wang, Y. Zhao, Y. Liu, Y. Wu*, and Y. Zhang*, “A stretchable, asymmetric, coaxial fiber-shaped supercapacitor for wearable electronics,” Nano Research, 13, 6, 1686-1692 (2020).
(46)Y. Xu, S. Zhao, G. Zhou, W. Chen, F. Zhou, Z. Rong, Y. Wu, J. Li, J. Guo*, and Y. Zhang*, “Solubility-Dependent Protective Effects of Binary Alloys for Lithium Anode,” ACS Applied Energy Materials, 3, 3, 2278-2284 (2020).
(47)M. Dai, H. Fan, G. Xu, M. Wang, S. Zhang, L. Lu*, and Y. Zhang*, “Boosting electrocatalytic oxygen evolution using ultrathin carbon protected iron–cobalt carbonate hydroxide nanoneedle arrays,” Journal of Power Sources, 450, 227639 (2020).
(48)N. Liu, Z. Pan, X. Ding, J. Yang, G. Xu, L. Li, Q. Wang, M. Liu*, and Y. Zhang*, “In-situ growth of vertically aligned nickel cobalt sulfide nanowires on carbon nanotube fibers for high capacitance all-solid-state asymmetric fiber-supercapacitors,” Journal of Energy Chemistry, 41, 209-215 (2020).
(49)H. Li, S. Liu, C. Liu, J. Zhang, Y. Xu, R. Yu, Y. Wu*, Y. Zhang*, and S. Fan, “Antiferromagnetic topological insulator MnBi2Te4: synthesis and magnetic properties,” Physical Chemistry Chemical Physics, 22, 2, 556-563 (2020).
(50)D. Jiang, Y. Zhang, and X. Li*, “Synergistic effects of CuO and Au nanodomains on Cu2O cubes for improving photocatalytic activity and stability,” Chinese Journal of Catalysis, 40, 1, 105-113 (2019).
(51)S. Zhang, Y. Zhang, W. Li, Y. Wen, M. Liu, L. Lu*, J. Liu*, Y. Chen, W. Song, and Y. Zhang*, “Graphene edge-enhanced anchoring of the well-exposed cobalt clusters via strong chemical bonding for accelerating the oxygen reduction reaction,” Sustainable Energy & Fuels, 3, 10, 2859-2866 (2019).
(52)Z. Pan, J. Yang, W. Zang, Z. Kou, C. Wang, X. Ding, C. Guan, T. Xiong, H. Chen, Q. Zhang, Y. Zhong, M. Liu, L. Xing, Y. Qiu, W. Li, C. Yan, Y. Zhang*, and J. Wang*, “All-solid-state sponge-like squeezable zinc-air battery,” Energy Storage Materials, 23, 375-382 (2019).
(53)X. Wang, Z. Pan, J. Yang, Z. Lyu, Y. Zhong, G. Zhou, Y. Qiu, Y. Zhang, J. Wang*, and W. Li*, “Stretchable fiber-shaped lithium metal anode,” Energy Storage Materials, 22, 179-184 (2019).
(54)J. Wang, J. Yang, Q. Xiao, L. Jia, H. Lin*, and Y. Zhang*, “Hierarchical Sulfur-Doped Graphene Foam Embedded with Sn Nanoparticles for Superior Lithium Storage in LiFSI-Based Electrolyte,” ACS Applied Materials & Interfaces, 11, 30500-30507 (2019).
(55)Y. Ye, M. Song, Y. Xu, K. Nie, Y. Liu, J. Feng, X. Sun, E. Cairns, Y. Zhang*, and J. Guo*, “Lithium nitrate: A double-edged sword in the rechargeable lithium-sulfur cell,” Energy Storage Materials, 16, 498-504 (2019).
(56)J. Yang, Z. Pan, Q. Yu, Q. Zhang, X. Ding, X. Shi, Y. Qiu, K. Zhang*, J. Wang, and Y. Zhang*, “Free-Standing Black Phosphorus Thin Films for Flexible Quasi-Solid-State Micro-Supercapacitors with High Volumetric Power and Energy Density,” ACS Applied Materials & Interfaces, 11, 5938-5946 (2019).
(57)Y. Xu, G. Zhou, S. Zhao, W. Li, F. Shi, J. Li, J. Feng, Y. Zhao, Y. Wu, J. Guo*, Y. Cui*, and Y. Zhang*, “Improving a Mg/S Battery with YCl3 Additive and Magnesium Polysulfide,” Advanced Science, 6, 4, 1800981 (2019).
(58)Y. Xu, Y. Ye, S. Zhao, J. Feng, J. Li, H. Chen, A. Yang, F. Shi, L. Jia, Y. Wu, X. Yu, P. Glans-Suzuki, Y. Cui, J. Guo*, and Y. Zhang*, “In Situ X-ray Absorption Spectroscopic Investigation of the Capacity Degradation Mechanism in Mg/S Batteries,” Nano Letters, 19, 5, 2928-2934 (2019).
(59)X. Wang, Z. Pan, J. Zhuang, G. Li, X. Ding, M. Liu, Q. Zhang, Y. Liao, Y. Zhang*, and W. Li*, “Simultaneously Regulating Lithium Ion Flux and Surface Activity for Dendrite-Free Lithium Metal Anodes,” ACS Applied Materials & Interfaces, 11, 5, 5159-5167 (2019).
(60)X. Wang, Z. Pan, Y. Wu, X. Ding, X. Hong, G. Xu, M. Liu, Y. Zhang*, and W. Li*, “Infiltrating lithium into carbon cloth decorated with zinc oxide arrays for dendrite-free lithium metal anode,” Nano Research, 12, 3, 525-529 (2019).
(61)J. Wang, L. Jia, J. Zhong, Q. Xiao, C. Wang, K. Zang, H. Lin, H. Zheng, J. Luo, J. Yang, H. Fan, W. Duan, Y. Wu, H. Lin, and Y. Zhang*, “Single-atom catalyst boosts electrochemical conversion reactions in batteries,” Energy Storage Materials, 18, 246-252 (2019).
(62)Z. Pan, J. Yang, Q. Zhang, M. Liu, Y. Hu, Z. Kou, N. Liu, X. Yang, X. Ding, H. Chen, J. Li, K. Zhang, Y. Qiu, Q. Li, O. Wang*, and Y. Zhang*, “All-Solid-State Fiber Supercapacitors with Ultrahigh Volumetric Energy Density and Outstanding Flexibility,” Advanced Energy Materials, 9, 9, 1802753 (2019).
(63) L. Jia, J. Wang, Z. Chen, Y. Su, W. Zhao, D. Wang, Y. Wei, K. Jiang, J. Wang, Y. Wu, J. Li, W. Duan, S. Fan, and Y. Zhang*, “High areal capacity flexible sulfur cathode based on multi-functionalized super-aligned carbon nanotubes,” Nano Research 12, 1105-1113 (2019).
