基本情况
姓 名：孙少东
出生年月：1981.12
职 称：教授/硕士生导师
毕业院校：西安交通大学
邮 箱：sdsun@xaut.edu.cn
个人主页：http://js.xaut.edu.cn/web/sdsun/
学习与工作情况
2000.09-2007.04 西安理工大学材料科学与工程学院 学士/硕士
2007.09-2011.03 西安交通大学理学院 博士
2011.04-2014.12 西安交通大学理学院 透射电子显微镜工程师
2015.01-2016.01 新加坡国立大学 博士后
2017.07~至今 西安理工大学材料科学与工程学院 教授
研究方向
1.面向环境保护和清洁燃料开发的光催化材料的设计、可控构筑与相关机理研究。
① 光催化降解污染物（污水处理和有害气体处理）；
② 光解水制氢气；
③ 光还原CO2转化。
2.非贵金属SERS材料的可控合成与机理研究。
3.电化学生物传感材料的设计合成与应用探究。
荣誉奖励
1. 2016年陕西省科学技术奖（二等奖）
2. 2015年陕西省高等学校科学技术奖（一等奖）
科研项目
1. 国家自然科学基金项目，**，主持，结题
2. 教育部博士点基金新教师启动项目，051，主持，结题
3. 陕西省自然科学基金，2012JQ6007，主持，结题
代表性论文
[62]Shaodong Sun,* Xin Zhang, Jie Cui, Qing Yang and Shuhua Liang*,High-index faceted metal oxide micro-/nanostructures: a review on their characterization, synthesis and applications.Nanoscale, 2019, 11, 15739.
[61] Haoqi Ren, Jie Cui andShaodong Sun,* Water-guided synthesis of well-defined inorganic micro-/nanostructures,Chemical Communications, 2019, 55, 9418.
[60]Shaodong Sun,* Peng Song, Jie Cui and Shuhua Liang,* Amorphous TiO₂ nanostructures: synthesis, fundamental properties and photocatalytic applications,Catalysis Science & Technology, 2019, 9, 4198.
[59]Shaodong Sun,* Xin Zhang, Jie Cui, Qing Yang, and Shuhua Liang*, Tuning interfacial Cu–O atomic structures for enhanced catalytic applications,Chemistry-An Asian Journal, 2019, 14, 2912.
[58]Shaodong Sun,* Xiaojing Yu,* Qing Yang, Shuhua Liang*, and Zhimao Yang, Mesocrystals for photocatalysis: A comprehensive review on synthetic engineering and functional modifications,Nanoscale Advances, 2019, 1, 34.
[57]Peng Song, Shuhua Liang,* Jie Cui, Dong Ren, Ruyan Duan, Qing Yang andShaodong Sun*,Purposefully designing novel hydroxylated and carbonylated melamine towards the synthesis of targeted porous oxygen-doped g-C₃N₄ nanosheets for highly enhanced photocatalytic
hydrogen production,Catalysis Science & Technology, 2019, 9, 5150.
[56] Shaodong Sun,* Xufeng Gou, Shasha Tao, Jie Cui, Jia Li, Qing Yang, Shuhua Liang* and Zhimao Yang, Mesoporous graphitic carbon nitride (g-C₃N₄) nanosheets synthesized from carbonated beverage-reformed commercial melamine for enhanced photocatalytic hydrogen evolution,Materials Chemistry Frontiers, 2019, 3, 597.
[55]Shaodong Sun*, Jia Li, Jie Cui, Xufeng Gou, Qing Yang, Yihui Jiang, Shuhua Liang*, Zhimao Yang,Simultaneously engineering K-doping and exfoliation into graphitic carbon nitride (g-C₃N₄) for enhanced photocatalytic hydrogen production,International Journal of Hydrogen Energy, 2019, 44, 778.
[54]Shaodong Sun,* Xiaojing Zhang, Qing Yang, Shuhua Liang,* Xiaozhe Zhang, Zhimao Yang*, Cuprous oxide (Cu₂O) crystals with tailored architectures: A comprehensive review on synthesis, fundamental properties, functional modifications and applications,Progress in Materials Science, 2018, 96, 111. (2016-2017年影响因子31.140)
[53] Haoqi Ren,Shaodong Sun,* Jie Cui and Xifei Li,* Synthesis, functional modifications and diversified applications of micro/nanostructured molybdenum oxide: A review,Crystal Growth & Design, 2018, 18, 6236.
[52] Qing Yang*, Leilei Zhang, Xiaohong Zhou,Shaodong Sun and Shuhua Liang, Porous/dense ZnO bilayer films grown by thermal oxidation of ZnS film with gallium,Vacuum, 2018, 153, 96.
