楊士寬

楊士寬

楊士寬,男,博士,浙江大學材料工程與科學學院百人計畫研究員、博士生導師。

基本介紹

  • 中文名:楊士寬
  • 畢業院校:中國科學院合肥物質科學研究院
  • 學位/學歷:博士
  • 職業:教師
  • 專業方向:金屬仿生微納超表面
  • 就職院校:浙江大學
個人經歷,研究方向,主講課程,學術成果,

個人經歷

於2016年6月加入浙江大學材料科學與工程學院,受聘為正高級職稱研究員。楊士寬博士2009年畢業於中國科學院合肥物質科學研究院,後在德國明斯特大學(2009-2011)及美國賓夕法尼亞州立大學(2011-2016)從事博士後研究工作。

研究方向

金屬仿生微納超表面
SERS感測器
仿生學

主講課程

楊士寬老師致力於指導 碩士&博士&博士後 科研項目及畢業設計等
包含下列研究方向及子課題:
(1)SLIPSERS平台的套用研究;
(2)基於Brochosomes的SERS研究。
(3)模板輔助電化學可控制備多功能微納米材料及感測器件構築;
(4)通過SERS實時檢測建立貴金屬成份和結構與電催化性能的內在關聯。
(5)超親水到超疏水按需調控及在SERS檢測中的套用;
(6)模板法構築電漿-光子晶體強耦合物理體系及新穎光學性能探索。
(7)電致變色材料結構設計;
(8)模板輔助微納結構電化學、濕化學可控合成。
(9)鈣鈦礦納米晶的可控合成與按需摻雜及光學性能研究
(10)無模板法程式化合成微納材料;
(11)SERS性能研究。
(12)電化學製備新型多孔薄膜材料及在柔性器件中的套用探索;
(13)鈣鈦礦納米晶體的製備及套用研究;
(14)新型單一基質白色發光材料的製備和光學性能研究;
(15)全無機鈣鈦礦納米晶的可控合成與光學性能研究等。