(64) X. Ding, Z. Pan, N. Liu, L. Li, X. Wang, G. Xu, J. Yang, J. Yang, N. Yu, M. Liu, W. Li*, and Y. Zhang*, “Freestanding Carbon Nanotube Film for Flexible Straplike Lithium/Sulfur Batteries,” Chemistry-a European Journal 25, 3775-3780 (2019).
(65) M. Chen, Z. Pan, X. Jin, Z. Chen, Y. Zhong, X. Wang, Y. Qiu, M. Xu, W. Li*, and Y. Zhang*, “A highly integrated All-manganese battery with oxide nanoparticles supported on the cathode and anode by super-aligned carbon nanotubes,” Journal of Materials Chemistry A, 7, 4494-4504 (2019).
(66) Q. Wang, Z. Jia, L. Li, J. Wang, G. Xu, X. Ding, N. Liu, M. Liu*, and Y. Zhang*, “Coupling Niobia Nanorods with a Multicomponent Carbon Network for High Power Lithium-Ion Batteries,” Acs Applied Materials & Interfaces, 11, 47, 44196-44203 (2019).
(67) A. Subramanian, Z. Pan, Z. Zhang, I. Ahmad, J. Chen, M. Liu, S. Cheng, Y. X{Ye, 2018 #3}u, J. Wu, W. Lei*, Q. Khan*, and Y. Zhang*, “Interfacial Energy-Level Alignment for High-Performance All Inorganic Perovskite CsPbBr3 Quantum Dot-Based Inverted Light Emitting Diodes,” ACS Applied Materials & Interfaces 10, 13236-13243 (2018).
(68) X. Wang, Z. Pan, Y. Wu, G. Xu, X. Zheng, Y. Qiu, M. Liu, Y. Zhang*, and W. Li*, “Reducing lithium deposition overpotential with silver nanocrystals anchored on graphene aerogel,” Nanoscale 10, 6562-16567 (2018).
(69) Y. Xu, W. Li, G. Zhou, Z. Pan, and Y. Zhang*, “A non-nucleophilic mono-Mg2+ electrolyte for rechargeable Mg/S battery,” Energy Storage Materials 14, 253-257 (2018).
(70) F. Ye, M. Liu, X. Yan, J. Li, Z. Pan, H. Li, and Y. Zhang*, “In Situ Electrochemically Derived Amorphous-Li2S for High Performance Li2S/Graphite Full Cell,” Small 14, 7 (2018).
(71) Y. Zhang, W. Li, L. Lu*, W. Song, C. Wang, L. Zhou, J. Liu*, Y. Chen, H. Jin, and Y. Zhang*, “Tuning active sites on cobalt/nitrogen doped graphene for electrocatalytic hydrogen and oxygen evolution,” Electrochimica Acta 265, 497-506 (2018).
(72) K. Zhu, Y. Luo, F. Zhao, J. Hou, X. Wang, H. Ma, H. Wu, Y. Zhang, K. Jiang, S. Fan, J. Wang*, and K. Liu*, “Free-Standing, Binder-Free Titania/Super-Aligned Carbon Nanotube Anodes for Flexible and Fast-Charging Li-Ion Batteries,” ACS Sustainable Chemistry & Engineering 6, 3426-+ (2018).
(73) Z. Pan, J. Zhong, Q. Zhang, J. Yang, Y. Qiu, X. Ding, K. Nie, H. Yuan, K. Feng, X. Wang, G. Xu, W. Li, Y. Yao, Q. Li, M. Liu*, and Y. Zhang*, “Ultrafast All-Solid-State Coaxial Asymmetric Fiber Supercapacitors with a High Volumetric Energy Density”, Advanced Energy Materials 8, 1702946 (2018).
(74) C. Ye, W. Tu, L. Yin, Q. Zheng, C. Wang, Y. Zhong, Y. Zhang, Q. Huang, K. Xu*, and W. Li*, “Converting detrimental HF in electrolytes into a highly fluorinated interphase on cathodes,” Journal of Materials Chemistry A, 6, 36, 17642-17652 (2018).
(75) Z. Pan, H. Zhi, Y. Qiu, J. Yang, L. Xing, Q. Zhang, X. Ding, X. Wang, G. Xu, H. Yuan, M. Chen, W. Li, Y. Yao, N. Motta, M. Liu*, Y. Zhang*, “Achieving commercial-level mass loading in ternary-doped holey graphene hydrogel electrodes for ultrahigh energy density supercapacitors”, Nano Energy 46, 266–276 (2018).
(76) A. Subramanian, Z. Pan, H. Li, L. Zhou, W. Li, Y. Qiu, Y. Xu, Y. Hou, C. Muzi, and Y. Zhang*, “Synergistic promotion of photoelectrochemical water splitting efficiency of TiO2 nanorods using metal-semiconducting nanoparticles,” Applied Surface Science, 420, 631-637 (2017).
(77) Q. Zhang, W. Xu, J. Sun, Z. Pan, J. Zhao, X. Wang, J. Zhang, P. Man, J. Guo, Z. Zhou, B. He, Z. Zhang, Q. Li, Y. Zhang, L. Xu*, and Y. Yao*, “Constructing Ultrahigh-Capacity Zinc-Nickel-Cobalt Oxide@Ni(OH)(2) Core-Shell Nanowire Arrays, for High-Performance Coaxial Fiber-Shaped Asymmetric Supercapacitors,” Nano Letters, 17, 12, 7552-7560 (2017).
(78) J. Wang, S. Cheng, W. Li, L. Jia, Q. Xiao, Y. Hou, Z. Zheng, H. Li, S. Zhang, L. Zhou, M. Liu, H. Lin*, and Y. Zhang*, “Robust electrical ‘highway’ network for high mass loading sulfur cathode”, Nano Energy 40, 390–398 (2017).
(79) H. Ryu, J. Hwang, D. Wang, A. S. Disa, J. Denlinger, Y. Zhang, S.-K. Mo*, C. Hwang*, and A. Lanzara, “Temperature-Dependent Electron–Electron Interaction in Graphene on SrTiO3”, Nano Letters 17, 5914-5918 (2017).
(80) Y. Xu, J. Yuan, K. Zhang,* Y. Hou, Q. Sun, Y. Yao, S. Li, Q. Bao, H. Zhang,* and Y. Zhang*, “Field-Induced n-Doping of Black Phosphorus for CMOS Compatible 2D Logic Electronics with High Electron Mobility”, Advanced Functional Materials 27, 1702211 (2017).
(81) Z. Pan, M. Liu, J. Yang, Y. Qiu, W. Li, Y. Xu, X. Zhang, and Y. Zhang*, “High Electroactive Material Loading on a Carbon Nanotube@3D Graphene Aerogel for High-Performance Flexible All-Solid-State Asymmetric Supercapacitors”, Advanced Functional Materials 27, 1701122 (2017).
(82) K. Bourzac, and Y. Zhang, “A Conversation with Yuegang Zhang,” Acs Central Science, 3, 11, 1131-1132, (2017).
