{"id":21,"date":"2016-04-29T01:40:41","date_gmt":"2016-04-29T01:40:41","guid":{"rendered":"https:\/\/live-optics-wp.pantheonsite.io\/masud\/?page_id=21"},"modified":"2023-08-10T23:29:57","modified_gmt":"2023-08-10T23:29:57","slug":"journal-articles","status":"publish","type":"page","link":"https:\/\/wp.optics.arizona.edu\/masud\/journal-articles\/","title":{"rendered":"Journal Articles"},"content":{"rendered":"
    \n
  1. M. Mansuripur, J.W. Goodman, E.G. Rawson, R.J. Norton, “Fiber optics receiver error rate prediction using the Gram-Charlier series,”<\/a><\/strong>\u00a0IEEE Trans. Comm. 28,<\/b> 402-407 (1980).<\/li>\n
  2. M. Mansuripur,\u00a0 “Magnetization reversal in thin magnetic films with perpendicular anisotropy,”<\/a><\/strong>\u00a0J. Appl. Phys. 53<\/b>, 1660-1663, (1982).<\/li>\n
  3. M. Mansuripur, G.A.N. Connell, and J.W. Goodman, “Laser-induced local heating of multilayers,”<\/a><\/b> Appl. Opt. 21<\/b>, 1106, (1982).<\/li>\n
  4. M. Mansuripur, G.A.N. Connell, and J.W. Goodman,\u00a0“Signal and noise in magneto-optical readout,”<\/a><\/strong>\u00a0J. Appl. Phys. 53<\/b>, 4485 (1982).<\/li>\n
  5. M. Mansuripur and G.A.N. Connell, “Laser induced local heating of moving multilayer media,”<\/a><\/b> Appl. Opt. 22<\/b>, 666, (1983).<\/li>\n
  6. M. Mansuripur, “Orientational effect of the extensional flow field on solutions of rigid rodlike macromolecules-disappearance of the isotropic to nematic phase transition,”<\/a><\/strong> Int. J. Multiphase Flow 9<\/b>, 229 (1983).<\/li>\n
  7. M. Mansuripur and G.A.N. Connell,\u00a0“Thermal aspects of magneto-optical recording,”<\/a><\/strong>\u00a0J. Appl. Phys. 54<\/b>, 4794, (1983).<\/li>\n
  8. G. A. N. Connell, D. Treves, R. Allen, and M. Mansuripur, “Signal-to\u00ad noise ratio for magneto-optic readout from quadrilayer structures,”<\/strong> <\/a>Appl. Phys. Lett. 42<\/b>, 742 (1983).<\/li>\n
  9. M. Mansuripur and G.A.N. Connell,\u00a0“Energetics of domain formation in thermomagnetic recording,”<\/a><\/strong>\u00a0J. Appl. Phys. 55<\/b>, 3049 (1984).<\/li>\n
  10. M. Mansuripur,\u00a0“High-density magneto-optical disk storage and the effect of finite beam-size in readout,”<\/a><\/strong>\u00a0J. Appl. Phys. 56<\/b>, 1165 (1984).<\/li>\n
  11. M. Mansuripur, M.F. Ruane, “Mean-field analysis of amorphous rare earth-transition metal alloys for thermomagnetic recording,”<\/strong> <\/a>IEEE Trans. Mag. 22<\/b>, 33 (1986).<\/li>\n
  12. M. Ruane, M. Mansuripur, and R. Rosenvold, “Measurement of reflectivities for magneto-optical media,”<\/a><\/b> Appl. Opt. 25<\/b>, 1946 (1986).<\/li>\n
  13. P. Wolniansky, S. Chase, R. Rosenvold, M. Ruane, and M. Mansuripur, “Magneto-optical measurements of hysteresis loop and anisotropy energy constants on amorphous TbxFel-x alloys,”<\/a><\/strong>\u00a0\u00a0J. Appl. Phys. 60<\/b>, 346 (1986).<\/li>\n
  14. M. Mansuripur, “Distribution of light at and near the focus of high numerical aperture objectives,”<\/strong> <\/a>J. Opt. Soc. Am. 3<\/b>, 2086 (1986).<\/li>\n
  15. M. Mansuripur, “Figure of merit for magneto-optical media based on the dielectric tensor,”<\/a><\/strong> Appl. Phys. Lett. 49<\/b>, 19 (1986).<\/li>\n
  16. M. Mansuripur,\u00a0\u00a0“Magnetization reversal process, coercivity and the process of thermomagnetic recording in thin films of amorphous rare earth-transition metal alloys,”<\/a><\/strong>\u00a0J. Appl. Phys. 61<\/b>, 1580 (1987).<\/li>\n
  17. M. Mansuripur, “Analysis of astigmatic focusing and push-pull tracking error signals in magneto-optic disk systems,”<\/a><\/b> Appl. Opt. 26<\/b>, 3981 (1987).<\/li>\n
  18. M. Mansuripur,\u00a0\u00a0“Magnetization reversal dynamics in the media of magneto-optical recording,”<\/a>\u00a0<\/b>\u00a0J. Appl. Phys. 63<\/b>, 5809 (1988).<\/li>\n
  19. M. Mansuripur, R. Giles, “Demagnetizing field computation for dynamic simulation of the magnetization reversal process,”<\/strong> <\/a>IEEE Trans. Magnet. 24<\/b>, 2326 (1988).<\/li>\n
  20. M. Mansuripur,\u00a0\u00a0“Demagnetizing field computation for thin films – Extension to the hexagonal lattice,”<\/a>\u00a0<\/b>\u00a0J. Appl. Phys. 66<\/b>, 3731 (1989).<\/li>\n
  21. M. Mansuripur, “On the self magnetostatic energy of jagged domain walls,”<\/a><\/strong>\u00a0J. Appl. Phys. 66<\/b>, 3727 (1989).<\/li>\n
  22. M. Mansuripur,\u00a0“Computation of fields and forces in magnetic force microscopy,”<\/a><\/strong> IEEE Trans Magnet. 25<\/b>, 3467 (1989).<\/li>\n
  23. M. Mansuripur, “Certain computational aspects of vector diffraction problems,”<\/strong> <\/a>J. Opt. Soc. Am. A 6<\/b>, 786 (1989). See also the corresponding erratum in J. Opt. Soc. Am. A 10<\/b>, 382-383 (1993).<\/li>\n
  24. M. Mansuripur,\u00a0“Detecting transition regions in magneto-optical disk systems,”<\/a><\/strong> Appl. Phys. Lett. 55<\/b>, 716 (1989).<\/li>\n
  25. M. Mansuripur, “Domain wall energy in the media of magneto-optical recording,”<\/a><\/strong>\u00a0J. Appl. Phys. 66<\/b>, 6175 (1989).<\/li>\n
  26. M. Mansuripur, F. Zhou, and J.K. Erwin, “Measuring the wavelength dependence of magneto-optical Kerr (or Faraday) rotation and ellipticity\u00af: a technique,”<\/a><\/b> Appl. Opt.\u00a029<\/b>, 1308 (1990).<\/li>\n
  27. M. Mansuripur, “Analysis of multilayer thin film structures containing magneto-optic and anisotropic media at oblique incidence using 2 x 2 matrices,”<\/a><\/strong>\u00a0J. Appl. Phys.67<\/b>, 6466-6475 (1990).<\/li>\n
  28. M. Mansuripur and R. Giles, “Simulation of the magnetization reversal dynamics on the Connection Machine,”<\/strong> <\/a>Computers in Physics 4<\/b>, 291-302, (1990).<\/li>\n
  29. R.A. Hajjar, F.L. Zhou and M. Mansuripur, “Magneto-optical measurement of anisotropy energy constants on amorphous rare earth-transition metal alloys,”<\/a><\/strong>\u00a0J. Appl. Phys. 67<\/b>, 5328-5330 (1990).<\/li>\n
  30. R. Giles, M. Mansuripur, “Possible sources of coercivity in thin films of amorphous rare earth-transition metal alloys”,<\/strong> <\/a>Computers in Physics 5<\/b>, 204-219 (1991).<\/li>\n
  31. M. Mansuripur, “Computation of electron diffraction patterns in Lorentz electron microscopy of thin magnetic films,”<\/a><\/strong>\u00a0J. Appl. Phys. 69<\/b>, 2455-2464 (1991).<\/li>\n
  32. R. Hajjar, M. Mansuripur, and H.P.D. Shieh, “Measurements of magnetoresistance in magneto-optical recording media,”<\/a><\/strong>\u00a0J. Appl. Phys. 69<\/b>, 7067-7080 (1991).<\/li>\n
  33. M. Mansuripur, R. Giles and G. Patterson, “Coercivity of domain wall motion in thin films of amorphous rare earth-transition metal alloys,” <\/a><\/strong>(invited), J. Magnet. Soc. Japan 15<\/b>, 17-30 (1991).<\/li>\n
  34. Hong Fu, M. Mansuripur and P. Meystre, “Generic source of perpendicular anisotropy in amorphous rare-earth–transition-metal films”<\/a><\/strong>\u00a0Phys. Rev. Lett. 66<\/b>, 1086-1089 (1991).<\/li>\n
  35. M. Mansuripur, “Effects of high-numerical-aperture focusing on the state of polarization in optical and magneto-optical data storage systems,”<\/a><\/b> Applied Optics 30<\/b>, 3154-3162 (1991).<\/li>\n
  36. B.E. Bernacki, M. Mansuripur, “Characterization of magneto-optical recording media in terms of domain boundary jaggedness,”<\/a><\/strong>\u00a0<\/b>J. Appl. Phys. 69<\/b>, 4960-4962 (1991).<\/li>\n
  37. M. Mansuripur, “Enumerative modulation coding with arbitrary constraints and post-modulation error correction coding for data storage systems,”<\/a><\/strong>\u00a0Proceedings of SPIE\u00a01499<\/b>, 72-86 (1991).<\/li>\n
  38. R. Giles, P. Alexopoulos and M. Mansuripur, “Micromagnetics of thin film cobalt-based media for magnetic recording,”<\/a><\/strong> Computers in Physics 6<\/b>, 53-70 (1992).<\/li>\n
  39. R. Giles and M. Mansuripur, “Dynamics of magnetization reversal in amorphous films of RE-TM alloys”<\/a><\/strong> (invited), Proceedings of the 1st magneto\u00ad optical recording international symposium (MORIS), J. Mag. Soc. Japan 15-S1<\/b>, 299-305 (1991).<\/li>\n