學術成果

研究與成果
1. 結合豬籠草啟發的潤滑液浸漬表面,開發了SLIPSERS超靈敏富集-檢測平台,使SERS在有機溶劑中的檢測限最佳化了三個數量級以上(PNAS 2016)。
2. 首次把種子層誘導電化學沉積套用於雙層膠體晶體模板,人工合成了有序網粒體(Brochosome)結構,並揭示了網粒體對蝗蟲的保護功能原理,為未來開發寬波段抗反射圖層指明了方向,在隱身和光熱轉化領域有潛在套用 (Nature Communications 2017)。
3. 發展了模板輔助種子層誘導電化學沉積製備複雜微納功能陣列結構。
4. 在液相雷射燒蝕中引入可控碳化反應,為製備超細(<5 nm)碳化物納米晶和量子環提供了迄今最可靠方案。
5. 探索出了一系列製備高SERS活性襯底的廉價技術,正在環境污染物檢測和生物檢測領域尋找套用。
6. 開創了電化學可控沉積微納分級結構的技術(進行中......)。
發表論文
  1. Y. Liu, L. Zhao, J. Lin, S. Yang*, Electrodeposited Surfaces with Reversibly Switching Interfacial Properties.
  2. Y. Wang, L. Zhao, Y. Zhao, W. Y. Wang, Y. Liu, C. Gu, J. Li, G. Zhang, T. J. Huang, S. Yang*, Electrocarving during Electrodeposition Growth.
  3. X. Dai,* N. Sun, S. O. Nielsen, B. B. Stogin, J. Wang, S. Yang, and T. -S. Wong,* Hydrophilic Directional Slippery Rough Surfaces for Water Harvesting,Science Advances, 2018,
  4. S. Yang,* N. Sun, 2.B. M. Boschitsch, J. Wang, Y. Huang, and T. -S. Wong,* Ultra-antireflective Synthetic Brochosome,Nature Communications, 2017
  5. S. Yang,* X. Dai, B. M. Boschitsch, and T. –S. Wong,*Ultrasensitive Surface-Enhanced Raman Scattering Detection in Common Fluids.Proceedings of the National Academy Sciences, USA,2016, (Top-50 most read articles in Jan, 2016) (highly cited paper);See alsoPenn State News,NSF,ScienceDaily, KurzweilAl, andWikipedia(維基百科)'s explanation of SERS(see Ref. 11 and Ref. 12).
  6. 1. Y. Yu, J. Hou, L. Zhang, Q. Sun, S. Attique, W. Wang, X. Xu, F. Xu, Z. Ci, B. Cao*, X. Qiao*, X. Xiao*,S. Yang*, Ultrastable Laurionite Spontaneously Encapsulates Reduced-dimensional Lead Halide Perovskites,Nano Letters2020, Accepted. (#共同一作)
  7. 1. Y. Liu, L. Zhao, J. Lin,S. Yang*, Electrodeposited Surfaces with Reversibly Switching Interfacial Properties,Science Advances, 2019, 5,
  8. Q. Ding, Y. Kang, W. Li, G. Sun, H. Liu, M. Li, Z. Ye, M. Zhou*, J. Zhou*,S. Yang*,Bioinspired Brochosomes as Broadband and Omnidirectional Surface-Enhanced Raman Scattering Substrates,J. Phys. Chem. Lett.2019, accepted.
  9. X. Zhang, X. Zhang, C. Luo, Z. Liu, Y. Chen, S. Dong, C. Jiang,S. Yang*, F, Wang*, X. Xiao*, Volume-enhanced Raman scattering Detection of Viruses,Small, 2019, ( 封面論文)
  10. L. Zhang, Q. Sun, Y. Xu, L. Han, Q. Wang, Y. Yu, Z. Jin*,S. Yang*,Z. Ci*, Self-assembled Template-Confined Growth of Ultrathin CsPbBr3 Nanowires.Applied Materials Today, 2019, Online.
  11. Y. Wang, L. Zhao, Y. Zhao, W. Y. Wang, Y.Liu, C. Gu, J. Li, G. Zhang, T. J. Huang,S. Yang,* Electrocarving during Electrodeposition Growth.Adv. Mater.2018, . (影響因子21.95;封底論文; #共同一作)
  12. Z. Li, J. Lin, Z. Liu, S. Feng, Y. Liu, C. Wang, Y. Liu,S. Yang,*Durable Broadband and Omnidirectional Ultra-antireflective Surfaces.ACS Appl. Mater. Inter.2018, ACCEPTED. (影響因子8.1)
  13. Q. Sun, C. Ni, Y. Yu, S. Attique, S. Wei, Z. Ci, J. Wang*,S. Yang,*Design Principle of All-inorganic Halide Perovskite-related Nanocrystals.J. Mater. Chem. C.2018, ACCEPTED. (影響因子6.1)
  14. 4. Y. Wang, Y. Yu, Y. Liu,S. Yang,*Template-confiend Site-specific Electrodeposition of Nanoparticle Cluster-in-Bowl Arrays as SERS Substrates.ACS Sensors, 2018, ACCEPTED. (影響因子5.7)
  15. X. Dai*, N. Sun, S. O. Nielsen, B. B. Stogin, J. Wang,S. Yang, and T.-S. Wong*, Hydrophilic Directional Slippery Rough Surfaces for Water Harvesting,Science Advances, 2018, 4, (影響因子11.5)