(83) G. Rong, X. Zhang, W. Zhao, Y. Qiu, M. Liu, F. Ye, Y. Xu, J. Chen, Y. Hou, W. Li, W. Duan, and Y. Zhang*, “Liquid-Phase Electrochemical Scanning Electron Microscopy for In Situ Investigation of Lithium Dendrite Growth and Dissolution”, Advanced Materials, 1606187 (2017).
(84) M. Chen, Y. Zhang, L. Xing, Y. Liao, Y. Qiu,* S. Yang,* and W. Li*, “Morphology-Conserved Transformations of Metal-Based Precursors to Hierarchically Porous Micro-/Nanostructures for Electrochemical Energy Conversion and Storage”, Advanced Materials, 1607015 (2017).
(85) Q. Zhang, X. Wang, Z. Pan, J. Sun, J. Zhao, J. Zhang, C. Zhang, L. Tang, J. Luo, B. Song, Z. Zhang*, W. Lu, Q. Li, Y. Zhang, and Y. Yao*, “Wrapping Aligned Carbon Nanotube Composite Sheets around Vanadium Nitride Nanowire Arrays for Asymmetric Coaxial Fiber-Shaped Supercapacitors with Ultrahigh Energy Density”, Nano Letters 17, 2719-2726 (2017).
(86) Q. Zhang, J. Sun, Z. Pan, J. Zhang, J. Zhao, X. Wang, C. Zhang, Y. Yao*, W. Lu, Q. Li, Y. Zhang, Z. Zhang*, “Stretchable fiber-shaped asymmetric supercapacitors with ultrahigh energy density”, Nano Energy 39, 219–228 (2017).
(87) Z. Jia, M. Liu*, X. Zhao, X. Wang, Z. Pan, Y. Zhang*, “Lithium Ion Hybrid Supercapacitor Based on Three-Dimensional Flower-Like Nb2O5 and Activated Carbon Electrode Materials”, Acta Physico-Chimica Sinica 33, 2510-2516 (2017).
(88) D. Jiang*, Y. Zhang, and X. Li*, “Folded-up thin carbon nanosheets grown on Cu2O cubes for improving photocatalytic activity”, Nanoscale 9, 12348-12352 (2017).
(89) D. Jiang, J. Xue, Q. Wu, W. Zhou, Y. Zhang, and X. Li*, “Photocatalytic performance enhancement of CuO/Cu2O heterostructures for photodegradation of organic dyes: Effects of CuO morphology”, Applied Catalysis B: Environmental 211, 199-204 (2017).
(90) A. Subramanian, Z. Pan, H. Li, L. Zhou, W. Li, Y. Qiu, Y. Xu, Y. Hou, M. Chen, Y. Zhang*, “Synergistic promotion of photoelectrochemical water splitting efficiency of TiO2 nanorods using metal-semiconducting nanoparticles”, Applied Surface Science 420, 631-637 (2017).
(91) A. Subramanian, Z. Pan, G. Rong, H. Li, L. Zhou, W. Li, Y. Qiu, Y. Xu, Y. Hou, Z. Zheng, Y. Zhang*, “Graphene quantum dot antennas for high efficiency Forster resonance energy transfer based dye-sensitized solar cells”, Journal of Power Sources 343, 39-46 (2017).
(92) S. Cheng, J. Wang, H. Lin, W. Li*, Y. Qiu, Z. Zheng, X. Zhao, Y. Zhang*, “Improved cycling stability of the capping agent-free nanocrystalline FeS2 cathode via an upper cut-off voltage control”, Journal of Materials Science 52, 2442–2451 (2017).
(93) W. Li, M. Liu, J. Wang, Y. Zhang*, “Progress of Lithium/Sulfur Batteries Based on Chemically Modified Carbon”, Acta Physico-Chimica Sinica 33, 165-182 (2017).
(94) Y. Zhang, L. Ji, W. Li, Z. Zhang, L. Lu, L. Zhou, J. Liu*, Y. Chen, L. Liu*, W. Chen, and Y. Zhang*, “Highly defective graphite for scalable synthesis of nitrogen doped holey graphene with high volumetric capacitance,” Journal of Power Sources, 334, 104-111 (2016).
(95) M. Chen, D. Chen, Y. Liao, X. Zhong, W. Li*, and Y. Zhang, “Layered Lithium-Rich Oxide Nanoparticles Doped with Spinel Phase: Acidic Sucrose-Assistant Synthesis and Excellent Performance as Cathode of Lithium Ion Battery,” Acs Applied Materials & Interfaces, 8, 7, 4575-4584 (2016).
(96) W. Li, Q. Ma, Z. Zheng, Y. Zhang*, “Preparation of Three-dimensional Nitrogen-doped Carbon Nanoribbon and Application in Lithium/Sulfur Batteries”, Acta Chimica Sinica 75, 225-230 (2017).
(97) G. Rong, X. Zhang, Y. Xu, Y. Zhang*, “In-situ TEM Study of the Liquid-Phase Reaction of Ag Nanowires with a Sulfur Solution”, Acta Chimica Sinica 74, 980-983 (2016).
(98) J. Liu*, S. Xie, Z. Geng, K. Huang, L. Fan, W. Zhou, L. Qiu, D. Gao, L. Ji, L. Duan*, L. Lu, W. Li, S. Bai, Z. Liu, W. Chen, S. Feng*, and Y. Zhang*, “Carbon Nitride Supramolecular Hybrid Material Enabled High-Efficiency Photocatalytic Water Treatments”, Nano Letters 16, 6568–6575, (2016).
(99) Y. Qiu, W. Liu, W. Chen, W. Chen, G. Zhou, P-C. Hsu, R. Zhang, Z. Liang, S. Fan, Y. Zhang*, Y. Cui*, “Efficient solar driven water splitting by nanocone BiVO4-perovskite tandem cells”, Science Advances, 2:e1501764 (2016).
(100) Z. Pan, Y. Qiu, J. Yang, F. Ye, Y. Xu, X. Zhang, M. Liu*, and Y. Zhang*, “Ultra-endurance flexible all-solid-state asymmetric supercapacitors based on three-dimensionally coated MnOx nanosheets on nanoporous current collectors”, Nano Energy 26, 610–619 (2016).
(101) F. Ye, M. Liu, X. Zhang, W. Li, Z. Pan, H. Li, S. Zhang, and Y. Zhang*, “Prelithiation of Nanostructured Sulfur Cathode by an ‘On-Sheet’ Solid-State Reaction”, Small 36, 4966-4972 (2016).
(102) Y. Xu, J. Yuan, L. Fei, X. Wang, Q. Bao, Y. Wang, K. Zhang*, and Y. Zhang*, “Selenium-Doped Black Phosphorus for High-Responsivity 2D Photodetectors”, Small 36, 5000-5007 (2016).
