1. 毕业设计(论文)的内容和要求
原子力显微镜与其他测量方法的结合开辟了广泛的应用领域,从而提供了在横向范围内纳米范围内获得更多样品特性的途径。
代表作,开尔文探针力显微镜(KPFM),最早由Nonnenmacher等人开发。
和韦弗等。
2. 参考文献
1. Hutter E, Fendler JH. Exploitation of localized surface plasmon resonance. Adv Mater2004; 16: 16851706.2. Anker JN, Hall WP, Lyandres O, Shah NC, Zhao J et al. Biosensing with plasmonicnanosensors. Nat Mater 2008; 7: 442453.3. Mrejen M. Near-field imaging probes electromagnetic waves. Laser Focus World 2007;43: 2832.4. Challener WA, Peng CB, Itagi AV, Karns D, Peng W et al. Heat-assisted magneticrecording by a near-field transducer with efficient optical energy transfer. Nat Photon2009; 3: 220224.5. Nagatani N, Tanaka R, Yuhi T, Endo T, Kerman K et al. Gold nanoparticle-based novelenhancement method for the development of highly sensitive immunochromatographictest strips. Sci Technol Adv Mater 2006; 7: 270275.6. Gandra N, Portz C, Nergiz SZ, Fales A, Vo-Dinh T et al. Inherently stealthy and highlytumor-selective gold nanoraspberries for photothermal cancer therapy. Sci Rep 2015;5: 10311.7. Bergman DJ, Stockman MI. Surface plasmon amplification by stimulated emission ofradiation: quantum generation of coherent surface plasmons in nanosystems. Phys RevLett 2003; 90: 027402.8. Noginov MA, Zhu G, Belgrave AM, Bakker R, Shalaev VM et al. Demonstration of aspaser-based nanolaser. Nature 2009; 460: 11101112.9. Apalkov V, Stockman MI. Proposed graphene nanospaser. Light Sci Appl 2014; 3:e191.10. Su CY, Lin CH, Shih PY, Hsieh C, Yao YF et al. Coupling behaviors of surface plasmonpolariton and localized surface plasmon with an InGaN/GaN quantum well. Plasmonics2016; 11: 931939.11. Cho CY, Park SJ. Enhanced optical output and reduction of the quantum-confined Starkeffect in surface plasmon-enhanced green light-emitting diodes with gold nanoparticles.Opt Express 2016; 24: 74887494.12. Lozano G, Rodriguez SRK, Verschuuren MA, Rivas JG. Metallic nanostructures forefficient LED lighting. Light Sci Appl 2016; 5: e16080.13. Pryce IM, Koleske DD, Fischer AJ, Atwater HA. Plasmonic nanoparticle enhancedphotocurrent in GaN/InGaN/GaN quantum well solar cells. Appl Phys Lett 2010; 96:153501.14. Atwater HA, Polman A. Plasmonics for improved photovoltaic devices. Nat Mater 2010;9: 205213.15. Su YH, Ke YF, Cai SL, Yao QY. Surface plasmon resonance of layer-by-layer goldnanoparticles induced photoelectric current in environmentally-friendly plasmon-sensitized solar cell. Light Sci Appl 2012; 1: e14.16. Chen X, Jia BH, Zhang YN, Gu M. Exceeding the limit of plasmonic light trapping intextured screen-printed solar cells using Al nanoparticles and wrinkle-likegraphene sheets. Light Sci Appl 2013; 2: e92.17. Li D B, Sun X J, Jia Y P, et al. Direct observation of localized surface plasmon field enhancement by Kelvin probe force microscopy[J]. Light: Science Applications, 2017, 6(8): e17038.18. Kai C H, Sun X J, Jia Y P, et al. Carrier behavior in the vicinity of pit defects in GaN characterized by ultraviolet light-assisted Kelvin probe force microscopy[J]. SCIENCE CHINA Physics, Mechanics Astronomy, 2019, 62(6): 67311.19. Jiang C S, Mansfield L M, Glynn S, et al. Effect of Window-Layer Materials on pn Junction Location in Cu (In, Ga) Se 2 Solar Cells[J]. IEEE Journal of Photovoltaics, 2018, 9(1): 308-312.20. Li H, Gao Y, Zhou Y, et al. Construction and nanoscale detection of interfacial charge transfer of elegant Z-scheme WO3/Au/In2S3 nanowire arrays[J]. Nano letters, 2016, 16(9): 5547-5552.
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