  16. Y. Wang, Y. Kang, W. Y. Wang, Q. Q. Ding, J. G. Zhou,* andS. Yang,Circumventing Sliver Oxidation Induced Degradation of Surface-Enhanced Raman Scattering Substrates.Nanotechnology, 2018, (影響因子3.4)
  17. 7. Z. Ye,G. Sun, C. Sui, B. Yan, F. Gao, P. Cai, B. Lv, Y. Li, N. Chen, F. Xu, K. Wang, G. Ye,S. Yang,Surface Enhanced Raman Scattering Substrates Prepared by Thermal Evaporation on Liquid Surfaces.Nanotechnology, 2018,
  18. 8. T. Luo, X. Chen, P. Li, P. Wang, C. Li, B. Cao,andS. Yang,Laser Irradiation induced Laminated Graphene/MoS2Composites with Synergistically Improved Tribological Properties.Nanotechnology, 2018,
  19. 9. W. Liu, Y. Hou, Z. Lin,S. Yang,C. Yu, C. Lei, X. Wu, D. He, Q. Jia, G. Zheng, X. Zhang,L. Lei, Porous Cobalt Oxinitrade Nanosheets for Efficient Electrocatalytic Water Oxidation.ChemSusChem, 2018,
  20. S. Yang,N. Sun, B. B. Stogin, J. Wang, Y. Huang, T. S. Wong,Ultra-antireflective Synthetic Brochosomes.Nature Communications, 2017,
  21. Y. Huang, B. B. Stogin, N. Sun, J. Wang,S. Yang, T. S. Wong,A Switchable Cross-species Liquid Repellent Surfaces.Advanced Materials, 2017,
  22. S. Yang,*X. Dai, B. M. Boschitsch, and T. –S. Wong,*Ultrasensitive Surface-Enhanced Raman Scattering Detection in Common Fluids.Proceedings of the National Academy Sciences, USA,2016, .
  23. X. Zhang, Z. Dai, X. Zhang, S. Dong, W. Wu,S. Yang,X. Xiao,C. Jiang, Recent Progress in the Fabrication of SERS Substrates based on the Arrays of Polystyrene Nanospheres. Science China-Physics Mechanics & Astronomy,2016,
  24. S. Yuan, Z. Qiu, H. Zhang, X. Qiu, C. Gao, H. Gong,S. Yang,J. Yu, B. Cao,Growth Temperature-Dependent Performance of Planar CH3NH3PbI3 Solar Cells Fabricated by a Two-step Subliming Vapor Method Below 120 Degree C.RSC Advances,2016,
  25. Y. Xie,S. Yang,Z. Mao, P. Li, C. Zhao, Z. Cohick, P. –H. Huang, and T. J. Huang,* In Situ Fabrication of 3D Ag@ZnO Nanostructures for Microfluidic SERS Systems.ACS Nano, 2014,
  26. S. Yang,* D. Slotcavage, J. D. Mai, W. Liang, Y. Xie, Y. Chen, and T. J. Huang,* Combining the Masking and Scaffolding Modalities of Colloidal Crystal Templates: Plasmonic Nanoparticle Arrays with Multiple Periodicities.Chem. Mater.2014,
  27. S. Yang, M. I. Lapsley, B. Cao, C. Zhao, Y. Zhao, Q. Hao, B. Kiraly, J. Scott, W. Li, L. Wang, Y. Lei,* and T. J. Huang,* Large-Scale Fabrication of Three-Dimensional Surface Patterns Using Template-Defined Electrochemical Deposition.Adv. Funct. Mater.2013,
  28. S. Yang,B. Kiraly, W. Y. Wang, S. Shang, B. Cao, H. Zeng, Y. Zhao, W. Li, Z. K. Liu, W. P. Cai,* and T. J. Huang,* Fabrication and Characterization of SiC Quantum Rings with Anomalous Red Spectral Shift Using Laser Ablation in Liquid.Adv. Mater.2012,
  29. S. Yang,F. Xu, S. Ostendorp, G. Wilde, H. Zhao, and Y. Lei,* Template-Confined Dewetting Process to Surface Nanopatterns: Fabrication, Structural Tunability, and Structure-Related Properties.Adv. Funct. Mater.2011,
  30. Y. Lei* (Advisor),S. Yang, M. Wu, and G. Wilde, Surface Patterning Using Templates: Concept, Properties and Device Applications.Chem. Soc. Rev.2011,
  31. S. Yang,W. Cai*, L. Kong, and Y. Lei,* Surface Nanometer-Scale Patterning in Realizing Large-Scale Ordered Arrays of Metallic Nanoshells with Well-Defined Structures and Controllable Properties.Adv. Funct. Mater. 2010,