(103) L. Lu*, W. Li, L. Zhou, Y. Zhang, Z. Zhang, Y. Chen, J. Liu*, L. Liu, W. Chen, Y. Zhang*, “Impact of size on energy storage performance of graphene based supercapacitor electrode”, Electrochimica Acta 219, 463–469 (2016).
(104) J. Yang, M. Liu, Z. Wei, Z. Pan, Y. Qiu, F. Ye, Y. Yang, X. Zhao, L. Sheng*, Y. Zhang*, “Controlling Electrochemical Lithiation/Delithiation Reaction Paths for Long-cycle Life Nanochain-structured FeS2 Electrodes”, Electrochimica Acta 211, 671–678 (2016).
(105) J. Wang, X. Wang*, H. Li, X. Yang, Y. Zhang, “Intrinsic factors attenuate the performance of anhydride organic cathode materials of lithium battery”, Journal of Electroanalytical Chemistry 773, 22–26 (2016).
(106) J. Wang, S. Cheng, W. Li*, S. Zhang, H. Li, Z. Zheng, F. Li, L. Shi, H. Lin*, Y. Zhang*, “Simultaneous optimization of surface chemistry and pore morphology of 3D graphene-sulfur cathode via multi-ion modulation”, Journal of Power Sources 321, 193-200 (2016).
(107) W. Li, S. Cheng, J. Wang, Y. Qiu, Z. Zheng, H. Lin, S. Nanda, Q. Ma, Y. Xu, F. Ye, M. Liu, L. Zhou, Y. Zhang*, “Synthesis, crystal structure and electrochemical properties of a novel simple-type magnesium electrolyte for magnesium/sulfur batteries”, Angewandte Chemie - International Edition 55, 6406-6410 (2016).
(108) M. Liu, F. Ye, W. Li, H. Li, Y. Zhang*, “Chemical routes toward long-lasting lithium/sulfur cells”, Nano Research 9, 94-116 (2016).
(109) H. Li, X. Yang*, X. Wang*, Y. He, F. Ye, M. Liu, and Y. Zhang*, “A dual-spatially-confined reservoir by packing micropores within dense graphene for long-life lithium/sulfur batteries”, Nanoscale 8, 2395-2402 (2016).
(110) Y. Qiu, G. Rong, J. Yang, G. Li, S. Ma, X. Wang, Z. Pan, Y. Hou, M. Liu, F. Ye, W. Li, Z. W. Seh, X. Tao, H. Yao, N. Liu, R. Zhang, G. Zhou, J. Wang, S. Fan, Y. Cui*, Y. Zhang*, “Highly nitridated graphene-Li2S cathodes with stable modulated cycles”, Advanced Energy Materirals 5, 1501369, (2015).
(111) M.-K. Song, Y. Zhang, and E. J. Cairns*, “Effects of cell construction parameters on the performance of lithium/sulfur cells,” Aiche Journal, 61, 9, 2749-2756 (2015).
(112) X. Liang, B. Liang, Z. Pan, X. Lang, Y. Zhang, G. Wang*, P. Yin, and L. Guo, “Tuning plasmonic and chemical enhancement for SERS detection on graphene-based Au hybrids,” Nanoscale, 7, 47, 20188-20196 (2015).
(113) S. Zhang, M. Liu*, F. Ma, F. Ye, H. Li, X. Zhang, Y. Hou, Y. Qiu, W. Li, J. Wang, J. Wang and Y. Zhang*, “A high energy density Li2S@C nanocomposite cathode with a nitrogen-doped carbon nanotube top current collector”, Journal of Materials Chemistry A, 3, 18913–18919 (2015).
(114) J. Yang, G. Li, Z. Pan, M. Liu, Y. Hou, Y. Xu, H. Deng, L. Sheng, X. Zhao*, Y. Qiu* and Y. Zhang*, “All-Solid-State High-Energy Asymmetric Supercapacitors Enabled by Three-Dimensional Mixed-Valent MnOx Nanospike and Graphene Electrodes”, ACS Applied Materials & Interfaces 7, 22172–22180, (2015).
(115) J. Wu, Y. Xu, P. Xu, Z. Pan, S. Chen, Q. Shen, L. Zhan*, Y. Zhang*, W. Ni*, “Surface-enhanced Raman scattering from AgNP-graphene-AgNP sandwiched nanostructures”, Nanoscale 7, 17529–17537 (2015).
(116) J. Liu*, W. Li, L. Duan, X. Li, L. Ji, Z. Geng, K. Huang, L. Lu, L. Zhou, Z. Liu, W. Chen, L. Liu, S. Feng*, and Y. Zhang*, “A Graphene-like Oxygenated Carbon Nitride Material for Improved Cycle-Life Lithium/Sulfur Batteries” Nano Letters 15, 5137−5142 (2015).
(117) F. Ye, Y. Hou, M. Liu, C. W. Li, X. Yang, Y. Qiu, L. Zhou, H. Li, Y. Xu, and Y. Zhang*, “Fabrication of mesoporous Li2S–C nanofibers for high performance Li/Li2S cell cathodes”, Nanoscale 7, 9472–9476 (2015).
(118) M. Liu, C. Yan, Y. Zhang*, “Fabrication of Nb2O5 Nanosheets for High-rate Lithium Ion Storage Applications”, Scientific Reports 5, 8326 (2015).
(119) Z. Pan, Y. Qiu, J. Yang, M. Liu, L. Zhou, Y. Xu, L. Sheng, X. Zhao*, and Yuegang Zhang*, “Synthesis of three-dimensional hyperbranched TiO2 nanowire arrays with significantly enhanced photoelectrochemical hydrogen production”, Journal of Materials Chemistry A, 3, 4004–4009 (2015).
(120) H. Li, X. Yang, X. Wang, M. Liu, F. Ye, J. Wang, Y. Qiu, W. Li, Y. Zhang*, “Dense Integration of Graphene and Sulfur via the Soft Approach for Compact Lithium/Sulfur Battery Cathode”, Nano Energy 12, 468–475 (2015).
(121) Y. Qiu, G. Li, Y. Hou, Z. Pan, H. Li, W. Li, M. Liu, F. Ye, X. Yang,* Y. Zhang*, “Vertically Aligned Carbon Nanotubes on Carbon Nanofibers: A Hierarchical Three-Dimensional Carbon Nanostructure for High-Energy Flexible Supercapacitors”, Chemistry of Materials, 27, 1194−1200 (2015).
(122) G. Li, Y. Qiu, Y. Hou, H Li, L. Zhou, H. Deng*, and Yuegang Zhang*, “Synthesis of V2O5 hierarchical structures for long cycle-life lithium-ion storage”, Journal of Materials Chemistry A,3, 1103–1109 (2015).
(123) D. Wang, H. Tian, I. Martin-Fernandez, Y. Yang, T. L. Ren*, and Y. Zhang* , “Large-Scale Fabrication of Graphene-based Electronic and MEMS Devices” (Invited Paper), IEDM (International Electron Devices Meeting) Technical Digest, 382−385, 2014.