  40. R.A. Hajjar, Te-ho Wu and M. Mansuripur, “Measurement of anisotropy energy for magneto-optical media,”<\/a><\/strong>\u00a0J. Appl. Phys. 71<\/b>, 813-820 (1992).<\/li>\n
  41. R.A. Hajjar and M. Mansuripur, “Magnetoresistance peaks in the neighborhood of coercivity in magneto-optical recording media,”<\/a><\/strong>\u00a0J. Appl. Phys. 72<\/b>, 1528-1538 (1992).<\/li>\n
  42. A.F. Zhou, J.K. Erwin, C.F. Brucker and M. Mansuripur, “Dielectric tensor characterization for magneto-optical recording media,”<\/a><\/b> Applied Optics, 31<\/b>, 6280-6286 (1992).<\/li>\n
  43. Hong Fu and M. Mansuripur,\u00a0“Boltzmann distribution of bond orientations and perpendicular anisotropy in amorphous rare-earth–transition-metal films”<\/a><\/strong> Physical Review B 45<\/b>, 7188-7195 (1992).<\/li>\n
  44. Hong Fu, R. Giles, M. Mansuripur and G. Patterson,\u00a0“Investigation of the effects of nanostructure on the observable behavior of magnetic thin film using large-scale computer simulation,”<\/a><\/strong> Computers in Physics 6<\/b>, 610-629 (1992).<\/li>\n
  45. Hong Fu, R. Giles and M. Mansuripur, “Coercivity mechanisms in magneto-optical recording media”,<\/strong> <\/a>Computers in Physics 8<\/b>, 80-91 (1994).<\/li>\n
  46. Te-ho Wu, Hong Fu, R.A. Hajjar, T. Suzuki and M. Mansuripur, “Measurement of magnetic anisotropy constant for magneto-optical recording media – a comparison of several techniques,”<\/a><\/strong>\u00a0J. Appl. Phys. 73<\/b>, 1368-1376 (1993).<\/li>\n
  47. B.E. Bernacki, K. Bates, M. Mansuripur, D. Hansen, D. Cisneros, “Characterization of a novel focusing\/tracking technique with increased feedthrough immunity for optical-disk applications: the double-astigmatic method”<\/a><\/b>, Applied Optics 32<\/b>, 5789-5796 (1993).<\/li>\n
  48. B.E. Bernacki and M. Mansuripur, “Investigation of substrate birefringence effects on optical-disk performance”<\/a><\/b>, Applied Optics 32<\/b>, 6547-6555 (1993).<\/li>\n
  49. B.E. Bernacki and M. Mansuripur, “Causes of focus-error feedthrough in optical-disk systems: stigmatic and obscuration methods”<\/a><\/b>, Applied Optics, 33<\/b>, 735-743 (1994).<\/li>\n
  50. Hong Fu, Teho Wu and M. Mansuripur, “Direct measurement of subnetwork exchange coupling constant for ferrimagnets”<\/a><\/strong>\u00a0Jpn. J. Appl. Phys. 33<\/b>, 12 (1994).<\/li>\n
  51. Hong Fu, S. Sugaya, J.K. Erwin and M. Mansuripur, “Measurement of birefringence for optical recording disk substrates,”<\/a><\/b> Applied Optics 33<\/b>, 1938-1949 (1994).<\/li>\n
  52. Hong Fu, S. Sugaya and M. Mansuripur, “Measuring distribution of the ellipsoid of birefringence through the thickness of optical disk substrates,”<\/a><\/b> Applied Optics 33<\/b>, 5994-5998 (1994).<\/li>\n
  53. Hong Fu, T. Goodman, S. Sugaya, J.K. Erwin and M. Mansuripur, “Retroreflecting ellipsometer for measuring the birefringence of optical disk substrates,”<\/a><\/b> Applied Optics\u00a034<\/b>, 31-39 (1995).<\/li>\n
  54. Hong Fu, Z. Yan and M. Mansuripur, “<\/a><\/strong>Measurement of the wavelength dependence of birefringence for optical disk substrates,”<\/strong>\u00a0<\/a>Applied Optics 33<\/b>, 7406-7411 (1994).<\/li>\n
  55. S. Sugaya and M. Mansuripur, “Effect of substrate birefringence on focusing and tracking servo signals in magneto-optical disk data storage,”<\/a><\/b> Applied Optics 33<\/b>, 5073-5079 (1994).<\/li>\n
  56. S. Sugaya and M. Mansuripur, “Effect of tilted ellipsoid of birefringence on readout signal in magneto-optical disk data storage,”<\/a><\/b> Applied Optics 33<\/b>, 5999-6008 (1994).<\/li>\n
  57. M. Mansuripur and Y-C. Hsieh,\u00a0 “A novel method for measuring the vertical birefringence of optical disk substrates,”<\/a><\/strong>\u00a0Optics and Photonics News, Laboratory Notes section, S12-S15<\/b>, May 1994.<\/li>\n
  58. R. Ploessl, J.N. Chapman, M.R. Scheinfein, J.L. Blue, M. Mansuripur, H. Hoffmann,\u00a0“Micromagnetic structure of domains in Co-Pt multilayers; I. Investigations of wall structure,”<\/a><\/strong> J. Appl. Phys. 74<\/b>, 7431-7437 (1993).<\/li>\n
  59. J.J. Zambuto, R.E. Gerber, J.K. Erwin, M. Mansuripur, “Ring lens focusing and push-pull tracking scheme for optical disk systems,”<\/a><\/b> Applied Optics 33<\/b>, 7987-7994 (1994).<\/li>\n
  60. S. Gadetsky, I. Syrgabaev, J.K. Erwin, M. Mansuripur, T. Suzuki, and M. Ruane, “Measurements of the magneto-optic Kerr effect and the extraordinary Hall effect on grooved glass substrates coated with amorphous TbFeCo,”<\/a><\/strong>\u00a0J. Opt. Soc. Am. A. 13<\/b>, 314-319 (1996).<\/li>\n
  61. S. Gadetsky, T. Suzuki, J.K. Erwin, and M. Mansuripur, “Effects of grooves on magnetization reversal in amorphous TbFeCo thin films,”<\/a><\/strong>\u00a0IEEE Trans. Magnet. 30<\/b>, 4404-4406 (1994).<\/li>\n
  62. R.E. Gerber and M. Mansuripur, “Effects of substrate birefringence and tilt on the irradiance and phase patterns of the return beam in magneto\u00adoptical disk data storage,”<\/a><\/b> Applied Optics 34<\/b>, 4780-4787 (1995).<\/li>\n
  63. R.E. Gerber, Lifeng Li, and M. Mansuripur, “Effect of surface plasmon excitations on the irradiance pattern of the return beam in optical disk data storage,”<\/a><\/b> Applied Optics\u00a034<\/b>, 4929-4936 (1995).<\/li>\n
  64. L. Cheng, M. Mansuripur, and D.G. Howe, “Partial response equalization in magneto-optical disk readout: a theoretical investigation,”<\/a><\/b> Applied Optics 34<\/b>, 5153-5166 (1995).<\/li>\n
  65. Y-C. Hsieh and M. Mansuripur,\u00a0“Coercivity of magnetic domain wall motion near the edge of a terrace,”<\/a><\/strong> J. Appl. Phys. 78<\/b>, 380-386 (1995).<\/li>\n
  66. Hong Fu, Z. Yan, S-K. Lee, M. Mansuripur,\u00a0“Dielectric Tensor characterization and evaluation of several magneto-optical recording media,”<\/a><\/strong>\u00a0J. Appl. Phys. 78<\/b>, 4076-4090 (1995).<\/li>\n
  67. T.D. Goodman and M. Mansuripur, “Optimization of groove depth for cross-talk cancellation in the scheme of land-groove recording in magneto\u00adoptic disk systems,”<\/a>\u00a0<\/b>Applied Optics, 35<\/b>, pp 1107-1119 (1996).<\/li>\n
  68. R.E. Gerber and M. Mansuripur, “Tilt correction in an optical disk system,”<\/a><\/b> Applied Optics 35<\/b>, 7000-7007 (1996).<\/li>\n
  69. R.E. Gerber and M. Mansuripur, “Dependence of the tracking performance of an optical disk on the direction of the incident-light polarization,”<\/a><\/b> Applied Optics 34<\/b>, 8192-8200 (1996).<\/li>\n
  70. M. Takahashi, S. Gadetsky and M. Mansuripur, “Study of doman formation mechanism in magneto-optical materials using micro Hall effect measurements,”<\/a><\/strong>\u00a0J. Magn. Soc. Jpn. 19<\/b>, Supplement S1, 395-398 (1995).<\/li>\n
  71. S. Gadetsky, T. Suzuki, J.K. Erwin and M. Mansuripur, “Domain wall pinning in amorphous TbFeCo films on patterned substrates,”<\/a>\u00a0<\/strong>J. Magn. Soc. Jpn. 19<\/b>, Supplement S1, 91-96 (1995).<\/li>\n
  72. S. Gadetsky, T. Suzuki, J.K. Erwin and M. Mansuripur, “Thermomagnetic recording in amorphous TbFeCo films on patterned substrates,”\u00a0<\/a><\/strong>IEEE Trans. Magnet. 31<\/b>, 3253-3255 (1995).<\/li>\n
  73. S. Gadetsky and M. Mansuripur, “Barkhausen jumps during domain wall motion in thin magneto-optical films,”<\/a><\/b> J. Appl. Phys. 79<\/b>, 5667-5669 (1996).<\/li>\n
  74. S. Gadetsky, T. Suzuki, J.K. Erwin, and M. Mansuripur, “Magneto-optical recording on patterned substrates,”<\/a><\/strong> J. Appl. Phys. 79<\/b>, 5687-5692 (1996).<\/li>\n
  75. Y-C. Hsieh, M. Takahashi, S.N. Gadetsky, and M. Mansuripur,\u00a0“A dynamic study of domain formation mechanism during thermomagnetic recording based on micro-Hall effect measurements,”<\/a><\/strong> J. Appl. Phys. 79<\/b>, 5700-5702 (1996).<\/li>\n
