西安电子科技大学杨如森

qingsheng

杨如森，西安电子科技大学“华山学者”特聘教授，博士生导师。分别于1998年、2001年在吉林大学获得物理专业学士学位和凝聚态物理硕士学位。2007年在美国佐治亚理工学院获得材料科学与工程博士学位；从事博士后研究3年后，2010年任美国明尼苏达大学机械工程学院助理教授，现任西安电子科技大学先进材料与纳米科技学院教授。

杨如森教授长期从事新型纳米材料合成、及其在新型能源和传感器应用。在国际上首次制备出包括纳米环，超小单晶纳米弹簧，极性可控压电生物材料等功能微纳结构，发现精确控制纳米线阵列取向的生长方法，参与了纳米能源的开创性研究，利用压电电子效应在先进传感器方向取得突破。三次组织了美国材料学会年会的纳米能源分会；应邀在国际学术会议上做特邀报告10余次；获得纳米能源奖（Nano Energy Award, 2017），美国3M公司杰出青年教授奖（3M Non-tenured Faculty Award, 2014）和美国自然科学基金早期职业生涯奖（NSF Career Award，2012）；并于2013年被明尼苏达大学授予McKnight Land-Grant教授称号。已在Science, Nature Nanotech, Nano Lett, Adv. Mat.，J. Am. Chem. Soc.，Appl. Phys. Lett.等国际著名期刊上发表论文70余篇，被引用7,000余次。

姓名]姓名]硕导或博导：博导

联系方式

<span]联系方式

<span]通信地址：西安电子科技大学南校区G楼129

电子邮箱：rsyang@xidian.edu.cn

<span]电子邮箱：rsyang@xidian.edu.cn

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主要研究方向

<span]主要研究方向

<span]1. 智能生物材料的合成与表征

2.]2.]3. 先进传感器

4.]4.]

1.     H. Hao; K. Jenkins, X. Huang; Y. Xu; J. Huang, R. Yang,.Piezoelectric potential in single-crystalline ZnO nanohelices based on finite element analysis. Nanomaterials 7, 430 (2017).

2.     J. Kory, Y. Rusen, Mechanical transfer of ZnO nanowires for a flexible and conformal piezotronic strain sensor, Semicond. Sci. Technol. 32, 074004 (2017)

3.     V. Nguyen, S. Kelly, R. Yang, Piezoelectric peptide-based nanogenerator enhanced by single-electrode triboelectric nanogenerator, APL Materials 5, 074108 (2017)

4.     V. Nguyen, R. Zhu, K. Jenkins, R. Yang, Self-assembly of diphenylalanine peptide with controlled polarization for power generation. Nature Communications 7, 13566 (2016).

5.     R. Zhu, K. Jenkins, R. Yang, Degradation and nano-patterning of ferroelectric P(VDF-TrFE) thin films with electron irradiation, RSC Advances, 5, 106700 (2015).

6.     K. Jenkins, V. Nguyen, R. Zhu, R. Yang, Piezotronic effect: an emerging mechanism for sensing applications, Sensors 15, 22914 (2015).

7.     H. Li, Y. Sang, S. Chang, X. Huang, Y. Zhang, R. Yang, H. Jiang, H. Liu, Z. L. Wang, Enhanced ferroelectric-nanocrystal-based hybrid photocatalysis by ultrasonic-wave-generated piezophototronic effect. Nano Lett. 15, 2372 (2015).

8.     V. Nguyen, K. Jenkins, R. Yang, Epitaxial growth of vertically aligned piezoelectric diphenylalanine peptide microrods with uniform polarization, Nano Energy, 17, 323 (2015)

9.     V. Nguyen, R. Zhu, R. Yang, Environmental effects on nanogenerators, Nano Energy, 14, 49 (2015).

10.  R. Zhu, R. Yang, Separation of the piezotronic and piezoresistive effects in a zinc oxide nanowire, Nanotechnology 25, 345702 (2014).

11.  R. Zhu, Y. Lai, V. Nguyen, R. Yang, Scalable alignment and transfer of nanowires in a spinning Langmuir film, Nanoscale 6, 11976 (2014).