(124) J. J. Velasco-Velez, C. –H. Wu , B. –Y. Wang , Y. Sun , Y. Zhang , J. Guo , and M. Salmeron, “Polarized X-ray Absorption Spectroscopy Observation of Electronic and Structural Changes of CVD Graphene in Contact with Water”, The Journal of Physical Chemstry C, 118, 25456–25459 (2014).
(125) Y. Qiu, S. -F. Leung, Z. Wei, Q. Lin, X. Zheng, Y. Zhang, Z. Fan, and S. Yang, “Enhanced Charge Collection for Splitting of Water Enabled by an Engineered Three-Dimensional Nanospike Array”, The Journal of Physical Chemstry C, 118, 22465–22472 (2014).
(126) Y. Qiu, W. Li, W. Zhao, G. Li, Y. Hou, M. Liu, L. Zhou, F. Ye, H. Li, Z. Wei, S. Yang, W. Duan, Y. Ye, J. Guo, Y. Zhang*: “High-Rate, Ultralong Cycle-Life Lithium/Sulfur Batteries Enabled by Nitrogen-Doped Graphene” Nano Letters 14, 4821−4827 (2014).
(127) Y. Qiu, W. Li, G. Li, Y. Hou, L. Zhou, H. Li, M. Liu, F. Ye, X. Yang, Y. Zhang*: “Polyaniline-modified cetyltrimethylammonium bromide-graphene oxide-sulfur nanocomposites with enhanced performance for lithium-sulfur batteries” Nano Research 7, 1355–1363 (2014).
(128) D. Jiang, W. Zhou, X. Zhong, Y. Zhang, and X. Li, “Distinguishing Localized Surface Plasmon Resonance and Schottky Junction of Au−Cu2O Composites by Their Molecular Spacer Dependence”, ACS Applied Materials Interfaces 6, 10958−10962 (2014).
(129) Y. C. Qiu, Y. Zhao, X. Yang, W. Li, Z. Wei, Q. Lin, J. Xiao, S. –F. Leung, H. Wu, Y. Zhang*, Z. Fan*, S. Yang*, “Three-dimensional metal/oxide nanocone arrays for high-performance electrochemical pseudocapacitors”, Nanoscale 6, 3626-3631 (2014).
(130) Y. C. Qiu, S. -F. Leung, Q. Zhang, B. Hua, Q. Lin, Z. Wei, K. -H. Tsui, Y. Zhang, S. Yang*, Z. Fan*, “Efficient Photoelectrochemical Water Splitting with Ultra-thin Film of Hematite on Three-dimensional Nanophotonic Structures” Nano Letters 14, 2123−2129 (2014).
(131) H. Tian, Y. Yang, D. Xie, Y. -L. Cui, W-T. Mi, Y. Zhang*, and T. -L. Ren*, “Wafer-Scale Integration of Graphene-based Electronic, Optoelectronic and Electroacoustic Devices”, Scientific Reports 4, 3598 (2014).
(132) J. J. Velasco-Velez, C. -H. Chuang, H. -L. Han, I. Martin-Fernandez, C. Martinez, W. -F Pong, Y. -R. Shen, F. Wang, Y. Zhang, J. Guo, and M. Salmeron, “In-Situ XAS Investigation of the Effect of Electrochemical Reactions on the Structure of Graphene in Aqueous Electrolytes”, Journal of The Electrochemical Society 160, C445-C450 (2013).
(133) D. Ielmini*, C. Cagli, F. Nardi, and Y. Zhang, “Nanowire-based resistive switching memories: devices, operation and scaling,” Journal of Physics D-Applied Physics, 46, 7 (2013).
(134) M. K. Song, Y. Zhang*, and E. J. Cairns*, “A Long-Life, High-Rate Lithium/Sulfur Cell: A Multifaceted Approach to Enhancing Cell Performance”, Nano Letters 13, 5891-5899 (2013).
(135) G. Xu, Y. Zhang, X. Duan, A. A. Balandin, K. L. Wang, “Variability Effects in Graphene: Challenges and Opportunities for Device Engineering and Applications,” Proceedings of the IEEE 101, 1670-1688 (2013).
(136) H. Tian, Y. Yang, D. Xie, T. –L. Ren, Y. Shu, H. Sun, C. J. Zhou, X. Liu, L. Q. Tao, J. Ge, C. H. Zhang, and Y. Zhang*, “Laser directed lithography of asymmetric graphene ribbons on a polydimethylsiloxane trench structure”, Physical Chemistry Chemical Physics 15, 6825-6830 (2013).
(137) M. K. Song, E. J. Cairns, and Y. Zhang*, “Lithium-Sulfur Batteries with High Specific Energy: Old Challenges and New Opportunities” (Feature Article), Nanoscale 5, 2186–2204 (2013).
(138) D. Wang, H. Tian, Y. Yang, D. Xie, T. –L. Ren, Y. Zhang*, “Scalable and Direct Growth of Graphene Micro Ribbons on Dielectric Substrates”, Scientific Reports 3, 1348(2013).
(139) H. Tian, H. -Y. Chen, B. Gao, S. Yu, J. Liang, Y. Yang, D.Xie, J. Kang, T. -L.Ren, Y. Zhang,* and H.-S. P. Wong, “Monitoring Oxygen Movement by Raman Spectroscopy of Resistive Random Access Memory with a Graphene-Inserted Electrode”, Nano Letters 13, 651−657 (2013).
(140) K. Cai, M. K. Song, E. J. Cairns, and Y. Zhang*, “Nanostructured Li2S−C Composites as Cathode Material for High-Energy Lithium/Sulfur Batteries”, Nano Letters 12, 6474−6479 (2012).
(141)I. Martin-Fernandez, D. Wang, and Y. Zhang*, “Direct Growth of Graphene Nanoribbons for Large-Scale Device Fabrication”, Nano Letters 12, 6175−6179 (2012).
(142)H.-Y. Chen, H. Tian, B. Gao, S. Yu, J. Liang, J. Kang, Y. Zhang, T.-L. Ren, H.-S. P. Wong, “Electrode/Oxide Interface Engineering by Inserting Single-Layer Graphene: Application for HfOx–Based Resistive Random Access Memory”, IEDM (International Electron Devices Meeting) Technical Digest, 489-492 (2012).
(143)J. Li, X. Fang, X. Wang, and Y. Zhang*, “Direct Growth of Vertical ZnO Nanorods on Single-Layer Graphene by Electrochemical Deposition”, Journal of Nanoengineering and Nanomanufacturing 2, 367-370 (2012).
(144)C. Hwang, D. A. Siegel, S. K. Mo, W. Regan, A. Ismach, Y. Zhang, A. Zettl, and A. Lanzara, “Fermi velocity engineering in graphene by substrate modification”, Scientific Reports 2, 590 (2012).