  76. T. D. Goodman, R.E. Gerber, and M. Mansuripur, “Temperature dependence of the birefringence of optical-disk substrates,”<\/a><\/b> Applied Optics 35<\/b>, 3031-3038 (1996).<\/li>\n
  77. Y-C. Hsieh, S.N. Gadetsky, T. Suzuki, and M. Mansuripur,\u00a0“Oblique sputtering of amorphous TbFeCo thin films on glass substrates and the effect of deposition angle on perpendicular magnetic anisotropy,”<\/a><\/strong> J. Appl. Phys. 81<\/b>, 3555-3560 (1997).<\/li>\n
  78. Y-C. Hsieh and M. Mansuripur, “Measurement of the thermal coefficients of nonreversible phase-change optical recording films,”<\/a><\/b> Applied Optics 36<\/b>, 866-872 (1997).<\/li>\n
  79. R.E. Gerber, M. Mansuripur, and J.M. Sasian, “A versatile objective lens for testing of optical disks with adjustable correction for different wavelengths and substrate thicknesses,”<\/a><\/b> Applied Optics 36<\/b>, 2414-2420 (1997).<\/li>\n
  80. L. Cheng, C.L. Bartlett, J.K. Erwin, and M. Mansuripur, “A leaky polarizing beam-splitter with adjustable leak ratio for operation in the wavelength range of 440-690nm,”\u00a0<\/a><\/b>Applied Optics 36<\/b>, 4393-4399 (1997).<\/li>\n
  81. T.D. Goodman and M. Mansuripur, “Subtle effects of the substrate in optical disk data storage systems,”<\/a><\/b> Applied Optics 35<\/b>, 6747-6753 (1996).<\/li>\n
  82. J. M. Sasian and M. Mansuripur, “Design approaches with a lenslet array and a single, high-numerical aperture, annular-field objective lens for optical data storage systems that incorporate large numbers of parallel read-write-erase channels,”\u00a0<\/a><\/b>Applied Optics 38<\/b>, 1163-1168 (1999).<\/li>\n
  83. M. Mansuripur, C. Peng, J. K. Erwin, W. Bletscher, S. G. Kim, S. K. Lee, R. E. Gerber, C. Bartlett, T. D. Goodman, L. Cheng, C. S. Chung, T. Kim, and K. Bates, “Versatile polychromatic dynamic testbed for optical disks,”<\/a><\/b> Applied Optics 36<\/b>, 9296-9303 (1997).<\/li>\n
  84. Y-C. Hsieh and M. Mansuripur, “Image contrast in polarization microscopy of magneto-optical disk data storage media through birefringent plastic substrates,”\u00a0<\/a><\/b>Applied Optics 36<\/b>, 4839-4852 (1997).<\/li>\n
  85. C. Peng and M. Mansuripur, “Sources of noise in erasable optical disk data storage,”\u00a0<\/a><\/b>Applied Optics 37<\/b>, 921-928 (1998).<\/li>\n
  86. C. Bartlett, D. Kay, and M. Mansuripur, “Computer simulations of the effects of disk tilt and lens tilt on the push-pull tracking error signal in an optical disk drive,”<\/a><\/b> Applied Optics 36<\/b>, 8467-8473 (1997).<\/li>\n
  87. J. H. Yoo, C. W. Lee, D. H. Shin, C. Bartlett, K. I. Cheong, J. K. Erwin and M. Mansuripur,\u00a0“Investigation of certain diffraction effects in an optical disk,”<\/a><\/b> Applied Optics 36<\/b>, 9287-9295 (1997).<\/li>\n
  88. C. Peng, M. Mansuripur, W. M. Kim and S. G. Kim, “Edge detection in phase-change optical data storage,”\u00a0<\/a><\/strong>Edge detection in phase-change optical data storage,” Appl. Phys. Lett. 71<\/b>, 2088-2090 (1997).<\/li>\n
  89. C. Peng, L. Cheng, and M. Mansuripur,\u00a0“Experimental and theoretical investigations of laser-induced crystallization and amorphization in phase-change optical recording media,”<\/a><\/strong>\u00a0J. Appl. Phys. 82<\/b>, 4183-4191 (1997).<\/li>\n
  90. Wei-Hung Yeh, M. Mansuripur, M. Fallahi and R. S. Penner, “Talbot imaging with increased spatial frequency: a technique for replicating truncates self-imaging objects,”\u00a0<\/a><\/strong>Optics Communications 170<\/b>, 207-212 (1999).<\/li>\n
  91. C. Peng and M. Mansuripur,\u00a0“Noise and coupling in magnetic super-resolution media for magneto-optical readout,”<\/a><\/strong> J. Appl. Phys. 85<\/b>, 6323-6330 (1999).<\/li>\n
  92. C. Peng, W. H. Yeh, and M. Mansuripur, “Measurements and simulations of differential phase-tracking signals in optical disk data storage,”<\/a><\/b> Applied Optics 37<\/b>, 4425-4432 (1998).<\/li>\n
  93. C. Peng, M. Mansuripur, and K. Nagata, “Edge detection readout signal and cross-talk in phase-change optical data storage,”<\/a>\u00a0<\/strong>Applied Physics Letters 72<\/b>, 3422-3424 (1998).<\/li>\n
  94. Wei-hung Yeh, Lifeng Li, and M. Mansuripur, “Vector diffraction and polarization effects in an optical disk system,”<\/a><\/b> Applied Optics 37<\/b>, 6983-6988 (1998).<\/li>\n
  95. A. Kikitsu, C. M. Falco, and M. Mansuripur,\u00a0“Kerr effect enhancement by photon tunneling and possible application to a new scanning probe magnetic microscope,”<\/a><\/strong> J. Appl. Phys. 83<\/b>, 6232-6234 (1998).<\/li>\n
  96. Wei-hung Yeh, Warren Bletscher, and M. Mansuripur,\u00a0 “High resolution optical shaft encoder for motor speed control based on an optical disk pick-up,”<\/a><\/strong>\u00a0Review of Scientific Instruments 69<\/b>, 3068-3071 (1998).<\/li>\n
  97. C. Peng and M. Mansuripur, “Evaluation of partial-response, maximum-likelihood detection for phase-change optical data storage,”<\/a><\/b> Applied Optics 38<\/b>, 4394-4405 (1999).<\/li>\n
  98. Wei-hung Yeh, J. Carriere, and M. Mansuripur, “Polarization microscopy of magnetic domains for magneto-optical disks,”<\/a><\/b> Applied Optics 38<\/b>, 3749-3758 (1999).<\/li>\n
  99. Wei-hung Yeh and M. Mansuripur, “Evanescent coupling in magneto-optical and phase-change disk systems based on the solid immersion lens,”<\/a><\/b> Applied Optics 39<\/b>, 302-315 (2000).<\/li>\n
  100. E. M. Wright, M. Mansuripur, V. Liberman, and K. Bates, “Spatial pattern of microchannel formation in fused silica irradiated by nanosecond ultraviolet pulses,”<\/a>\u00a0<\/b>Applied Optics 38<\/b>, 5785-5788 (1999).<\/li>\n
  101. M. Mansuripur, J. K. Erwin, W. Bletscher, P. Khulbe, K. Sadeghi, X. Xun, A. Gupta, and S. Mendes, “Static tester for characterization of phase-change, dye-polymer, and magneto-optical media of optical data storage,”<\/a><\/b> Applied Optics 38<\/b>, 7095-7104 (1999).<\/li>\n
  102. P. Khulbe, X. Xun, and M. Mansuripur, “Crystallization and amorphization studies of a Ge2Sb2.3Te5 thin-film sample under pulsed laser irradiation,”<\/b><\/a> Applied Optics 39<\/b>, 2359-2366 (2000).<\/li>\n
  103. C. Peng and M. Mansuripur, “Measurement of the thermal conductivity of erasable phase-change optical recording media,”<\/b><\/a> Applied Optics 39<\/b>, 2347-2352 (2000).<\/li>\n
  104. P. Khulbe, E. M. Wright, and M. Mansuripur,\u00a0“Crystallization behavior of as-deposited, melt-quenched, and primed amorphous states of Ge2Sb2.3Te5 films,”<\/a><\/strong>\u00a0J. Appl. Phys.88<\/b>, 3926-3933 (2000).<\/li>\n
  105. Wei-Hung Yeh, Lifeng Li, and M. Mansuripur, “Computation of effective groove depth in an optical disk with vector diffraction theory,”<\/b><\/a> Applied Optics 39<\/b>, 316-323 (2000).<\/li>\n
  106. R. Liang, J. K. Erwin, and M. Mansuripur, “Measurement of the relative optical phase between amorphous and crystalline regions of the phase-change media of optical recording,”<\/b><\/a> Applied Optics 39<\/b>, 2167-2173 (2000).<\/li>\n
  107. R. Liang, J. K. Erwin, and M. Mansuripur, “Variation on Zernike’s phase-contrast microscope,”<\/b><\/a> Applied Optics 39<\/b>, 2152-2158 (2000).<\/li>\n
  108. X. Xun, C. Peng, and M. Mansuripur, “Estimation of thermal conductivity of magneto-optic media,”<\/b><\/a> Applied Optics 39<\/b>, 4355-4360 (2000).<\/li>\n
  109. J. Tesar, R. Liang, and M. Mansuripur,\u00a0 “Optical modeling combining geometrical ray tracing and physical-optics software,”<\/a><\/strong>\u00a0Opt. Eng. 39<\/b>, 1845-1849 (2000).<\/li>\n
  110. C. Peng and M. Mansuripur,\u00a0 “Thermal cross-track cross talk in phase-change optical disk data storage,”<\/a><\/strong>\u00a0J. Appl. Phys. 88<\/b>, 1214-1220 (2000).<\/li>\n
  111. M. Mansuripur, R. Liang, and J. Tsujiuchi, “Simulation software for optical systems: DIFFRACT\u2122 and its applications,<\/span>\u00a0(in Japanese), Optical Technology Contact 38<\/b>, 147-156 (2000).<\/li>\n