12.  W. Zhang, R. Zhu, V. Nguyen, R. Yang, Highly sensitive and flexible strain sensors based on vertical zinc oxide nanowire arrays, Sensors and Actuators A: Physical, 205, 164 (2014)

13.  R. Zhu, W. Zhang, C. Li, R. Yang, Uniform Zinc Oxide Nanowire Arrays Grown on Nonepitaxial Surface with General Orientation Control, Nano Lett 13, 5171 (2013)

14.  V. Nguyen, R. Yang, Effect of humidity and pressure on the triboelectric nanogenerator, Nano Energy, 2, 604 (2013)

15.  R.S. Yang, One-Dimensional Nanostructures by Pulsed Laser Ablation, Science of Advanced Materials, 4, 401 (2012)

16.  R. Zhu, W. G. Zhang, R. S. Yang, High Output Piezoelectric Nanogenerator: Development and Application, Sci Adv Mater 4, 798 (2012)

17.  Y. Cheng, R. Yang, J.-P. Zheng, Z. L. Wang, P. Xiong, Characterizing individual SnO2 nanobelt field-effect transistors and their intrinsic responses to hydrogen and ambient gases, Mater Chem Phys, 137, 372 (2012)

18.  G. Zhu, Y.S. Zhou, S.H. Wang, R.S. Yang, Y. Ding, X. Wang, Y. Bando, Z.L. Wang, Synthesis of vertically aligned ultra-long ZnO nanowires on heterogeneous substrates with catalyst at the root, Nanotechnology, 23, 055604 (2012)

19.  H. L. Zhang, C. G. Hu, M. C. Zhang, R. S. Yang, C. H. Zheng, Synthesis of BaCO3 Nanowires and Their Humidity Sensitive Property, J. of Nanosci. and Nanotechno. 11, 10706 (2011)

20.  Q.N. Yi, C.G.Hu, R.S. Yang, H. Liu, B.Y. Wan, Y. Zhang, Preparation of WO3 network squares for ultrasensitive photodetectors, J. Alloys Compd. 509, L255–L261 (2011)

21.  Y. Xi, D. H. Lien, R.S. Yang, C. Xu , and C. G. Hu, Direct-current nanogenerator based on ZnO nanotube arrays, Phys. Status Solidi RRL, 5, 77-79 (2011)

22.  M. Lee*, R.S. Yang*, (*equally contributed) C. Li, and Z.L. Wang, Nanowire-Quantum Dot Hybridized Cell for Harvesting Sound and Solar Energies,  J. Phys. Chem. Lett., 1, 2929–2935 (2010)

23.  S. Xu , C. Xu , Y. Liu , Y.F. Hu , R.S. Yang, Q. Yang , J.H. Ryou, H.J. Kim , Z. Lochner , S. Choi , R. Dupuis, and Z.L. Wang, Ordered Nanowire Array Blue/Near-UV Light Emitting Diodes, Adv. Mater., 22, 4749 (2010)

24.  Z.L. Wang, R.S. Yang, J. Zhou, Y. Qin, C. Xu, Y.F. Hu, S. Xu, Lateral nanowire/nanobelt based nanogenerators, piezotronics and piezo-phototronics, Mater. Sci. Eng. R, , 70, 320 (2010)

25.  G. Zhu*, R.S. Yang*, (*equally contributed) S.H. Wang, and Z.L. Wang, Flexible High-Output Nanogenerator Based on Lateral ZnO Nanowire Array, Nano Lett., 10, 3151, (2010)

26.  B.J. Hansen, Y. Liu, R.S. Yang, and Z.L. Wang, Hybrid Nanogenerator for Concurrently Harvesting Biomechanical and Biochemical Energy, ACS Nano, 4, 3647, (2010)

27.  Z. Li, G. Zhu, R.S. Yang, A.C. Wang, and Z.L. Wang, Muscle Driven In-Vivo Nanogenerator Adv. Mater., 22, 2534, (2010)

28.  S. Xu, Y. Qin, C. Xu, Y.G. Wei, R.S. Yang and Z.L. Wang, Self-powered nanowire devices, Nat. Nanotechnol., 5, 366, (2010)

29.  Y. Xi, C.G. Hu, C. Zheng, H. Zhang, R.S. Yang and Y. Tian, Optical switches based on CdS single nanowire, Mater. Res. Bull., 45, 1476, (2010)

30.  Y. Xi, C.G. Hu, P.X. Gao, R.S. Yang, X. He, X. Wang and B. Wan, Morphology and phase selective synthesis of CuxO (x = 1, 2) nanostructures and their catalytic degradation activity, Mater. Sci. Eng., B, 166, 113 (2010).