  32. S. Yang,*D. Slotcavage, J. D. Mai, F. Guo, S. Li, Y. Zhao, Y. Lei, C. E. Cameron, and T. J. Huang,* Electrochemically Created Highly Surface Roughened Ag Nanoplate Arrays for SERS Biosensing Applications.J. Mater. Chem. C2014,
  36. 23.S. Yang,* P. J. Hricko, P. –H. Huang, S. Li, Y. Zhao, Y. Xie, F. Guo, L. Wang, and T. J. Huang,* SERS Sensing Using Janus Particle Arrays Realized by Site-specific Electrochemical Growth.J. Mater. Chem. C2014,
  39. 24.S. Yang, F. Guo, B. Kiraly, X. Mao, M. Lu, K. Leong, and T. J. Huang,* Microfluidics Synthesis of Janus Particles for Biomedical Applications.Lab Chip,2012,
  43. 25. X. Hu, H. Gong, Y. Wang, Q. Chen, J. Zhang, S. Zheng,S. Yang,*and B. Cao,* Laser Induced Reshaping of Irregular Shaped Particles for Energy Saving Applications. J. Mater. Chem.2012,
  44. 26.S. Yang,*and H. Zeng,* Hybrid Architectures: Spherical Au Nanoparticles on Cubic AgCl Sub-Micrometer Particles.Sci. Adv. Mater. 2012,
  45. 27.S. Yang,*H. Zeng, H. Zhao, H. Zhang, and W. Cai*, Luminescent Hollow Carbon Shells and Fullerene-Like Carbon Spheres Induced by Laser Ablation with Toluene. J. Mater. Chem. 2011,
  46. 28.S. Yang,*B. Cao,* L. Kong, and Z. Wang, Template-Directed Dewetting of a Gold Membrane to Fabricate Highly SERS-Active Substrates. J. Mater. Chem. 2011,
  47. 29.S. Yang,*J. Xu, Z. Wang, H. Zeng, and Y. Lei,* Janus Particle Arrays with Multiple Structural Controlling Abilities Synthesized by Seed-Directed Deposition. J. Mater. Chem. 2011,
  48. 30.S. Yang,and Y. Lei,* Recent Progress on Surface Pattern Fabrications Based on Monolayer Colloidal Crystal Templates and Related Applications. Nanoscale 2011,
  49. 31.S. Yang,P. S. Liu,* M. Fang, X. Luo, and W. Cai, Complex Nanostructures Synthesized from Nanoparticle Colloids under an External Electric Field. Nanoscale 2011,
  50. 32.S. Yang,*W. Li, B. Cao, H. Zeng, and W. Cai*, Origin of Blue Emission fromSilicon Nanoparticles: Direct Transition and Interface Recombination.J. Phys. Chem. C2011,
  54. 33.S. Yang, W. Cai*, H. W. Zhang, H. B. Zeng, and Y. Lei,* A General Strategy for Fabricating Unique Carbide Nanostructures with Excitation Wavelength-Dependent Light Emissions. J. Phys. Chem. C 2011,
  55. 34. H. Zeng,*S. Yang,*and W. Cai, Reshaping Formation and Luminescence Evolution of ZnO Quantum Dots by Laser-Induced Fragmentation in Liuqid. J. Phys. Chem. C 2011,
  56. 35.S. Yang,*W. Cai,* H. Zhang, X. Xu, and H. Zeng, Size and Structure Control of Si Nanoparticles by Laser Ablation in Different Liquid Media and Further Centrifugation Classification. J. Phys. Chem. C 2009,
  57. 36.S. Yang,W. Cai*, H. Zeng, and X. Xu, Ultra-fine beta-SiC Quantum Dots Fabricated by Laser Ablation in Reactive Liquid at Room Temperature and Their Violet Emission. J. Mater. Chem. 2009,
  58. 37.S. Yang,W. Cai*, G. Liu, and H. Zeng, From Nanoparticles to Nanoplates: Preferential Oriented Connection of Ag Colloids during Electrophoretic Deposition. J. Phys. Chem. C 2009,
  59. 38.S. Yang, W. Cai,* G. Liu, H. Zeng, and P. Liu, Optical Study of Redox Behavior of Silicon Nanoparticles Induced by Laser Ablation in Liquid. J. Phys. Chem. C 2009,
  60. 39.S. Yang,W. Cai,* J. Yang, and H. Zeng, General and Simple Route to Micro/Nanostructured Hollow-Sphere Arrays Based on Electrophoresis of Colloids Induced by Laser Ablation in Liquid. Langmuir 2009,

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