  112. E. M. Wright, P. K. Khulbe, and M. Mansuripur, “Dynamic theory of crystallization in Ge2Sb2.3Te5 phase-change optical recording media,”<\/b><\/a> Applied Optics 39<\/b>, 6695-6701 (2000).<\/li>\n
  113. R. Liang, L. Li, K. Saito, and M. Mansuripur, “Polarization dependence of readout signals from periodic one-dimensional arrays of magnetic domains in magneto-optical media and crystalline-amorphous line pairs in phase-change media of optical recording,”<\/a><\/b> Applied Optics 40<\/b>, 2323-2330 (2001).<\/li>\n
  114. C. Peng, R. Liang, J. K. Erwin, W. Bletscher, K. Nagata, and M. Mansuripur,\u00a0“Determination of optical constants of thin films and multilayer stacks by use of concurrent reflectance, transmittance, and ellipsometric measurements,”<\/a><\/b> Applied Optics 40<\/b>, 5088-5099 (2001).<\/li>\n
  115. C. Peng, M. Mansuripur, M. Ikenishi, and M. Miura, \u201cSubstrate noise in optical data-storage systems,\u201d<\/a><\/b> Applied\u00a0 Optics 40<\/b>, 3379-3386 (2001).<\/li>\n
  116. X. Xun, C. Peng, K. Saito, and M. Mansuripur, “Scattering measurements on optical disks and their relation to media noise,”<\/a><\/b> Applied Optics 40<\/b>, 4728-4737 (2001).<\/li>\n
  117. M. Mansuripur, “Dependence of Capacity on Media Noise in Data Storage Systems” <\/a><\/strong>Japn. J. Appl. Phys. 41<\/b>, 1638-1642 (2002).<\/li>\n
  118. G. M. Fischer, B. Medower, R. Revay and M. Mansuripur, \u201cThermal Properties and Crystallization Dynamics of a Phase-change Alloy for Write-Once Optical Data Storage,\u201d<\/a><\/b> Applied Optics 41<\/b>, 1998-2007 (2002).<\/li>\n
  119. N. Miyagawa and M. Mansuripur, “Analog Recording on Phase-chang Optical Disks”<\/a><\/strong>\u00a0Special Issue of J. Magn. Soc. Japan<\/i> 25<\/b>, No. 3-2, 437-440 (2001).<\/li>\n
  120. M. Mansuripur, P. K. Khulbe, X. Xun, J. K. Erwin, and W. Bletscher,\u00a0“Real-time studies of mark formation processes in phase-change and magneto-optical media using a two-laser tester,”<\/a><\/strong>\u00a0J. Magn. Soc. Japan<\/i> 25<\/b>, 399-407 (2001).<\/li>\n
  121. R. Liang, C. Peng, K. Nagata, K. Daly-Flynn, and M. Mansuripur, “Optical characterization of multilayer stacks used as phase-change media of optical disk data storage,”<\/a><\/b> Applied Optics 41<\/b>, 370-378 (2001).<\/li>\n
  122. C. Peng and M. Mansuripur, “Measurement of the thermal coefficients of rewritable phase-change optical recording media”<\/a><\/b>, Applied Optics 41<\/b>, 361-369 (2002).<\/li>\n
  123. X. Xun, J. K. Erwin, W. Bletscher, J. Choi, S. Kallenbach, and M. Mansuripur,“Crystallization studies on phase-change optical recording media by use of a two-dimensional periodic mark array,”<\/a><\/b> Applied Optics 40<\/b>, 6535-6547 (2001).<\/li>\n
  124. R. Liang, J. Carriere, and M. Mansuripur, “Intensity, polarization, and phase information in optical disk systems,”<\/a><\/b>Applied Optics 41<\/b>, 1565-1573 (2002).<\/li>\n
  125. M. Mansuripur, “DNA, Human Memory, and the Storage Technology of the 21st Century,”<\/a><\/b> SPIE Proceedings, Vol. 4342<\/b>, 1-29 (2001).<\/li>\n
  126. C. Peng and M. Mansuripur, “Partial response signaling for phase-change optical data storage without electronic equalization”,<\/a><\/b> Applied Optics 41<\/b>, 3479-3486 (2002).<\/li>\n
  127. X. Xun, C. Peng, and M. Mansuripur, \u201cEstimation of thermal coefficients of magneto-optical media,\u201d<\/a><\/b> Applied Optics 41<\/b>, 4596-4602 (2002).<\/li>\n
  128. P. K. Khulbe, T. Hurst, M. Horie, and M. Mansuripur, \u201cCrystallization behavior of Ge-doped eutectic Sb70<\/sub>Te30<\/sub> films in optical disks,\u201d<\/a><\/b> Applied Optics 41<\/b>, 6220-6229 (2002).<\/li>\n
  129. M. Mansuripur, P.K. Khulbe, S.M. Kuebler, J.W. Perry, M.S. Giridhar, and N. Peyghambarian,\u00a0“Information Storage and Retrieval using Macromolecules as Storage Media,”<\/a>\u00a0<\/strong>SPIE Proceedings Vol. 5069<\/b>, pp 231-243 (2003).<\/li>\n
  130. A.\u00a0R. Zakharian, J.\u00a0V. Moloney, and M. Mansuripur, “Simulating near-field effects in high-density optical disk data storage”<\/a><\/strong>\u00a0(invited feature article), Computing in Science & Engineering<\/i>, a joint publication of the IEEE Computer Society<\/i> and the American Institute of Physics<\/i>, Vol. 5<\/b>, No.\u00a06, pp 15-21 (November\/December 2003).<\/li>\n
  131. C. Peng and M. Mansuripur,\u00a0“Amorphization induced by sub-nanosecond laser pulses in phase-change optical recording media”<\/strong><\/a>\u00a0Applied Optics 43<\/b>, 4367 (2004).<\/li>\n
  132. M.S. Giridhar, K.B.\u00a0Seong, A.\u00a0Sch\u00fclzgen, P.K. Khulbe, N.\u00a0Peyghambarian, and M.\u00a0Mansuripur,\u00a0“Femtosecond pulsed laser micro-machining of glass substrates with application to microfluidic devices”<\/a><\/strong>\u00a0\u00a0Applied Optics<\/i> 43<\/b>, 4584 (2004).<\/li>\n
  133. A. Kosterin, V. Temyanko, M. Fallahi, and M. Mansuripur,\u00a0“Tapered fiber bundles for combining high-power diode lasers,”<\/a><\/strong>\u00a0Applied Optics<\/i> 43<\/b>, 3893 (2004).<\/li>\n
  134. A. Kosterin, J.\u00a0K. Erwin, M. Fallahi, and M. Mansuripur, “Heat and temperature distribution in a cladding pumped, Er:Yb co-doped phosphate fiber,”<\/a><\/strong>\u00a0Review of Scientific instruments<\/i> 75<\/b>, 5166 (2004).<\/li>\n
  135. A. R. Zakharian, M. Mansuripur and J. V. Moloney, \u201cTransmission of light through small elliptical apertures,\u201d<\/a><\/b> Optics Express<\/i> 12<\/b>, 2631 (2004).<\/span><\/li>\n
  136. K. Watabe, P. Polynkin, and M. Mansuripur,\u00a0“Behavior of GeSbTeBi phase-change optical recording media under sub-nanosecond pulsed laser irradiation,”<\/a><\/strong> Applied Optics<\/i> 43<\/b>, 4033-4040 (2004).<\/li>\n
  137. K.\u00a0Watabe, P. Polynkin, and M. Mansuripur,\u00a0“Behavior of GeSbTeBi phase-change optical recording media under sub-nanosecond pulsed laser irradiation,”<\/a><\/strong> Proceedings of SPIE<\/i> 5380<\/b>, 342-350 (2004).<\/li>\n
  138. K. Watabe, P. Polynkin, and M. Mansuripur,\u00a0“Optical pump-and-probe test system for thermal characterization of thin metal and phase-change films,”<\/a><\/strong> Applied Optics<\/i> 44,\u00a0<\/b>3167-3173 (2005).<\/li>\n
  139. T. Vallius, J. Turunen, M. Mansuripur, and S. Honkanen \u201cTransmission through single subwavelength apertures in thin metal films and effects of surface plasmons,\u201d<\/a><\/b>Journal of the Optical Society of America A, 21<\/b>, Issue 3, 456-463 (2004).<\/li>\n
  140. Tao Liu, A.\u00a0R. Zakharian, M. Fallahi, J. V. Moloney, and M. Mansuripur, \u201cMultimode interference-based photonic crystal waveguide power splitter,\u201d<\/a><\/b> Journal of Lightwave Technology<\/i> 22<\/b>, 2842-46 (2004).<\/li>\n
  141. Tao Liu, A. Zakharian, R. Rathnakumar, M. Fallahi, J. V. Moloney, and M. Mansuripur, Applications of photonic crystals in optical data storage”<\/strong><\/a>\u00a0Proceedings of SPIE<\/i> 5380<\/b>, 430-438 (2004).<\/li>\n
  142. P. Polynkin, V. Temyanko, M. Mansuripur, and N. Peyghambarian,\u00a0Efficient and scalable side-pumping scheme for short, high power optical fiber lasers and amplifiers”<\/strong><\/a>\u00a0IEEE Photonics Technology Letters<\/i> 16<\/b>, 2024 (2004). Featured as \u201cEfficient side-pumping scheme excites short fiber laser,\u201d in Photonic Spectra <\/i>38<\/b>, <\/i>116-18 (2004).<\/li>\n
  143. N. Peyghambarian, T. Qiu, P. Polynkin, A. Schulzgen, L. Li, V. Temyanko, M. Mansuripur, J.\u00a0V.\u00a0Moloney, “Short fiber lasers produce record power\/length of 1.33 W\/cm”<\/a><\/strong>\u00a0Optics & Photonics News<\/i> 15<\/b>, 41 (2004).<\/li>\n
  144. Y. Xie, A. R. Zakharian, J.\u00a0V. Moloney, and M. Mansuripur, \u201cTransmission of light through slit apertures in metallic films,\u201d<\/b> <\/a>Optics Express<\/i> 12<\/b>, 6106 (2004).<\/li>\n