(145) L. Zhang , L. Ji, P. Glans , Y. Zhang , J. Zhu and J. Guo, “Electronic structure and chemical bonding of a graphene oxide–sulfur nanocomposite for use in superior performance lithium–sulfur cells”, Physical Chemistry Chemical Physics 14, 13670–13675 (2012).
(146) N. Tayebi, A. Yanguas-Gil, N. Kumar, Y. Zhang, J. R. Abelson, Y. Nishi, Q. Ma, and V. R. Rao, “Hard HfB2 tip-coatings for ultrahigh density probe-based storage”, Applied Physics Letters 101, 091909 (2012).
(147) L. Zhang, E. Pollak, W. Wang, P. Jiang, P. Glans, Y. Zhang, J. Cabana, R. Kostecki, C. Chang, M. Salmeron, J. Zhu, J. Guo, “Electronic structure study of ordering and interfacial interaction in graphene/Cu composites”, Carbon 50, 5316–5322 (2012).
(148) L. Ji, H. Xin, T. R. Kuykendall, S. Wu, H. Zheng, M. Rao, E. J. Cairns, V. Battaglia, and Y. Zhang*, “SnS2 nanoparticle loaded graphene nanocomposites for superior energy storage”, Physical Chemistry Chemical Physics 14, 6981–6986 (2012).
(149) L. Ji, M. Rao, H. Zheng, L. Zhang, Y. Li, W. Duan, J. Guo, E. J. Cairns, and Y. Zhang*, “Graphene Oxide as a Sulfur Immobilizer in High Performance Lithium/Sulfur Cells”, Journal of the American Chemical Society 133, 18522–18525 (2011).
(150)L. Ji, M. Rao, S. Aloni, L. Wang, E. J. Cairns, Y. Zhang*, “Porous Carbon Nanofiber-Sulfur Composite Electrodes for Lithium/Sulfur Cells”, Energy & Environmental Science 4, 5053-5059 (2011).
(151) L. Ji, H. Zheng, A. Ismach, Z. Tan, S. Xun, E. Lin, V. Battaglia, V. Srinivasan, Y. Zhang*, “Graphene/Si Multilayer Structure Anodes for Advanced Half and Full Lithium-Ion Cells”, Nano Energy 1, 164–171 (2012).
(152)C. Cagli, F. Nardi, B. Harteneck, Z. Tan, Y. Zhang,* and D. Ielmini*, “Resistive-switching crossbar memory based on Ni-NiO core-shell nanowires”, Small 7, 2899–2905 (2011). [Featured cover picture in Small, Volume 7, Issue 20, page 2818].
(153) L. Ji, Z. Tan, T. R. Kuykendall, E. J. An, Y. Fu, V. Battaglia, and Y. Zhang*, “Multilayer nanoassembly of Sn-nanopillar arrays sandwiched between graphene layers for high-capacity lithium storage”, Energy & Environmental Science 4, 3611-3616 (2011).
(154)L. Ji, Z. Tan, T. R. Kuykendall, S. Aloni, S. Xun, E. Lin, V. Battaglia, and Y. Zhang*, “Fe3O4 nanoparticle-integrated graphene sheets for high-performance half and full lithium ion cells”, Physical Chemistry Chemical Physics 13, 7170-7177 (2011).
(155) G. Xu, C. M. Torres, Jr., J. Bai, J. Tang, T. Yu, Y. Huang, X. Duan, Y. Zhang, and K. Wang, “Linewidth roughness in nanowire-mask-based graphene nanoribbons”, Applied Physics Letters98, 243118 (2011).
(156) G. Xu, C. M. Torres, Jr., J. Tang, J. Bai, E. B. Song, Y. Huang, X. Duan, Y. Zhang*, and K. Wang*, “Edge Effect on Resistance Scaling Rules in Graphene Nanostructures”, Nano Letters 11, 1082-1086 (2011).
(157)G. Xu, C. M. Torres, Jr., E. B. Song, J. Tang, J. Bai, X. Duan, Y. Zhang*, and K. Wang*, “Enhanced conductance fluctuation by quantum confinement effect in graphene nanoribbons”, Nano Letters 10, 4590–4594 (2010).
(158)N. Tayebi, Y. Zhang*, R. J. Chen, Q. Tran, R. Chen, Y. Nishi, Q. Ma, and V. Rao, “An Ultraclean Tip-Wear Reduction Scheme for Ultrahigh Density Scanning Probe-Based Data Storage,” Acs Nano, 4, 10, 5713-5720 (2010).
(159) N. Tayebi, Y. Zhang*, R. J. Chen, Q. Tran, R. Chen, Y. Nishi, Q. Ma, and V. Rao, “An ultraclean tip-wear reduction scheme for ultrahigh density scanning probe-based data storage”, ACS Nano 4, 5713–5720 (2010).
(160) G. Xu, J. Bai, C. M. Torres, Jr., E. B. Song, J. Tang,Y. Zhou, X. Duan, Y. Zhang, and K. L. Wang, “Low-noise submicron channel graphene nanoribbons”, Applied Physics Letters 97, 073107 (2010).
(161)G. Xu, C. M. Torres Jr., Y. Zhang*, F. Liu, E. B. Song, M. Wang, Y. Zhou, C. Zeng, and K. L. Wang*, “ Effect of spatial charge inhomogeneity on 1/f noise behavior in graphene”, Nano Letters 10, 3312-3317 (2010).
(162)A. Ismach, C. Druzgalski, S. Penwell, Adam Schwartzberg, M. Zheng, A. Javey, J. Bokor, Y. Zhang*, “Direct chemical vapor deposition of graphene on dielectric surfaces”, Nano Letters 10, 1542-1548 (2010).
(163)M. Zheng, K. Takei, B. Hsia, H. Fang, X. Zhang, N. Ferralis, H. Ko, Y. Chueh, Y. Zhang, R. Maboudian, and A. Javey, “Metal-catalyzed crystallization of amorphous carbon to graphene”, Applied Physics Letters 96, 063110 (2010).
(164) N. Tayebi, Y. Narui, N. Franklin, C. P. Collier, K. P. Giapis, Y. Nishi, and Y. Zhang*, “Fully inverted single-digit nanometer domains in ferroelectric films”, Applied Physics Letters 96, 023103 (2010).
(165) J. R. McDonough, J. W. Choi, Y. Yang, F. La Mantia, Y. Zhang*, and Y. Cui, “Carbon nanofibersupercapacitors with large areal capacitances”, Applied Physics Letters 95, 243109 (2009).
(166)X. Liang, A. S. P. Chang, Y. Zhang, B. D. Harteneck, H. Choo, D. L. Olynick, and S. Cabrini, “Electrostatic force assisted exfoliation of prepatterned few-layer graphenes into device sites”, Nano Letters 9, 467-472 (2009).
(167) N. Teyabi, Y. Narui, R. Chen, C. P. Collier, K. Giapis, Y. Zhang*, “Nanopencil as a wear-tolerant probe for ultrahigh density data storage”, Applied Physics Letters 93, 103112 (2008).