[51] Wen Zhou, Qing Yang,*Shaodong Sun and Shuhua Liang, Effect of thermal oxidation on microstructures and mechanical properties of nanoporous coppers,Science ChinaTechnological Sciences, 2018, 61, https://doi.org/10.1007/s11431-018-9304-8.
[50] Shuhua Liang,* Xufeng Gou, Jie Cui, Yongguang Luo, Hongtao Qu, Te Zhang, Zhimao Yang, Qing Yang andShaodong Sun*, Novel cone-like ZnO mesocrystals with coexposed (101ˉ1) and (0001ˉ) facets and enhanced photocatalytic activity,Inorg. Chem. Front.,2018, 5, 2257.
[49]Shaodong Sun,* Jia Li, Jie Cui, Xufeng Gou, Qing Yang, Shuhua Liang,* Zhimao Yang and Jianmin Zhang, Constructing oxygen-doped g-C3N4 nanosheets with an enlarged conductive band edge for enhanced visible-light-driven hydrogen evolution,Inorg. Chem. Front., 2018, 5, 1721.
[48] Jie Cui, Shuhua Liang,*Shaodong Sun, Xing Zheng and Jianmin Zhang, Enhanced photocatalytic property of hybrid graphitic C3N4 and graphitic ZnO nanocomposite: the effects of interface and doping,J. Phys.: Condens. Matter,2018, 30,175001.
[47] Xufeng Gou,Shaodong Sun,* Qing Yang, Pengju Li, Shuhua Liang,* Xiaojing Zhang and Zhimao Yang*, A very facile strategy for the synthesis of ultrathin CuO nanorods towards non-enzymatic glucose sensing,New J. Chem.,2018, 42, 6364.
[46]Shaodong Sun*, Qing Yang, Shuhua Liang* and Zhimao Yang*, Hollow CuxO (x = 2, 1) micro/nanostructures: synthesis, fundamental properties and applications,CrystEngComm, 2017,19, 6225.
[45]Shaodong Sun* and Shuhua Liang*, Morphological zinc stannate: synthesis, fundamental properties and applications,Journal of Materials Chemistry A, 2017, 5, 20534.
[44]Shaodong Sun*, Pengju Li, Shuhua Liang* and Zhimao Yang*, Diversified copper sulfide (Cu2?xS) micro-/nanostructures: a comprehensive review on synthesis, modifications and applications,Nanoscale, 2017, 9, 11357.
[43]Shaodong Sun* and Shuhua Liang*, Recent advances in functional mesoporous graphitic carbon nitride (mpg-C3N4) polymers,Nanoscale, 2017, 9, 10544.
[42]Sun SD. Recent advances in hybrid Cu2O-based heterogeneous nanostructures,Nanoscale, 2015, 7, 10850.
[41]Sun SD, Sun YX, Chen AR, Zhang XZ, Yang ZM. Nanoporous copper oxide ribbon assembly of free-standing nanoneedles as biosensors for glucose,Analyst, 2015, 140, 5205.
[40] Tang LL, Du YH, Kong CC,Sun SD, Yang ZM. One-pot synthesis of etched Cu2O cubes with exposed {110} facets with enhanced visible-light-driven photocatalytic activity,Phys. Chem. Chem. Phys.,2015, 17, 29479.
[39]Sun SD, Yang ZM. Cu2O-templated strategy for synthesis of definable hollow architectures,Chem. Commun., 2014, 50, 7403.
[38]Sun SD, Yang ZM. Recent advances in tuning crystal facets of polyhedral cuprous oxide architectures,RSC Adv.,2014, 4, 3804.
[37]Sun SD, Zhang HJ, Tang LL, Zhang XZ, Yang ZM. One-pot fabrication of novel cuboctahedral Cu2O crystals enclosed by anisotropic surfaces with enhancing catalytic performance,Phys. Chem. Chem. Phys.,2014, 16, 20424.
[36] Zhang XZ,Sun SD, Lv J, Tang LL, Kong CC, Song XP, Yang ZM. Nanoparticle-aggregated CuO nanoellipsoids for high-performance non-enzymatic glucose detection,J. Mater. Chem. A, 2014, 2, 10073.
[35] Zhang YX,Sun SD, Zhang XZ, Tang LL, Song XP, Ding BJ, Yang ZM. Magnetic field controlled particle-mediated growth inducing icker-like silver architectures,Chemical Engineering Journal, 2014, 240, 494.
[34] Kong CC, Tang LL, Zhang XZ,Sun SD, Yang SC, Song XP, Yang ZM. Templating synthesis of hollow CuO polyhedron and its application for nonenzymatic glucose detection,J. Mater. Chem. A, 2014, 2, 7306.