  145. M. Mansuripur, Y. Xie, A. R. Zakharian, and J.\u00a0V. Moloney, \u201cTransmission of light through slit apertures in metallic films,\u201d <\/a><\/b>IEEE Trans. Magnetics<\/i> 41<\/b>,\u00a01012-1015 (2005).<\/li>\n
  146. M. Mansuripur, \u201cRadiation pressure and the linear momentum of the electromagnetic field,\u201d <\/a><\/b>Optics Express<\/i> 12<\/b>, 5375-5401 (2004).<\/li>\n
  147. M. Mansuripur, A. R. Zakharian, and J. V. Moloney, \u201cRadiation pressure on a dielectric wedge,\u201d<\/a><\/b> Optics Express<\/i> 13<\/b>, 2064-2074 (2005).<\/li>\n
  148. A.\u00a0R. Zakharian, M. Mansuripur, and J. V. Moloney, \u201cRadiation pressure and the distribution of electromagnetic force in dielectric media,\u201d<\/a><\/b> Optics Express<\/i> 13<\/b>, 2321-2336 (2005).<\/li>\n
  149. M. Mansuripur,\u00a0\u201cRadiation pressure and the linear momentum of light in dispersive dielectric media,\u201d\u00a0<\/a><\/b>Optics Express<\/i> 13<\/b>, 2245-2250 (2005).<\/li>\n
  150. M. Mansuripur and P. K. Khulbe,\u00a0“Macromolecular data storage with petabyte-cm3\u00a0density, highly parallel read-write operations, and genuine 3D storage capability,”<\/a><\/strong> Proceedings of SPIE<\/i> 5380<\/b>, 272-282 (2004).<\/li>\n
  151. P.\u00a0K.\u00a0Khulbe, M. Mansuripur, and R.\u00a0Gruener,\u00a0“DNA translocation through a-hemolysin nano-pores with potential application to macromolecular data storage,”<\/a><\/strong> J. Appl. Phys.<\/i> 97<\/b>, 104317-1:7 (2005).<\/li>\n
  152. P. Polynkin, A. Polynkin, N. Peyghambarian, and M. Mansuripur, “Evanescent-field based optical fiber sensor device for measuring the refractive index of liquids in microfluidic devices”<\/a><\/strong>\u00a0\u00a0Optics Letters<\/i> 30<\/b>, 1273-1275 (2005). Also listed in the Virtual Journal of Nanoscale Science and Technology<\/i> 11<\/b> (May 2005).<\/li>\n
  153. A. Polynkin, P. Polynkin, A. Shultzgen, M. Mansuripur, and N. Peyghambarian, \u201cWatts-level, short all-fiber laser at 1.5mm with a large core and diffraction-limited output via intra-cavity spatial-mode filtering,\u201d <\/a><\/strong>Optics Letters<\/i> 30<\/b>, 403-405 (2005).<\/li>\n
  154. A. Polynkin, P. Polynkin, M. Mansuripur, and N. Peyghambarian,\u00a0Single-frequency fiber ring laser with 1W output power at 1.5 mm”<\/strong><\/a>\u00a0Optics Express<\/i> 13<\/b>, 3179-3184 (2005). Featured as\u00a0 \u00a0“Fiber ring laser generates 1W in a single frequency in eye-safe region,”<\/a><\/strong>\u00a0Photonics Spectra<\/i>39<\/b>, 113 (June 2005).<\/li>\n
  155. H. Zhang, D. Lu, T. Liu, M. Mansuripur, and M. Fallahi, “Direct laser writing of electro-optic waveguide on chromophore-doped hybrid sol-gel,”<\/a><\/strong> Appl. Phys. Lett. <\/i>85<\/b>, 4275-4277 (2004).<\/li>\n
  156. Tao Liu, A.\u00a0R. Zakharian, M. Fallahi, J. V. Moloney, and M. Mansuripur,\u00a0 Design of a compact, photonic-crystal-based polarizing beam-splitter,”<\/strong><\/a>\u00a0 \u00a0IEEE Photonics Technology Letters\u00a0<\/i>17<\/b>, 1435-1437 (2005).<\/li>\n
  157. Y. Xie, A.\u00a0R. Zakharian, J.\u00a0V. Moloney, and M. Mansuripur, \u201cTransmission of light through a periodic array of slits in a thick metallic film,\u201d<\/a><\/b> Optics Express <\/i>13<\/b>, 4485-4491 (2005).<\/li>\n
  158. M. Mansuripur, \u201cAngular momentum of circularly polarized light in dielectric media,\u201d<\/a><\/b> Optics Express<\/i> 13<\/b>, 5315-5324 (2005).<\/li>\n
  159. Tao Liu, M. Fallahi, M. Mansuripur, A.R. Zakharian, and J.\u00a0V. Moloney, \u201cIntersection of non-identical optical waveguides based on photonic crystals,\u201d<\/a><\/b> Optics Letters<\/i> 30<\/b>, 2409-2411 (2005).<\/li>\n
  160. P. Polynkin, A. Polynkin, M. Mansuripur, J.\u00a0V. Moloney, and N. Peyghambarian,\u00a0 “Single-frequency laser oscillator with watts-level output power at 1.5mm by use of a twisted-mode technique,”<\/a><\/strong>\u00a0<\/b>Optics Letters<\/i> 30<\/b>, 2745-2747 (2005).<\/li>\n
  161. M.\u00a0V. Berry, M. R. Jeffrey, and M. Mansuripur,\u00a0“Orbital and spin angular momentum in conical diffraction,”<\/a><\/strong>\u00a0J. Opt. A: Pure Appl. Opt.<\/i> 7<\/b>, 685-690 (2005).<\/li>\n
  162. M. Mansuripur,\u00a0“Radiation pressure and the distribution of electromagnetic force in dielectric media,”<\/a><\/strong>\u00a0Proceedings of SPIE<\/i> 5930<\/b>, 0O-1:7 (2005).<\/li>\n
  163. H. Yoda, P. Polynkin, and M. Mansuripur, “Beam quality factor of higher order modes in a step-index fiber,”<\/a><\/strong>\u00a0I<\/em>EEE Journal of Lightwave Technology <\/i>24<\/b>, 1350-55 (2006).<\/li>\n
  164. Tao Liu, M. Fallahi, J. V. Moloney, and M. Mansuripur,\u00a0“Fabrication of two-dimensional photonic cyrstals with embedded defects using blue-laser-writer and optical holography,”<\/strong><\/a>\u00a0IEEE Photonics Technology Letters<\/em> 18<\/strong>, 1100-1102 (2006).<\/li>\n
  165. A.\u00a0R. Zakharian, P. Polynkin, M. Mansuripur, and J.\u00a0V. Moloney, \u201cSingle-beam trapping of micro-beads in polarized light: Numerical simulations,\u201d<\/b> <\/a>Optics Express<\/i> 14<\/b>, 3660-3676 (2006).<\/li>\n
  166. Y. Xie, A.\u00a0R. Zakharian, J. V. Moloney, and M. Mansuripur,\u00a0“Transmission of light through periodic arrays of sub-wavelength slits in a metallic host,”<\/a><\/strong>\u00a0\u00a0<\/b>Optics Express <\/i>14<\/b>, 6400-6413 (2006).<\/li>\n
  167. P. Polynkin, A. Polynkin, D. Panasenko, N. Peyghambarian, M. Mansuripur, J. Moloney,\u00a0\u201cAll-fiber passively mode-locked laser oscillator at 1.5mm with Watts-level average output power and high repetition rate,\u201d <\/a><\/b>Optics Letters<\/i> 31<\/b>, 592-594 (2006). Featured as “Mode-Locked Fiber Laser Oscillator Generates Multiwatt Output,” Photonics Spectra 40<\/strong>, p. 75 (April 2006)<\/li>\n
  168. A. Polynkin, P. Polynkin, D. Panasenko, M. Mansuripur, J. Moloney, N. Peyghambarian,\u00a0“Short-cavity passively mode-locked fiber laser oscillator at 1.5mm with 550\u00a0MHz repetition rate and high average power,”<\/a><\/strong> Electronics Letters<\/i> 42<\/b>, 157-159 (2006).<\/li>\n
  169. A. Polynkin, P. Polynkin, D. Panasenko, M. Mansuripur, J. Moloney, N. Peyghambarian, “Short-cavity passively mode-locked picosecond ER\/Yb co-doped fiber laser oscillator with high average power<\/a>,”\u00a0Electronics Letters\u00a0<\/em>42,\u00a0<\/strong>41 (2006).<\/li>\n
  170. D. Panasenko, P. Polynkin, A. Polynkin, J. Moloney, M. Mansuripur, N. Peyghambarian,\u00a0\u201cEr\/Yb femtosecond ring fiber oscillator with 1.1W average power and GHz repetition rates\u201d<\/a><\/b>, IEEE Photonics Technology Letters <\/i>18<\/b>. <\/i>853-855 (2006).<\/li>\n
  171. K. Kieu and M. Mansuripur, “Tuning of fiber lasers by use of a single-mode biconic fiber taper,”<\/a><\/b> Opt<\/em>ics<\/em> Lett<\/em>ers<\/em> 31<\/b>, 2435-37 (2006).<\/li>\n
  172. K. Kieu and M. Mansuripur, “Active Q-switching of a fiber laser with a micro-sphere resonator,” <\/a><\/b>Opt<\/em>ics<\/em> Lett<\/em>ers<\/em> 31<\/strong>, 3568-3570 (2006).<\/li>\n
  173. Y. Xie, A.\u00a0R. Zakharian, J. V. Moloney, and M. Mansuripur, \u201cOptical transmission at oblique incidence through a periodic array of sub-wavelength slits in a metallic host,\u201d<\/a><\/b> Optics Express <\/i>14<\/strong>, 10220-27 <\/i>(2006).<\/li>\n
  174. A.\u00a0R. Zakharian, J. V. Moloney, and M. Mansuripur, \u201cSurface plasmon polaritons on metallic surfaces,\u201d<\/a><\/b> Optics Express <\/i>15<\/strong>, 183-197 (2007).<\/li>\n
  175. K. Kieu and M. Mansuripur, “Fiber laser using a microsphere resonator as a feedback element,” <\/a><\/b>Opt<\/em>ics<\/em> Lett<\/em>ers<\/em> 32<\/strong>, 244-246 (2007).<\/li>\n
  176. K. Kieu, K. Narumi, M. Mansuripur, “Investigation of crystallization and amorphization dynamics of phase-change thin films by sub-nanosecond laser pulses,”<\/a><\/b> Applied Optics<\/em> 45<\/strong>, 7826-31 (2006).<\/li>\n
