[1] G. D. M. Jeffries, J. S. Edgar,Y. Zhao et al.. Using polarization-shaped optical vortex traps for single-cell nanosurgery[J]. Nano. Lett., 2007, 7(2): 415~420
[2] K. I. Willig, J. Keller, M. Bossi et al.. STED microscopy resolves nanoparticle assemblies[J]. New J. Phys., 2006, 8(106): 1~8
[4] P. L.Greene, D. G. Hall. Diffraction characteristics of the azimuthal Bessel-Gauss beam[J]. J. Opt. Soc. Am. A, 1996, 13(5): 962~966
[5] P. L.Greene, D. G. Hall. Properties and diffraction of vector Bessel-Gauss beams[J]. J. Opt. Soc. Am. A, 1998, 15(12): 3020~3027
[6] C. J. R. Sheppard, H. J. Matthews. Imaging in a high aperture optical systems[J]. J. Opt. Soc. Am. A, 1987, 4(8): 1354~1360
[7] B. Richards, E. Wolf. Electromagnetic diffraction in optical systems II. Structure of the image field in an aplanatic system[J]. Proc. Roy. Soc. A, 1959, 253: 358~379
[8] D. P. Biss, T. G. Brown. Cylindrical vector beam focusing through a dielectric interface[J]. Opt. Express, 2001, 9(10): 490~497
[9] Qiwen Zhan, J. R. Leger. Focus shaping using cylindrical vector beams[J]. Opt. Express, 2002, 10(7): 324~331
[10] D. P. Biss, T. G. Brown. Primary aberrations in focused radially polarized vortex beams[J]. Opt. Express, 2004, 12(3): 383~393
[11] K. S. Youngworth, T. G. Brown. Focusing of high numerical aperture cylindrical-vector beams[J]. Opt. Express, 2000, 7(2): 77~87
[12] Rebecca H. Jordan, Dennis G. Hall. Free-space azimuthal paraxial wave equation: the azimuthal Bessel-Gauss beam solution[J]. Opt. Lett., 1994, 19(7): 427~429
[13] R. Kant. An analytical solution of vector diffraction for focusing optical systems with Seidel aberrations I. Spherical aberration, curvature of field, and distortion[J]. J. Mod. Opt., 1993, 40(11): 2293~2310