31.  Y. Xi, J.H. Song, S. Xu, R.S. Yang, Z.Y. Gao, C.G. Hu and Z.L. Wang, Growth of ZnO nanotube arrays and nanotube based piezoelectric nanogenerator, J. Mater. Chem., 19, 9260, (2009).

32.  S. Singamaneni, M. Gupta, R.S. Yang, M.M. Tomczak, R.R. Naik, Z.L. Wang and V.V. Tsukruk, Nondestructive In Situ Identification of Crystal Orientation of Anisotropic ZnO Nanostructures, ACS Nano., 3, 2593 (2009).

33.  R.S. Yang, Y. Qin, C. Li, G. Zhu, Z.L. Wang, Converting Biomechanical Energy into Electricity by a Muscle-Movement-Driven Nanogenerator, Nano Lett., 9, 1201 (2009)

34.  R.S. Yang, Y. Qin, C. Li, Z.L. Wang, and L.M. Dai, Characteristics of Output Voltage and Current of Integrated Nanogenerators, Appl. Phys. Lett., 94,022905 (2009)

35.  R.S. Yang, Y. Qin, L.M. Dai and Z.L. Wang, Power Generation with Laterally-packaged Piezoelectric Fine Wires, Nature Nanotechnology, 4, 34 (2009)

36.  Z. Li, R.S. Yang, M. Yu, F. Bai, C. Li and Z.L. Wang, Cellular Level Biocompatibility and Biosafety of ZnO Nanowires, J. Phys. Chem. C, 112, 20114 (2008)

37.  Y. Qin, R.S. Yang, and Z.L. Wang, Growth of Horizontal ZnO Nanowire Arrays on Any Substrate , J. Phys. Chem. C, 112, 18734 (2008)

38.  Y. Cheng, P. Xiong, C.S. Yun, G.F. Strouse, J.P. Zheng, R.S. Yang, and Z.L. Wang, Mechanism and Optimization of pH Sensing Using SnO2 Nanobelt Field Effect Transistors, Nano Lett., 8, 4179 (2008)

39.  S. Xu, Y.G. Wei, J. Liu, R.S. Yang, and Z.L. Wang, Integrated Multil[ant]ayer Nanogenerator Fabricated Using Paired Nanotip-to-Nanowire Brushes, Nano Lett., 8, 4027 (2008).

40.  J. Zhou, P. Fei, Y.D. Gu, W.J. Mai, Y.F. Gao, R.S. Yang, G. Bao, and Z.L. Wang, Piezoelectric-Potential-Controlled Polarity-Reversible Schottky Diodes and Switches of ZnO Wires, Nano Lett., 11. 3973 (2008).

41.  J. A. Corno, J. Stout, R.S. Yang, and J. L. Gole, Diffusion-Controlled Self-Assembly and Dendrite Formation in Silver-Seeded Anatase Titania Nanospheres, J. Phys. Chem. C, 112, 5439 (2008).

42.  A. Qin, Z. Li, R.S. Yang, Y.D. Gu, Y.Z. Liu and Z.L. Wang, Rapid Photoresponse of Single-crystalline Selenium Nanobelts, Solid State Commun., 148, 145 (2008).

43.  J. Zhou, Y.D. Gu, P. Fei, W.J. Mai, Y.F. Gao, R.S. Yang, G. Bao and Z.L. Wang, Flexible Piezotronic Strain Sensor, Nano Lett., 8,3035 (2008)

44.  C.Y. Xu, L. Zhen, R.S. Yang and Z. L. Wang, Synthesis of Single-Crystalline Niobate Nanorods via Ion-Exchange Based on Molten-Salt Reaction, J. Am. Chem. Soc., 129, 15444 (2007).

45.  L.Q. Mai, B. Hu, W. Chen, Y.Y. Qi, C.S. Lao, R.S. Yang and Z.L. Wang, Lithiated MoO3 Nanobelts with Greatly Improved Performance for Lithium Batteries, Adv. Mater., 19, 3712 (2007).

