Transmission Field Study of Optical Microscopy Systems with a Hemisphere Immersion Lens

Zhang Yaoju; Yie Xuehua

[1] Mansfield S M,Kino G S. Solid immersion microscope.Appl Phys Lett,1990,57(24) :2615～2616

[2] Terris B D,Mamin H J,Rugar D,et al. Near-field optical data storage using a solid immerson lens. Appl Phys Lett,1994,65(4):388～390

[3] Karrai K,Lorenz X,Novotny L. Enhanced reflectivity contrast in confocal solid immersion lens microscopy.Appl Phys Lett,2000,77(21) :3459～3461

[4] Wu Q,Feke G D,Grober R D. Realization of numerical aperture 2.0 using a gallium phosphide solid immersion lens. Appl Phys Lett 1999,75(26) :4064～4067

[5] Feng X,He F,Zhang D,et al. Acta Photonica Sinica,2005,34(6):927～930

[6] Ghislain L P,Elings V B. Near-field photolithography with a solid immersion lens. Appl Phys Lett,1999,74(4):501～503

[7] Hewaparakrama K P,Wilson A,Mackowski S,et al.Subwavelength multichannel imaging using a solid immersion lens: Spectroscopy of excitons in single quantum dots. Appl Phys Lett,2004,85(22) :463～5465

[8] Baba,M,Sasaki T,Yoshita M,et al. Aberrations and allowances for errors in a hemisphere solid immersion lens for submicron-resolution photoluminescence microscopy. J Appl Phys,1999,85(9) :923～925

[9] Poweleit C D,Gunther A,Goodnick S. Raman imaging of patterned silicon using a solid immersion lens. Appl Phys Lett,1998,73(16):2275-2277

[10] Koyama K,Yoshita M,Baba M,et al. High collection efficiency in fluorescence microscopy with a solid immersion lens. Appl Phys Lett,1999,75 (12) :1667～1669

[11] Zwiller V,Bj rk G. Improved light extraction from emitters in high refractive index materials using solid immersion tenses. J Appl Phys,2002,92(2) :660-665

[12] Yoshita M,Koyama K,Baba M,et al. Fourier imaging study of efficient near-field optical coupling in solid immersion fluorescence microscopy. J Appl Phys,2002,92(2):862-865

[13] Moehl S,Zhao H,Don B D. Solid immersion lensenhanced nano-photoluminescence: Principle and applications. J Appl Phys,2003,93(10) :6265～6272

[14] Richards B,Wolf E. Electromagnetic diffraction in optical systems II. Structure of the image field in an aplanatic system. ProcRoy Soc A,1959,253:358～379

[15] T r k P,Varga P,Booker G R. Electromagnetic diffraction of light focused through a planar interface between materials of mismatched refractive indices:structure of the electromagnetic field. J Opt Soc Am A,1995,12:2136～2144

[16] Hetseth L E. Roles of polarization,phase and amplitude in solid immersion lens systems. Opt Commun,2001,191:161～172

[17] Guo F,Schlesinger T E,Stancil D D. Optical field study of near-field optical recording with a solid immersion lens. Appl Opt,2000,39(2) :324～332

[18] Lu Y,Xie J,Zhang J,et al. Increase the storage density of solid immersion lens system by high-pass angular spectrum filter method. Opt Commun,2002,203:87～92

[19] Zhang Y,Xiao H,Zhang C. Diffractive super-resolution elements applied to near-field optical data storage with solid immersion lens. New J Phys,2004,6 (75):1～14

[20] Zhang Y,Zhang C,Zou Y. Focal-field distribution of the solid immersion lens system with an annular filter.Optzk,2004,115(6):277～280

[21] Zhang D L,Bai Y L,Feng X Q,et al. Acta Photonica Sinica,2004,33(7):884～888

[22] He F T,Zhang D L,Bai Y L,et at. Acta Photonica Sinica,2005,34(2):276～279