  177. K. Kieu and M. Manusripur,\u00a0“Biconical Fiber Taper Sensors,”<\/a><\/strong> IEEE Photonics Technology Letters<\/em> 18<\/strong>, 2239-41 (2006).<\/li>\n
  178. K. Kieu and M. Mansuripur,\u00a0 Self-locked excitation scheme for microsphere resonators,”<\/strong><\/a>\u00a0IEEE Photonics Technology Letters<\/em> 19<\/strong>, 100-102 (2007).<\/li>\n
  179. G. M. Skinner, K. Visscher, and M. Mansuripur, “Biocompatible writing of data into DNA,”<\/a><\/strong>\u00a0Journal of Bionanoscience<\/em> 1<\/strong>, 17-21 (June 2007).<\/li>\n
  180. F. Kalkum, G. Gay, O. Alloschery, J. Weiner, H. J. Lezec, Y. Xie, and M. Mansuripur,\u00a0“Surface-wave interferometry on single subwavelength slit-groove structures fabricated on gold films,” <\/a><\/b>Optics Express<\/em> 15<\/strong>, 2613-2621 (2007).<\/li>\n
  181. M. Mansuripur, “Radiation pressure on submerged mirrors: Implications for the momentum of light in dielectric media,” <\/a><\/b>Optics Express<\/em> 15<\/strong>, 2677-2682 (2007).<\/li>\n
  182. M. Mansuripur,\u00a0“Radiation pressure and the linear momentum of the electromagnetic field in magnetic media,”<\/a><\/strong>\u00a0Optics Express<\/em> 15<\/strong>, 13502-13517 (2007).<\/li>\n
  183. M. Mansuripur,\u00a0“Modeling diffractive optical elements for optical data storage applications,”<\/a>\u00a0<\/strong>SPIE Proc. <\/em>6620<\/strong>, 66200N-1 (2007).<\/li>\n
  184. M. Mansuripur,\u00a0“Momentum of the electromagnetic field in transparent dielectric media,”<\/a><\/strong>\u00a0SPIE Proc.<\/em> 6644<\/strong>, 664413 (2007).<\/li>\n
  185. K. Kieu and M. Mansuripur, “Femtosecond laser pulse generation with a fiber taper embedded in carbon nanotube\/polymer composite,” <\/a><\/b>Optics Letters<\/em> 32<\/strong>, 2242-2244 (2007).<\/li>\n
  186. K. Kieu and M. Mansuripur, “All-fiber bidirectional passively mode-locked ring laser.”<\/a><\/b> Optics Letters <\/em>33<\/strong>, 64-66 (2008).<\/li>\n
  187. Y. Xie, A. R. Zakharian, J. V. Moloney, and M. Mansuripur,\u00a0“Bloch mode analysis of transmission through periodic slit arrays in finite thickness metallic slabs,”<\/a><\/strong>\u00a0SPIE Proc.\u00a0<\/em>6641<\/strong>, 66411S-1 (2007).<\/li>\n
  188. M. Mansuripur, “Electromagnetic Stress Tensor in Ponderable Media,” <\/a><\/b>Optics Express<\/em> 16<\/strong>, 5193-98 (2007).<\/li>\n
  189. M. Mansuripur, “Electromagnetic Force and Torque in Ponderable Media,” <\/a><\/b>Optics<\/i>Express<\/i> 16<\/b>, 14821-14835 (2008).<\/li>\n
  190. M. Mansuripur, “Generalized Lorentz law and the force of radiation on magnetic dielectrics,” <\/a><\/b>Proceedings of SPIE Symposium on NanoScience & Engineering <\/i>7038,<\/b> 70381T (2008).<\/li>\n
  191. Z. Deng, F. L. Lie, S. Shen, I. Ghosh, M. Mansuripur, and A. J. Muscat, “Water-based route to ligand-selective synthesis of ZnSe and Cd-doped ZnSe quantum dots with tunable ultraviolet A to blue photoluminescence,”<\/a><\/b> Langmuir<\/em> 25,<\/b> 434-442 (2009).<\/li>\n
  192. Z. Dneg, M. Mansuripur, A. J. Muscat, “New Method to Single-Crystal Micrometer-Sized Ultra-Thin Silver Nanosheets:\u00a0 Synthesis and Characterization,”<\/a><\/b> J. phys. Chem. C <\/i>113,<\/b> 867-873 (2009).<\/li>\n
  193. M. Mansuripur and A. R. Zakharian, “Maxwell’s macroscopic equations, the energy-momentum postulates, and the Lorentz law of force,”<\/a><\/b> Physical Review E <\/i>79, <\/b>026608 (2009).<\/li>\n
  194. Z. Deng, M. Mansuripur, A. J. Muscat, “Simple colloidal synthesis of single-crystal SbSeS nanotubes with composition-dependent band-gap energy in the near-infrared,”<\/a><\/strong>\u00a0NANO Letters\u00a0<\/em>9,\u00a0<\/strong>2015-2020 (2009).<\/li>\n
  195. Z. Deng, M. Mansuripur, A. J. Muscat, “Synthesis of two-dimensional single-crystal berzelianite nanosheets and nanoplates with near-infrared optical absorption,”<\/a><\/strong>\u00a0J. Mater. Chem.,<\/i>\u00a019,<\/strong> 6201-06 (2009).<\/li>\n
  196. Z. Deng, D. Chen, F. Tang, and M. Mansuripur, Growth of Single-Crystal Double-Directional Tellurium Nano-needles from CdTe Nanocrystals in Solution,”<\/a><\/b>\u00a0Crystal Growth & Design, <\/i>9,<\/strong>\u00a01823-28 (2009).<\/li>\n
  197. M. Mansuripur, “Comment on “Observation of a push force on the end face of a nanometer silica filament exerted by outgoing light,”<\/a><\/b>\u00a0Phys. Rev. Lett.\u00a0<\/i>103,\u00a0<\/strong>019301\u00a0(2009).<\/li>\n
  198. M.\u00a0Mansuripur, A. Zakharian, A. Lesuffleur, Sang-Hyun Oh, R. J. Jones, N.\u00a0C.\u00a0Lindquist, Hyungsoon Im, A. Kobyakov, and J. V. Moloney,\u00a0“Plasmonic nano-structures for optical data storage,”<\/strong><\/a> Optics Express<\/i> 17<\/b>, 14001-14014 (2009).<\/li>\n
  199. M.\u00a0Mansuripur and A.\u00a0R.\u00a0Zakharian, \u201cTheoretical analysis of the force on the end face of a nano-filament exerted by an outgoing light pulse,\u201d<\/a><\/b> Phys. Rev. A<\/i> 80<\/b>, 023823-1-7 (2009); also as a conference proceedings paper (with modifications) in \u201cWhat is wrong with the interpretation of recent nano-filament experiments?\u201d Proc. SPIE <\/i>Vol. 7400<\/b>, 740012-1-12 (2009).<\/li>\n
  200. M. Mansuripur, \u201cCan future storage technologies benefit from existing or emerging nano-tools and techniques?\u201d<\/a><\/b> Proc. SPIE<\/i> Vol. 7505<\/b> 75050F-1-3 (2009).<\/li>\n
  201. M.\u00a0Mansuripur and A.\u00a0R. Zakharian,\u00a0“Energy, momentum, and force in classical electro-dynamics – application to negative-index media,”<\/a><\/strong> \u00a0Optics Communications<\/i> 283<\/b>, 4594-4600 (2010); also as a conference proceedings paper in Proc. SPIE<\/i> OP101<\/b> 73920Q-1-9.<\/li>\n
  202. M.\u00a0Mansuripur,\u00a0“Resolution of Abraham-Minkowski controversy,”<\/a><\/strong> Optics Communications<\/i> 283<\/b>, 1997-2005 (2010).<\/li>\n
  203. M.\u00a0Mansuripur and A.\u00a0R.\u00a0Zakharian, \u201cWhence the Minkowski Momentum?\u201d<\/a><\/b> Optics Communications<\/i> 283<\/b>, 3557-3563 (2010); also as a conference proceedings paper in Proc. SPIE<\/i> 7400<\/b>, 740010-1-11 (2009).<\/li>\n
  204. C.H. Chu, C.D. Shiue, H.W. Cheng, M.L. Tzeng, H.P. Chiang, M. Mansuripur, and D.P. Tsai,\u201cLaser-induced phase transitions in Ge2<\/sub>Sb2<\/sub>Te5<\/sub> thin films used in optical and electronic data storage and in thermal lithography,\u201d<\/a><\/b> Optics Express<\/i> 18<\/b>, 18383-93 (2010).<\/li>\n
  205. M. Mansuripur,\u00a0“Nature of Electric and Magnetic Dipoles Gleaned from the Poynting Theorem and the Lorentz Force Law of Classical Electrodynamics,”<\/a><\/strong> Optics Communications<\/i> 284<\/b>, 594-602 (2011).<\/li>\n
  206. M. Mansuripur, and D. P. Tsai,\u00a0“New perspective on the reciprocity theorem of classical electrodynamics,”<\/a><\/strong> Optics Communications<\/i> 284<\/b>, 707-714 (2011).<\/li>\n
  207. W.T. Chen, P.C. Wu, C.J. Chen, C-J. Weng, H-C. Lee, T-J. Yen, C-H. Kuan, M. Mansuripur and D.P. Tsai, “Manipulation of multidimensional plasmonic spectra for information storage,”<\/a><\/strong> Applied Physics Letters<\/i> 98<\/b>, 171106~1-3\u00a0 (2011).<\/li>\n
  208. C.M. Chang, C.H. Chu, M.L. Tseng, H-P. Chiang, M. Mansuripur, and D.P. Tsai, \u201cLocal electrical characterization of laser-recorded phase-change marks on amorphous Ge2<\/sub>Sb2<\/sub>Te5<\/sub> thin films<\/a><\/b>,\u201d Optics Express<\/i> 19<\/b>, 9492-9504 (2011).<\/li>\n
  209. C.H. Chu, M.L. Tseng, C.D. Shiue, H.W. Cheng, H-P. Chiang, M. Mansuripur, and D.P. Tsai,\u00a0 “Fabrication of phase-change Ge2Sb2Te5 nano-rings,”<\/strong><\/a>\u00a0Optics Express\u00a0<\/i>19<\/strong>, 12652-12657 (2011).<\/li>\n
  210. M.L. Tseng, B.H. Chen, C.H. Chu, C.M. Chang, W.C. Lin, N.N. Chu, M. Mansuripur and D.P. Tsai,\u00a0“Fabrication of phase-change chalcogenide Ge2Sb2Te5 patterns by laser-induced forward transfer,”<\/a><\/strong> Optics Express<\/i> 19<\/b>, 16975-16984 (2011).<\/li>\n