46.  Z.W. Zhang, C.G. Hu, Y.F. Xiong, R.S. Yang and Z.L. Wang, Synthesis of Ba-doped CeO2 Nanowires and Their Application as Humidity Sensors, Nanotechnology, 18, 465504 (2007).

47.  R.S. Yang, Z.L. Wang, Growth of Self-assembled ZnO Nanowire Arrays, Phil. Mag.，87，2097 (2007).

48.  M. Lucas, W.J. Mai, R.S. Yang, Z.L. Wang and E. Riedo, Size Dependence of the Mechanical Properties of ZnO Nanobelts, Phil. Mag., 87, 2135 (2007).

49.  M. Lucas, W.J. Mai, R.S. Yang, Z.L. Wang, E. Riedo, Aspect Ratio Dependence of the Elastic Properties of ZnO Nanobelts, Nano Lett., 7，1314 (2007).

50.  R.S. Yang, Y.L. Chueh, J.R. Morber, R. Snyder, L.J. Chou, and Z.L. Wang Single-crystalline Branched Zinc Phosphide Nanostructures: Synthesis, Properties, and Optoelectronic Devices, Nano Lett., 7, 269 (2007).

51.  Y. Cheng, P. Xiong, L. Fields, J.P. Zheng, R.S. Yang and Z.L. Wang, Intrinsic Characteristics of Semiconducting Oxide Nanobelt Field-effect Transistors, Appl. Phys. Lett., 89, 093114 (2006).

52.  J. Zhou, J. Liu, R.S. Yang, C.S. Lao, P.X. Gao, R. Tummala, N.S. Xu, and Z.L. Wang SiC-shell Nanostructures Fabricated by Replicating ZnO Nano-objects: a Technique for Producing Hollow Nanostructures of Desired Shape, Small, 2, 1344 (2006).

53.  Y. Ding, R.S. Yang and Z.L. Wang, Ordered Zinc-vacancy Induced Zn0.75Ox Nanophase Structure, Solid State Commun., 138, 390 (2006).

54.  J.L. Gole, S.M. Prokes, J.D. Stout, O.J. Glembocki, and R.S. Yang, Unique Properties of Selectively Formed Zirconia Nanostructures, Adv. Mater., 18, 664 (2006).

55.  J.H. He, R.S. Yang, Y.L. Chueh, L.J. Chou, L.J. Chen, and Z.L. Wang, Aligned AlN Nanorods with Multi-tipped Surfaces-Growth, Field-emission, and Cathodoluminescence Properties, Adv. Mater., 18, 650 (2006).

56.  R.S. Yang and Z.L. Wang, Springs, Rings and Spirals of Rutile Structured Tin Oxide Nanobelts, J. Am. Chem. Soc., 128, 1466 (2006).

57.  C.S. Lao, P.X. Gao, R.S. Yang, Y. Zhang, Y. Dai, Z.L. Wang, Formation of Double-side Teethed Nanocombs of ZnO and Self-catalysis of Zn-terminated Polar Surface, Chem. Phys. Lett., 417, 358 (2006).

58.  R.S. Yang and Z. L. Wang, Interpenetrative and Transverse Growth Process of Self-catalyzed ZnO Nanorods, Solid State Commun., 137, 741 (2005).

59.  J. Zhou, L. Gong, S.Z. Deng, J. Chen, J.C. She, N.S. Xu, R.S. Yang and Z.L. Wang, Growth and Field-emission Property of Tungsten Oxide Nanotip Arrays, Appl. Phys. Lett., 87, 223108 (2005).

60.  Z. L. Wang, X. Y. Kong, Y. Ding, P. Gao, W. L. Hughes, R.S. Yang and Y. Zhang, Semiconducting and Piezoelectric Oxide Nanostructures Induced by Polar Surfaces, Adv. Funct. Mater., 14, 943 (2004).

61.  R.S. Yang, Yong Ding, and Z. L. Wang, Deformation-free Single-crystal Nanohelixes of Polar Nanowires, Nano Lett., 4, 1309 (2004).