[33] Zhang YX,Sun SD, Zhang XZ, Tang LL, Song XP, Yang ZM. Sulfate-ion-assisted galvanic replacement tuning of silver dendrites to highly branched chains for effective SERS,Phys. Chem. Chem. Phys., 2014, 2014, 16, 18918.
[32] Tang LL, Lv J,Sun SD, Zhang XZ, Kong CC, Yang ZM, Song XP. Facile hydroxyl-assisted synthesis of morphological Cu2O architectures and their shape-dependent photocatalytic performances,New J. Chem., 2014, 38, 4656.
[31] Kong CC, Lv J,Sun SD, Song XP, Yang ZM. Copper-templated synthesis of gold microcages for sensitive surface-enhanced Raman scattering activity,RSC Adv.,2014, 4, 27074.
[30]Sun SD, Zhang XZ, Sun YX, Yang SC, Song XP, Yang ZM. Facile water-assisted synthesis of cupric oxide nanourchins and their application as nonenzymatic glucose biosensor,ACS Appl. Mater. Interfaces, 2013, 5, 4429.
[29]Sun SD, Deng DC, Song XP, Yang ZM. Elucidating a twin-dependent chemical activity of hierarchical copper sulfide nanocages,Phys. Chem. Chem. Phys.,2013, 15, 15964.
[28]Sun SD,Zhang XZ, Sun YX, Yang SC, Song XP, Yang ZM. Hierarchical CuO nanoflowers: water-required synthesis and their application in a nonenzymatic glucose biosensor,Phys. Chem. Chem. Phys.,2013, 15, 10904.
[27]Sun SD, Wang SRL, Deng DC, Yang ZM. Formation of hierarchically polyhedral Cu7S4 cages from Cu2O templates and their structure-dependent photocatalytic performances,New J. Chem.,2013, 37, 3679.
[26]Sun SD, Zhang XZ, Sun YX, Zhang J, Yang SC, Song XP, Yang ZM. A facile strategy for the synthesis of hierarchical CuO nanourchins and their application as non-enzymatic glucose sensors,RSC Adv.,2013, 3, 13712.
[25]Sun SD, Zhang XZ, Zhang J, Wang LQ, Song XP, Yang ZM. Surfactant-free CuO mesocrystals with controllable dimensions: green ordered-aggregation-driven synthesis, formation mechanism and their photochemical performances,CrystEngComm, 2013, 15, 867. (Inside Cover)
[24]Sun SD, Sun YX, Zhang XZ, Zhang HJ, Song XP, Yang ZM. A surfactant-free strategy for controllable growth of hierarchical copper oxide nanostructures,CrystEngComm, 2013, 15, 5275.
[23] Kong CC,Sun SD, Zhang XZ, Song XP, Yang ZM. Nanoparticle-aggregated hollow copper microcages and their surface-enhanced Raman scattering activity,CrystEngComm, 2013, 15, 6136.
[22] Liang JY, Wang L, He L,Sun SD. Pyridine-containing block copolymer/silica core–shell nanoparticles for one-step preparation of superhydrophobic surfaces,Phys.Chem. Chem. Phys.,2013, 15, 10921.
[21]Sun SD, Zhang XZ, Zhang J, Song XP, Yang ZM. Unusual designated-tailoring on zone-axis preferential growth of surfactant-free ZnO mesocrystals,Cryst. Growth Des.,2012, 12, 2411.
[20]Sun SD, Deng DC, Song XP, Kong CC, Yang ZM. Twins in polyhedral 26-facet Cu7S4 cages: Synthesis, characterization and their enhancing photochemical activities,Dalton Trans.,2012, 41, 3214.
[19]Sun SD, Song XP, Sun YX, Deng DC, Yang ZM. The crystal-facet-dependent effect of polyhedral Cu2O microcrystals on photocatalytic activity,Catal. Sci. Technol.,2012, 2, 925.
[18]Sun SD, Song XP, Deng DC, Zhang XZ, Yang ZM. Nanotwins in polycrystalline Cu7S4 cages: highly active architectures for enhancing photocatalytic activities,Catal. Sci. Technol.,2012, 2, 1309.
[17]Sun SD, Zhang XZ, Song XP, Liang SH, Wang LQ, Yang ZM. Bottom-up assembly of hierarchical Cu2O nanospheres: controllable synthesis, formation mechanism and enhanced photochemical activities,CrystEngComm, 2012, 14, 3545.
[16]Sun SD, Song XP, Deng DC, Kong CC, Yang ZM. Copper sulfide cages wholly exposed with nanotwinned building blocks,CrystEngComm, 2012, 14, 67.