  211. M. Mansuripur,\u00a0“Solar Sails, Optical Tweezers, and Other Light-Driven Machines,”<\/a><\/strong> Tribute to Joseph W. Goodman, edited by H. J. Caulfield and H. H. Arsenault,Proceedings of SPIE<\/i> Vol. 8122<\/b>, 81220D~1-13 (2011).<\/li>\n
  212. M. Mansuripur, A.R. Zakharian, and E.M. Wright, \u201cSpin and orbital angular momenta of light reflected from a cone<\/a>,\u201d<\/strong> Physical Review A<\/i> 84<\/b>, 033813~1-12 (2011).<\/li>\n
  213. M. Mansuripur, A.R. Zakharian, and E.M. Wright,\u00a0“Spin-to-orbital angular momentum exchange via reflection from a cone,”<\/a> <\/strong>Proceedings of SPIE<\/i> Vol. 8097<\/b>, 809716~1-9 (2011).<\/li>\n
  214. M. Mansuripur, \u201cSpin and orbital angular momenta of electromagnetic waves in free space,\u201d<\/a><\/b> Physical Review A<\/i> 84<\/b>, 033838~1-6 (2011).<\/li>\n
  215. M. Mansuripur, \u201cNew perspective on the optical theorem of classical electrodynamics,\u201d<\/a><\/b> American Journal of Physics\u00a0<\/i>80<\/strong>, 329-333 (2012).<\/li>\n
  216. M. Mansuripur, \u201cDeducing radiation pressure on a submerged mirror from the Doppler shift,\u201d<\/a><\/strong> Physical Review A<\/i>, 85<\/strong>\u00a0023807 (2012).<\/li>\n
  217. M. Mansuripur,\u00a0“Trouble with the Lorentz law of force – Incompatibility with special relativity,”<\/a><\/strong> Physical Review Letters 108<\/i>, 193901~1-4 (2012).<\/li>\n
  218. M. Mansuripur,\u00a0\u201cTrouble with the Lorentz Law of Force: Response to Critics,\u201d<\/a><\/strong> Proceedings of the SPIE Conference<\/i>,\u00a0Vol. 8455,<\/strong> 845512~1-13 (2012).<\/li>\n
  219. M. Mansuripur, \u201cAuthor\u2019s Response to Comments on Trouble with the Lorentz Law of Force,\u201d Physical Review Letters<\/em> 110<\/strong>, 089405 (February 2013).<\/li>\n
  220. M. Mansuripur and A.R. Zakharian,\u00a0 “Radiation pressure on a submerged absorptive partial reflector deduced from the Doppler shift,”<\/a><\/strong>\u00a0Physical Review A<\/i> 86<\/b>, 013841~1-9 (2012).<\/li>\n
  221. M. Mansuripur and A.R. Zakharian, “Radiation pressure and photon momentum in negative-index media,”<\/a>\u00a0<\/strong>Proceedings of the SPIE <\/i>Vol. 8455,<\/strong>\u00a0845511~1014 (2012).<\/li>\n
  222. M. Mansuripur,\u00a0“Angular Momentum Exchange Between Light and Material Media deduced from the Doppler shift,”<\/a><\/strong>\u00a0Proceedings of SPIE<\/i> Vol. 8458,\u00a0<\/strong>845805~1-8 (2012).<\/li>\n
  223. C.M. Chang, Y.J. Liu, M.L. Tseng, N.N. Chu, D.W. Huang, M. Mansuripur and D.P. Tsai,\u00a0“Characterization of Ge2Sb2Te5 thin film alloys using conductive-tip atomic force microscopy,”<\/a><\/strong>\u00a0In Tribute to Stanford Ovshinski on the occasion of his 90th<\/sup> birthday, Physica Status Solidi<\/i> B\u00a0<\/i>249<\/strong>, 1945-50 (2012).<\/li>\n
  224. K. Tada, G.\u00a0A. Cohoon, K. Kieu, M. Mansuripur and R.\u00a0A. Norwood,\u00a0“Fabrication of High-Q Microresonators Using Femtosecond Laser Micromachining,”<\/a><\/strong>\u00a0IEEE Photonics Technology Letters<\/i> 25<\/b>, 430-433 (2013).<\/li>\n
  225. M. Mansuripur,\u00a0“On the Foundational Equations of the Classical Theory of Electro-dynamics,”<\/a><\/strong>\u00a0Resonance<\/i> 18<\/b>, 130-155 (2013).<\/li>\n
  226. P.C. Lau, R.A. Norwood, M. Mansuripur and N. Peyghambarian,\u00a0“An effective and simple oxygen nanosensor made from MPA-capped water soluble CdTe nanocrystals,”<\/a><\/strong>\u00a0Nanotechnology<\/i> 24<\/b>, 015501~1-8 (2013).<\/li>\n
  227. P.C. Lau, Z. Zhu, R.A. Norwood, M. Mansuripur, and N. Peyghambarian,\u00a0“Thermally robust and blinking suppressed core graded-shell CdSe CdSe1-xSx CdS giant multishell semiconductor nanocrystals,”<\/a><\/strong> \u00a0 \u00a0Nanotechnology<\/i> 24<\/b>, 475705~1-9 (2013).<\/li>\n
  228. M. Mansuripur, A.R. Zakharian, and E.M. Wright, \u201cElectromagnetic-force distribution inside matter,\u201d<\/a> <\/b>Physical Review A <\/i>88<\/b>, 023826~1-13 (2013).<\/li>\n
  229. M. Mansuripur,\u00a0 “The Force Law of Classical Electrodynamics – Lorentz versus Einstein and Laub,”<\/a><\/strong>\u00a0Proceedings of SPIE<\/i> Vol. 8810<\/b>, 88100K~1-18 (2013).<\/li>\n
  230. M. Mansuripur, \u201cOptical Manipulation: Momentum Exchange Effect,\u201d<\/a><\/b> News\u00a0&\u00a0Views, Nature Photonics<\/i> 7<\/b>, 765-766 (2013).<\/li>\n
  231. M. Mansuripur, “The Lorentz force law and its connections to hidden momentum, the Einstein-Laub force, and the Aharonov-Casher effect,”<\/a>\u00a0<\/b>to appear in IEEE Transactions on Magnetics<\/i>, 2014.<\/li>\n
  232. T.\u00a0S. Mansuripur and M. Mansuripur,\u00a0“Fresnel reflection from a cavity with new roundtrip gain,”<\/a><\/strong>\u00a0Applied Physics Letters<\/em> 104<\/strong>, 121106~1-4 (2014).<\/li>\n
  233. M. Mansuripur and A. R. Zakharian, \u201cReply to \u2018Comment on \u2018Theoretical analysis of the force on the end face of a nanofilament exerted by an outgoing light pulse\u2019\u2019<\/a><\/strong>,\u201d Phys. Rev. A<\/em> 89<\/strong>, 057802, pp 1-5 (2014).<\/li>\n
  234. P.C. Lau, R.A. Norwood, M. Mansuripur and N. Peyghambarian,\u00a0 \u201cAn effective nanosensor for organic molecules based on water-soluble mercaptopropionic acid-capped CdTe nanocrystals with potential application in high-throughput screening and high-resolution optical microscopy,\u201d<\/a><\/strong> Biomedical Optics Express<\/em> 5<\/strong>, 2420-2434 (2014).<\/li>\n
  235. M. Mansuripur,“On the Electrodynamics of Moving Permanent Dipoles in External Electromagnetic Fields”<\/a><\/strong> Proceedings of SPIE<\/em> Vol. 9160<\/strong>, 91600X~1-29 (2014).<\/li>\n
  236. M. Mansuripur,\u00a0\u201cElectromagnetic force and torque in Lorentz and Einstein-Laub formulations,\u201d<\/a> <\/strong>Proceedings of SPIE<\/em> 9164<\/strong>, 91640B~1-16 (2014).<\/li>\n
  237. M. Mansuripur, \u201cThe Charge-Magnet Paradoxes of Classical Electrodynamics,\u201d <\/a><\/strong>Proceedings of SPIE<\/em> 9167<\/strong>, 91670J~1:12 (2014).<\/li>\n
  238. M. Mansuripur, \u201cMechanical effects of light on material media: radiation pressure and the linear and angular momenta of photons,\u201d <\/a><\/strong>Proceedings of SPIE<\/em> 9186<\/strong>, 91860S~1-6 (2014).<\/li>\n
  239. M. Mansuripur, \u201cAdvances in Macromolecular Data Storage,\u201d <\/a><\/strong>Proceedings of SPIE<\/em> 9201<\/strong>, 92010A~1-6 (2014).<\/li>\n
  240. Z. Zhu, T. Mankowski, K. Balakrishnan, A.S. Shikoh, F. Touati, M.A. Benammar, M.\u00a0Mansuripur, and C.M. Falco, \u201cTransparent conducting electrodes based on thin, ultra-long Copper nanowires and graphene nano-composites,\u201d <\/a><\/strong>Proceedings of SPIE<\/em> 9177<\/strong>, 91770J~1:6 (2014).<\/li>\n
  241. T.S. Mankowski, Z. Zhu, K. Balakrishnan, A.S. Shikoh, F. Touati, M.A. Benammar, M.\u00a0Mansuripur, and C.M. Falco,\u00a0\u201cMetal nanowire-graphene composite transparent electrodes,\u201d<\/a> <\/strong>Proceedings of SPIE<\/em> 9177<\/strong>, 91770I~1:6 (2014).<\/li>\n
  242. Z. Zhu, T. Mankowski, K. Balakrishnan, A.S. Shikoh, F. Touati, M.A. Benammar, M.\u00a0Mansuripur, and C.M. Falco, \u201cSol-gel deposition and plasma treatment of intrinsic, aluminum-doped, and gallium-doped zinc oxide thin films as transparent conductive electrodes,\u201d <\/a><\/strong>Proceedings of SPIE<\/em> 9561<\/strong>, 956109~1:5 (2015).<\/li>\n
  243. Z. Zhu, T. Mankowski, K. Balakrishnan, A.S. Shikoh, F. Touati, M.A. Benammar, M.\u00a0Mansuripur, and C.M. Falco, \u201cUltrahigh Aspect Ratio Copper-Nanowire-Based Hybrid Transparent Conductive Electrodes with PEDOT:PSS and Reduced Graphene Oxide Exhibiting Reduced Surface Roughness and Improved Stability,\u201d<\/a><\/strong> ACS Applied Materials & Interfaces<\/em> 7<\/strong> (30), 16223-30 (2015).<\/li>\n