(168) D. Ielmini and Y. Zhang, “Evidence for trap-limited transport in the sub-threshold conduction regime of chalcogenide glasses”, Applied Physics Letters 90, 192102 (2007).
(169) D. Ielmini and Y. Zhang, “Analytical model for sub-threshold conduction and threshold switching in chalcogenide-based memory devices”, Journal of Applied Physics 102, 054517 (2007).
(170)D. Ielmini and Y. Zhang*, “Physics-based analytical model of chalcogenide-based memories for array simulation”, IEDM (International Electron Devices Meeting) Technical Digest, 401-404, 2006.
(171)Y. Zhang*, “Carbon nanotube based nonvolatile memory devices” (invited review paper), International Journal of High Speed Electronics and Systems, 16, 959-975 (2006).
(172) J. Guo, E. Kan, U. Ganguly, Y. Zhang, “High sensitivity and nonlinearity of carbon nanotube charge-based sensors”, Journal of Applied Physics 99, 084301 (2006).
(173)R. J. Chen and Y. Zhang* , “Controlled precipitation of solubilized carbon nanotubes by delamination of DNA”, Journal of Physical Chemistry B 110, 54-57 (2006).
(174) U. Ganguly, J. Guo, E. Kan, Y. Zhang*, “Carbon nanotube based non-volatile memory and charge sensors” (Invited paper), Proceedings of SPIE, Vol. 6003, 60030H (2005).
(175)U. Ganguly, E. Kan, Y. Zhang*, “Carbon nanotube-based nonvolatile memory with charge storage in metal nanocrystals” Applied Physics Letters 87, 043108 (2005).
(176) S. Tan, H. Lopez, Y. Zhang*, “In-situ Raman and fluorescence monitoring of optically trapped single-walled carbon nanotubes” (Invited paper), Proceedings of SPIE, Vol. 5593, 73-81 (2004).
(177) S. Tan, H. A. Lopez, C. W. Cai, Y. Zhang*, “Optical trapping of single-walled carbon nanotubes”, Nano Letters 4, 1415-1419 (2004).
(178)S. Zhang, X. Hu, H. Li, Z. Shi, K. Yue, J. Zi, Z. Gu, X. Wu, Z. Lian, Y. Zhan, F. Huang, L. Zhou, Y. Zhang, S. Iijima, “Abnormal anti-Stokes Raman scattering of carbon nanotubes”, Physical Review B 66, 035413 (2002).
(179) Y. Zhang, Y. Li, W. Kim, D. Wang, H. Dai, “Imaging as-grown single-walled carbon nanotubes originated from isolated catalytic nanoparticles”, Applied Physics A74, 325-328 (2002).
(180) A. Goldoni, R. Larciprete, L. Gregoratti, B. Kaulich, M. Kiskinova, Y. Zhang, H. Dai, L. Sangaletti and F. Parmigiani, “X-ray photoelectron microscopy of the C1 score level of free-standing single-wall carbon nanotube bundles”, Applied Physics Letters 80, 2165 (2002).
(181) Y. Zhang, A. Chang, J. Cao, Q. Wang, W. Kim, Y. Li, N. Morris, E. Yenilmez, J. Kong, H. Dai, “Electric-field-directed growth of aligned single-walled carbon nanotubes”, Applied Physics Letters 79, 3155-3157 (2001).
(182)R. Chen, N. Franklin, J. Kong, J. Cao, T. Tombler, Y. Zhang, H. Dai, “Molecular photodesorption from single-walled carbon nanotubes”, Applied Physics Letters 79, 2258-2260 (2001).
(183)Y. Li, W. Kim, Y. Zhang, M. Rolandi, D. Wang, H. Dai, “Growth of single-walled carbon nanotubes from discrete catalytic nanoparticles of various sizes”, Journal Physical Chemistry B 105, 11424 (2001).
(184)R. Chen, Y. Zhang, D. Wang, H. Dai, “Noncovalent sidewall functionalization of single-walled carbon nanotubes for protein immobilization”, Journal of the American Chemical Society 123, 3838-3839 (2001).
(185) Y. Zhang, N. W. Franklin, R. Chen, and H. Dai*, “Metal coating on suspended carbon nanotubes and its implication to metal-tube interaction,” Chemical Physics Letters, 331, 1, 35-41 (2000).
(186)Y. Zhang, H. Dai, “Formation of metal nanowires on suspended single-walled carbon nanotubes”, Applied Physics Letters 77, 3015-3017 (2000).
(187) Y. Zhang, N. W. Franklin, R. J. Chen, H. Dai, “A study of metal coating on suspended carbon nanotubes: towards elucidating metal-tube interactions”, Chemical Physics Letters 331, 35-41 (2000).
(188) Y. Zhang* and S. Iijima, “Controllable method for fabricating single-wall carbon nanotube tips”, Applied Physics Letters 77, 966-968 (2000).
(189) Y. Zhang* and S. Iijima, “Microstructural evolution of single-walled carbon nanotubes under electron irradiation”, Philosophical Magazine Letters 80, 427-433 (2000).
(190) Y. Zhang*, Z. Shi, Z. Gu, and S. Iijima, “Structure modification of single-wall carbon nanotubes”, Carbon38, 2055-2059 (2000).
(191)K. Suenaga, Y. Zhang, S. Iijima, “Coiled structure of eccentric coaxial nanocable made of amorphous boron and silicon oxide”, Applied Physics Letters 76, 1564-1566 (2000).
(192) Z. Shi, Y. Lian, F. H. Liao, X. Zhou, Z. Gu, Y. Zhang, S. Iijima, H. Li, K. T. Yue, S-L. Zhang, “Large scale synthesis of single-wall carbon nanotubes by arc-discharge method”, Journal of Physics and Chemistry of Solids 61, 1031-1036 (2000).
(193) Z. Shi, Y. Lian, X. Zhou, Z. Gu, Y. Zhang, S. Iijima, Q. Gong, H. Li, and S-L. Zhang, “Single-wall carbon nanotube colloids in polar solvents”, Chemical Communications, 461-462 (2000).
(194)H. D. Li, Z. L. Lian, K. T. Yue, Y. Zhan, S. L. Zhang , Z. J. Shi, X. H. Zhou, Y. F. Lian, Z. N. Gu, B. B. Liu, R. S. Yang, H. B. Yang, G. T. Zou, Y. Zhang, and S. Iijima, “Temperature dependence of the Raman spectra of single-wall carbon nanotubes”, Applied Physics Letters 76, 2053-2055 (2000).
(195) Y. Zhang* and S. Iijima, “Formation of single-wall carbon nanotubes by laser ablation of fullerenes at low temperature”, Applied Physics Letters 75, 3087-3089 (1999).
(196)Z. Shi, Y. Lian, X. Zhou, Z. Gu, Y. Zhang, S. Iijima, H. Li, K. T. Yue, S-L. Zhang, “Production of single-wall carbon nanotubes at high pressure”, Journal of Physical Chemistry B 103, 8698-8701 (1999).