[15]Sun SD, Kong CC, You HJ, Song XP, Ding BJ, Yang ZM. Facet-selective growth of Cu–Cu2O heterogeneous architectures. CrystEngComm, 2012, 14, 40. (Front Cover)
[14] Kong CC,Sun SD, Zhang J, Zhao HD, Song XP, Yang ZM. Nanocube-aggregated cauliflower-like copper hierarchical architectures: synthesis, growth mechanism and electrocatalytic activity,CrystEngComm, 2012, 14, 5737.
[13] Zhang YX,Sun SD, Deng DC, Song XP, Ding BJ, Yang ZM. Electrochemical deposition mediated growth of hierarchical Au architectures and the applications for SERS,CrystEngComm, 2012, 14, 656.
[12]Sun SD, Kong CC, Yang SC, Wang LQ, Song XP, Ding BJ, Yang ZM. Highly symmetric polyhedral Cu2O crystals with controllable-index planes,CrystEngComm, 2011, 13, 2217.
[11]Sun SD, Deng DC, Kong CC, Gao Y, Yang SC, Song XP, Ding BJ, Yang ZM. Seed-mediated synthesis of polyhedral 50-facet Cu2O architectures,CrystEngComm, 2011, 13, 5593. (Front Cover)
[10]Sun SD, Zhang H, Song XP, Liang SH, Kong CC, Yang ZM. Polyhedron-aggregated multi-facet Cu2O homogeneous structures,CrystEngComm, 2011, 13, 6040.
[9]Sun SD, Song XP, Kong CC, Yang ZM. Selective-etching growth of urchin-like Cu2O architectures,CrystEngComm, 2011, 13, 6616.
[8]Sun SD, You HJ, Kong CC, Song XP, Ding BJ, Yang ZM. Etching-limited branching growth of cuprous oxide during ethanol-assisted solution synthesis,CrystEngComm, 2011, 13, 2837.
[7]Sun SD, Song XP, Kong CC, Liang SH, Ding BJ, Yang ZM. Unique polyhedral 26-facet CuS hollow architectures decorated with nanotwinned, mesostructural and single crystalline shells,CrystEngComm, 2011, 13, 6200.
[6]Sun SD, Kong CC, Wang LQ, Yang SC, Song XP, Ding BJ, Yang ZM. Nanoparticle-aggregated paddy-like copper dendritic nanostructures,CrystEngComm, 2011, 13, 1916.
[5]Sun SD, Kong CC, Deng DC, Song XP, Ding BJ, Yang ZM. Nanoparticle-aggregated octahedral copper hierarchical nanostructures,CrystEngComm,2011, 13, 63.
[4]Sun SD, Deng DC, Kong CC, Zhang YX, Song XP, Ding BJ, Yang ZM. Magnetic field driven assembly of 1D-aligned silver superstructures,CrystEngComm, 2011, 13, 4827.
[3] Hong F,Sun SD, You HJ, Yang SC, Fang JX, Guo SW, Yang ZM, Ding BJ, Song XP. Cu2O template strategy for the synthesis of structure-definable noble metal alloy mesocages,Cryst. Growth Des.,2011, 11, 3694.
[2]Sun SD, Zhou FY, Wang LQ, Song XP, Yang ZM. Template-free synthesis of well-defined truncated edge polyhedral Cu2O architectures,Cryst. Growth Des.,2010, 10, 541.
[1] Yang ZM,Sun SD, Kong CC, Song XP, Designated-tailoring on {100} facets of Cu2O nanostructures:
From octahedral to its different truncated forms,Journal of nanomaterials, 2010, 710584.
授权专利
1. 孙少东，孔才春，杨志懋，宋晓平，丁秉钧，张晓哲，一种长径比可调的氧化锌介观晶体的制备方法，中国国家发明专利，ZL 7.3
2. 孙少东，杨志懋，张晓哲，孔春才，宋晓平，一种花状纳米氧化铜粉末的制备方法，中国国家发明专利，ZL 8.6
3. 孙少东，孔才春，杨志懋，宋晓平，丁秉钧，一种含有纳米孪晶结构的中空硫化铜晶体的制备方法，中国国家发明专利，ZL 0.2
4. 孙少东，杨志懋，孔才春，杨生春，宋晓平，丁秉钧，一种含高指数晶面包络表面的氧化亚铜单晶粉末制造方法，中国国家发明专利，ZL 7.3
5. 孙少东，孔才春，杨志懋，宋晓平，丁秉钧，一种Cu-Cu2O异质结的制备方法，中国国家发明专利，ZL 6.8.