[1] Timp G, Behringer R E, Tennant D M et al.. Using light as lens for submicron neutral-atom lithography. Phys. Rev. Lett., 1992, 69(11):1636～1639

[2] McClelland J J, Scholten R E, Palm E C et al.. Laser-focused atomic deposition. Science, 1993, 262(5135):877～880

[3] Anderson W R, Braadley C C, McClelland J J et al.. Minimizing feature width in atom optically fabricated chromium nanostructures. Phys. Rev. (A), 1999, 59(3):2476～2485

[4] Chang Jae Lee. Quantum-mechanical analysis of atom lithography. Phys. Rev. (A), 2000, 61(6):063604-1～06364-9

[5] Behringer R E, Natarajan V, Timp T. Optimal profile for a Gaussian standing-wave atom-optical lens. Opt. Lett., 1997, 22(2):114～116

[6] McGowan R W, Giltner D M, Lee S A. Light force cooling,focusing, and nanometer-scale deposition of aluminum atoms. Opt. Lett., 1995, 20(24):2535～2537

[7] McClelland J J, Anderson W R, Celotta R J. Nanofabrication via atom optics with chromium. Proc. SPIE, 2995:90～96

[8] Rehse S J, Glueck A D, Lee S A et al.. Nanolithography with metastable neon atoms: Enhanced rate of contaimination resist formation for nanostructure fabrication. Appl. Phys. Lett., 1997, 71(10):1427～1429

[9] Ishkhanyan A M. Diffraction of atoms by a standing wave at Gaussian initial momentum distribution. Phys. Rev. (A), 2000, 61(6):063611-1～063611～6

[10] Yang Benhui, Gao Hongtao, Han Keli. Time-dependent quantum dynamics study of the Cl+H2 reaction. J. Chem. Phys., 2000, 113(4):1434～1440