62.  X.Y. Kong, Y. Ding, R.S. Yang, and Z.L. Wang, Single-crystal Nanorings Formed by Epitaxial Self-coiling of Polar-nanobelts, Science, 303, 1348 (2004). Being cited among the top one-tenth of one percent (0.1%) in a current bimonthly period and featured as Hot Paper in Chemistry by ISI Essential Science Indicators Web on May 1, 2006

63.  X.Q. Wang, R.S. Yang, S.R. Yang, J.Z. Wang, X.J. Li, J.Z. Yin, H.C. Ong, X.Y. Jiang, C.X. Gao, and G.T. Du, Growth of ZnO Film by Plasma-assisted MOCVD , Chem. J. of Chinese Univ. 23, 927 (2002).

64.  H.D. Li, K.T. Yue, Z.L. Lian, Y. Zhan, L.X. Zhou, S.L. Zhang, Z.J. Shi, 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, Appl. Phys. Lett., 76, 2053 (2000).

65.  B.B. Liu, T. Wagberg, E.B. Nyeanchi, T.L. Makarova, X.M. Zhu, B. Sundqvist, R.S. Yang, D. Li, C. Gao, H. Yang, G. Zou, H.D. Li, and E. Olsson, Synthesis and Characterization of Single-Walled Nanotubes and Nanoparticles Produced with Ce or Eu as Catalysts , Molecular Materials, 13, 75 (2000).

66.  B.B. Liu, T. Wagberg, E. Olsson, R.S. Yang, H.D. Li, S.L. Zhang, H.B. Yang, G.T. Zou, and B. Sundqvist, Synthesis and Characterization of Single-walled Nanotubes Produced with Ce/Ni as Catalysts, Chem. Phys. Lett., 320, 365 (2000).

qingsheng

2019自然科学基金面上项目-二苯丙氨酸二肽纳米材料的可控生长和机电特性研究
批准号        51973170        学科分类        ( )
项目负责人        杨如森        负责人职称                依托单位        西安电子科技大学
资助金额        62.00万元        项目类别        面上项目        研究期限        2019 年 09 月 08 日 至2019 年 09 月 08 日

maixi

西安电子科技大学先进材料与纳米科技学院杨如森教授团队，联合以色列特拉维夫大学Ehud Gazit教授团队，对压电肽材料和可新陈代谢材料的最新研究进展进行了全面系统的总结。相关综述文章以“Piezoelectric Peptide and Metabolite Materials”为题发表在期刊Research上，并被Science期刊官方微信公众号报道。杨如森教授指导的博士研究生袁慧为第一作者、西安电子科技大学为第一单位。

      近年来，越来越多的可人工合成生物材料，包括肽和可新陈代谢材料展示出显著的压电性能。他们不仅具有显著的压电、光学和物理性能，还具有生物兼容性、生物可降解性和易于生物功能化等优点，在多功能和可植入体内器件上具有潜在的应用价值和前景。而这些性能与其自组装方式和晶体结构息息相关，因此，了解他们的自组装机理、性质和应用具有举足轻重的作用。
      文章重点分析和对比了不同晶体结构与压电性能的关系，进一步归纳总结了提高压电性能的方法，并延伸出其在纳米发电机等器件上的实际应用。通过密度泛函理论（DFT）计算对比了不同肽和可新陈代谢材料的禁带宽度，进而总结出其种类和导电性能的关系；通过分析肽和可新陈代谢材料的不同荧光特性和光波导性能，从而引申出其在癌细胞传感和探测等领域的实际应用；通过对比不同材料的热稳定性和机械稳定性，从而提出其在柔性传感器和纳米发电机上的应用前景。最后，文中针对肽和可新陈代谢材料所面临的挑战进行分析，提出了可行的解决方法，并为该材料未来的发展指明了方向。
       据悉，Research作为Science自1880年创建以来第一本合作期刊，通过Science的高影响力国际化传播平台和丰富的国际化高端学术资源，正在快速提高期刊的国际知名度和影响力。Research现已被DOAJ、PMC、CSCD、Scopus等数据库收录。
      相关报道链接：https://mp.weixin.qq.com/s/3ovLq48wS1LBQTmMPM9Yyg
      论文原文链接：https://spj.sciencemag.org/research/2019/9025939/