(197)Z. Shi, Y. Lian, F. Liao, X. Zhou, Z. Gu, Y. Zhang, S. Iijima, “Purification of single-wall carbon nanotubes”, Solid State Communications 112, 35-37 (1999).
(198) O. Lourie, H. D. Wagner, Y. Zhang, and S. Iijima, “Dependence of elastic properties on morphology in single-wall carbon nanotubes”, Advanced Materials 11, 931-934 (1999).
(199) Y. Zhang* and S. Iijima, “Elastic response of carbon nanotube bundles to visible light”, Physical Review Letters 82, 3472-3475 (1999).
(200) Y. Zhang*, S. Iijima, Z. Shi, and Z. Gu, “Defects in arc-discharge-produced single-walled carbon nanotubes”, Philosophical Magazine Letters 79, 473-479 (1999).
(201) Z. Shi, Y. Lian, X. Zhou, Z. Gu, L. Zhou, K. T. Yue, S. Zhang, Y. Zhang, S. Iijima, “Mass-production of single-wall carbon nanotubes by arc discharge method”, Carbon 37, 1449-1453 (1999).
(202) Y. Zhang*, T. Ichihashi, E. Landree, F. Nihey, and S. Iijima, “Heterostructures of single-walled carbon nanotubes and carbide nanorods”,Science 285, 1719-1722 (1999).
(203) Y. Zhang*, K. Suenaga, C. Colliex, and S. Iijima, “Coaxial nanocable: Silicon carbide and silicon oxide sheathed with boron nitride and carbon”, Science 281, 973-975 (1998).
(204) Y. Zhang*, H. Gu, and S. Iijima, “Single-wall carbon nanotubes synthesized by laser ablation in a nitrogen atmosphere”, Applied Physics Letters 73, 3827-3829 (1998).
(205) Y. Zhang and S. Iijima, “Microscopic structure of as-grown single-wall carbon nanotubes by laser ablation”, Philosophical Magazine Letters 78, 139-144 (1998).
(206) Y. Zhang*, H. Gu, K. Suenaga, and S. Iijima, “Heterogeneous growth of B-C-N nanotubes by laser ablation”, Chemical Physics Letters 279, 264-269 (1997).
(207)Y. Zhang, H. Ichinose, M. Nakanose, K. Ito, and Y. Ishida, “Structure modeling of 3 and 9 coincident boundaries in CVD diamond thin films”, Journal of Electron Microscopy 48, 245-251 (1999).
(208) K. Kohyama, H. Ichinose, Y. Zhang, Y. Ishida and M. Nakanose, “Tight-binding calculation of the {211} =3 boundary in diamond”, Interface Science 4, 157-167 (1997).
(209) H. Ichinose, M. Nakanose, Y. Zhang, “Atomic and electron structure of diamond grain boundaries in a polycrystalline film”, Materials Research Society symposium proceedings: Polycrystalline Thin Films - Structure, Texture, Properties and Applications III, 472, 93-98 (1997).
(210)H. Ichinose, Y. Zhang, Y. Ishida, K. Ito, and M. Nakanose, “Application of spatially resolved EELS on atomic structure determination of diamond grain boundary”, Materials Research Society Symposium Proceedings: Atomic Resolution Microscopy of Surfaces and Interfaces, 466 , 273-278 (1997).
(211) Y. Zhang, H. Ichinose, M. Nakanose, K. Ito, and Y. Ishida, “Transmission electron microscopic observation of grain boundaries in CVD diamond thin films”, Journal of Electron Microscopy 45, 436-441 (1996).
(212) Y. Zhang, H. Ichinose, Y. Ishida, K. Ito, and M. Nakanose, “Atomic and electronic structures of grain boundary in chemical vapor deposited diamond thin film”, Materials Research Society Symposium Proceedings: Diamond for Electronic Applications, 416 , 355-360 (1996).
(213)Y. Zhang, H. Ichinose, K. Ito, Y. Ishida, and M. Nakanose, “Grain boundary structure and growth sequence of diamond thin film”, Materials Science Forum 204-206, 207-214 (1996).
(214) H. Ichinose, Y. Zhang, Y. Ishida, and M. Nakanose, “Morphology, atomic structure and electronic structure of artificial diamond grain boundary”, JEOL News Vol. 32E, No. 1, p. 16, 1996
(215) Y. Zhang, H. Ichinose, Y. Ishida, and M. Nakanose, “HRTEM of grain boundaries in diamond thin film”, Proceedings of the 2nd NIRIM International Symposium on Advanced Materials (ISAM’95), 271-274 (1995).
(216)Y. Ishida, Y. Zhang, T. Katoh, H. Ichinose, “High resolution transmission electron microscopy of a segregated aluminum grain boundary and of diamond grain boundaries”, Annales de Physique C3 20, 83-89 (1995).
(217) Y. Zhang, S. Fan, C. Shi, Z. Niu, and B. Gu, “In-situ fabrication of YBCO/YSZ/Si thin films by laser ablation”, Physica C 185-189, 1997-1998 (1991).
(218) Y. Zhang, C. Shi, S. Fan, C. Cui, S. Li, J. Li, and M. Liu, “Preparation and critical current measurements of laser ablated YBCO superconducting thin films”, Chinese Physics Letters 8, 416-419 (1991).
(219) Y. Zhang, C. Shi, S. Fan, “In-situ fabrication of superconducting YBCO thin films by PLD method”, Cryogenics and Superconductivity (In Chinese), Vol.19, No.1, p. 45-47, 1991.
专著章节:
(220) Y. Zhang*, “Composite Nanowires”, in Nanowires and Nanobelts, ed. Zhong Lin Wang, Kluwer Academic Publishers, Boston, 2003, Vol. 2,pp. 257-268.
(221) Y. Zhang*, W. Han, G. Gu, “Nanocables and Nanojunctions“, in Encyclopedia of Nanoscience and Nanotechnology, ed. H. S. Nalwa, American Scientific Publishers, 2004, Vol. 6, pp. 61-76.
(222) Y. Zhang*, “Carbon nanotube based nonvolatile memory devices”, in Nanotubes and Nanowires, ed. P. J. Burke, World Scientific Publishing Co., Singapore, 2007, pp.77-93.
(223) N. Teyabi and Y. Zhang, “Ultrahigh density probe-based storage using ferroelectric thin films”, in Ferroelectrics – Applications, ed. M. Lallart, InTech, Rijeka, Croatia, 2011, pp. 157-178.
(224) Y. Zhang and X. Yang, “Lithium/Sulfur Batteries based on Carbon Nanomaterials”, in Carbon Nanomaterials for Advanced Energy Systems: Advances in Materials Synthesis and Device Applications, ed. W. Lu, J.-B. Naek, and L. Dai, John Wiley & Sons, Inc., Hoboken, New Jersey, 2015, pp. 365-384.