  244. Z. Zhu, T. Mankowski, K. Balakrishnan, A.S. Shikoh, F. Touati, M.A. Benammar, M.\u00a0Mansuripur, and C.M. Falco,\u00a0\u201cHybrid transparent conductive electrodes with copper nanowires embedded in a zinc oxide matrix and protected by reduced graphene oxide platelets,\u201d<\/a><\/strong> Journal of Applied Physics<\/em> 119<\/strong>, 085303, pp1-5 (2016).<\/li>\n
  245. Z. Zhu, T. Mankowski, K. Balakrishnan, A.S. Shikoh, F. Touati, M.A. Benammar, M.\u00a0Mansuripur, and C.M. Falco, \u201cSol-gel deposited aluminum-doped and gallium-doped zinc oxide thin-film transparent conductive electrodes with a protective coating of reduced graphene oxide,\u201d<\/strong> <\/a>to appear in SPIE Journal of Nanophotonics<\/em> (2016).<\/li>\n
  246. M. Mansuripur, \u201cReply to \u2018Comment on \u2018Deducing radiation pressure on a submerged mirror from the Doppler shift\u2019\u2019<\/a><\/strong>,\u201d Physical Review A<\/em> 92<\/strong>, 017804~1:2 (2015).<\/li>\n
  247. G. Spavieri and M. Mansuripur, \u201cOrigin of the Spin-Orbit Interaction,\u201d <\/a><\/strong>Physica Scripta<\/em> 90<\/strong>, 085501, pp1-11 (2015).<\/li>\n
  248. M. Mansuripur, \u201cElectric and Magnetic Dipoles in the Lorentz and Einstein-Laub Formulations of Classical Electrodynamics,\u201d <\/a><\/strong>Proceedings of SPIE<\/em> 9370<\/strong>, 93700U~1-15 (2015).<\/li>\n
  249. M. Mansuripur, \u201cTutorial: Opto-mechanical cooling by the back-action of cavity photons,\u201d<\/strong> <\/a>in Optical Trapping and Optical Micromanipulation XII, edited by K. Dholakia and G. C. Spalding, Proceedings of SPIE<\/em> 9548<\/strong>, 954808~1-7 (2015).<\/li>\n
  250. M. Mansuripur,\u00a0\u201cEnergy and linear and angular momenta is simple electromagnetic systems,\u201d<\/a><\/strong> in Optical Trapping and Optical Micromanipulation XII, edited by K. Dholakia and G. C. Spalding, Proceedings of SPIE<\/em> 9548<\/strong>, 95480K~1-24 (2015).<\/li>\n
  251. M. Mansuripur, \u201cLight-Matter Interaction: Conversion of Optical Energy and Momentum to Mechanical Vibrations and Phonons,\u201d<\/strong> <\/a>in Quantum Sensing and Nano Electronics and Photonics XIII, edited by M. Razeghi, G.J. Brown, and J.S. Lewis, Proceedings of SPIE<\/em> 9755<\/strong>, 975521~1-34 (2016).<\/li>\n
  252. M. Mansuripur, M. Kolesik, and P. Jakobsen, “Leaky Modes of Dielectric Cavities”<\/a> <\/strong>Spintronics IX, edited by H.-J. Drouhin, J.-E. Wegrowe, and M. Razeghi, Proceedings of SPIE<\/em> 9931<\/strong>, 99310B~1:20 (2016).<\/li>\n
  253. Z. Zhu, T. Mankowski, A.S. Shikoh, F. Touati, M.A. Benammar, M. Mansuripur, and C.M. Falco, “Ultra-high aspect ratio copper nanowires as transparent conductive electrodes for dye sensitized solar cells”<\/a> <\/strong>Thin Films for Solar and Energy Technology VIII, edited by M.J. Heben and M.M. Al-Jassim, Proceedings of SPIE<\/em> 9936<\/strong>, 993603~1:8 (2016).<\/li>\n
  254. M. Mansuripur, “Comment on Jackson’s analysis of electric charge quantization due to interaction with Dirac’s magnetic monopole”<\/a>\u00a0<\/strong>Scientia Iranica, Transactions D: Computer Science & Engineering and Electrical Engineering<\/em>, 23<\/strong> (6), pp2874-80 (December 2016).<\/li>\n
  255. M. Mansuripur, “Electromagnetic Force and Momentum,”<\/a><\/strong>\u00a0Roadmap on Structured Light, Journal of Optics<\/em> 19<\/strong>, 013001, pp 8-9\u00a0(2017).<\/li>\n
  256. M. Mansuripur,\u00a0“Electromagnetic Angular Momentum”<\/a><\/strong>\u00a0Roadmap on Structured Light, Journal of Optics<\/em> 19\u00a0<\/strong>, 013001, pp 10-11\u00a0(2017).<\/li>\n
  257. M. Mansuripur, “Optical angular momentum in classical electrodynamics”<\/a> <\/strong>Physica Scripta<\/em> 92<\/strong>, 065501~1-9 (2017).<\/li>\n
  258. M. Mansuripur, M. Kolesik, and P. Jakobsen, “Leaky Modes of Solid Dielectric Spheres”<\/a><\/strong> Physical Review A<\/em> 96<\/strong>, 013846~1-14 (2017).<\/li>\n
  259. M. Mansuripur and Pin Han, “Thermodynamics of Radiation Pressure and Photon Momentum”<\/a> <\/strong>published in Optical Trapping and Optical Micromanipulation XIV, edited by K. Dholakia and G.C. Spalding, Proceedings of SPIE<\/em> 10347, 103471y,~1-20 (2017); DOI: 10.1117\/12.2274589<\/li>\n
  260. M. Mansuripur, “Thermodynamics of Radiation Pressure and Photon Momentum Part 2,”<\/a><\/strong>published in Complex Light & Optical Forces XII, edited by E.J. Galvez, D.L. Andrews, J. Gl\u00fcckstad, Proceedings of SPIE\u00a0<\/em>10549<\/strong>, 105490X~1-13 (2018); doi: 10.1117\/12.2286300.<\/li>\n
  261. M. Mansuripur, “Nature of the electromagnetic force between classical magnetic dipoles”<\/a><\/strong>\u00a0published in Spintronics X, edited by H.-J. Drouhin J.E. Wegrowe, M. Razeghi, and Jaffres, Proceedings of SPIE <\/em>10357, 103570R-1:6(2017). doi: 10.1117\/12.2273216<\/li>\n
  262. M. Mansuripur,\u00a0“Force, torque, linear momentum, and angular momentum in classical electrodynamics,”<\/a><\/strong> Applied Physics A <\/em>123<\/strong>:653, pp1-11 (2017).<\/li>\n
  263. P. Jakobsen, M. Mansuripur, and M. Kolesik,\u00a0“Leaky-mode expansion of the electro-magnetic field inside dispersive spherical cavity,”<\/a><\/strong>Journal of Mathematical Physics\u00a0<\/em>59<\/strong>, 033501 (2018); doi: 10.1063\/1.5006956.<\/li>\n
  264. M. Mansuripur,\u00a0 “Energy, linear momentum, and angular momentum exchange between an electromagnetic wave-packet and a small particle,”<\/a><\/strong>\u00a0published (without appendices) in Journal of Nanophotonics<\/em> 13<\/strong>, 012503, pp1-9 (2018); doi: 10.1117\/1.JNP.13.012503. Complete paper appeared in Optical Trapping and Optical Micromanipulation XV, SPIE Proceedings<\/em> 10723<\/strong>, 107230R~1-23 (2018); doi: 10.1117\/12.2322071.<\/li>\n
  265. M. Mansuripur,\u00a0“Fourier Optics in the Classroom,”<\/a><\/strong>\u00a0Proceedings of the Optical Society of America\u2019s Imaging & Applied Optics Congres<\/em>s, Orlando, Florida, pp 1-2 (June 2018).<\/li>\n
  266. M. Mansuripur,\u00a0“Self-field, radiated energy, and radiated linear momentum of an accelerated point charge,”<\/a><\/strong>\u00a0Published in Spintronics XI, edited by H.-J. Drouhin, J.E. Wegrowe, M. Razeghi, SPIE<\/em> Proceedings <\/em>10732<\/strong>, pp1-18 (2018). doi: 10.1117\/12.2322082.<\/li>\n
  267. M. Mansuripur,\u00a0“Self-field, radiated energy, and radiated linear momentum of an accelerated point charge (Part 2),”<\/a><\/strong>\u00a0Published in Quantum Sensing and Nano Electronics and Photonics XVI, SPIE<\/em> Proceedings <\/em>10926<\/strong>, 109260O~1:18 (2019); doi: 10.1117\/12.2511214.<\/li>\n
  268. M. Mansuripur, \u201cAbsorption and Stimulated Emission by a Thin Slab Obeying the Lorentz Oscillator Model,\u201d<\/a><\/strong> Special Issue of the Japanese Journal of Applied Physics<\/em> (Proceedings of the International Symposium on Imaging, Sensing, and Optical Memory, Kitakyushu, Japan, October 2018), 58<\/strong>, SKKB02 (2019); doi: 10.7567\/1347-4065\/ab2cc6.<\/li>\n
  269. M. Mansuripur and P.K. Jakobsen, \u201cAn approach to constructing super oscillatory functions,\u201d<\/a><\/strong> Journal of Physics A: Mathematical & Theoretical<\/em> 52<\/strong>, 305202, pp1-14 (2019); doi: 10.1088\/1751-8121\/ab27de.<\/li>\n
  270. M. Mansuripur, \u201cThought experiments that shed light on the nature of optical linear and angular momenta,\u201d<\/a><\/strong> Proceedings of SPIE<\/em> 11083<\/strong>, Optical Trapping and Optical Micromanipulation XVI, 110831Y (September 2019); doi: 10.1117\/12.2529901.<\/li>\n
  271. M. Mansuripur, \u201cSpin-orbit coupling in the hydrogen atom, the Thomas precession, and the exact solution of Dirac\u2019s equation,\u201d<\/a><\/strong> Spintronics XII, Proceedings of SPIE<\/em> 11090<\/strong>, 110901X (2019); doi: 10.1117\/12.2529885.<\/li>\n
  272. P.K. Jakobsen and M. Mansuripur, \u201cOn the nature of the Sommerfeld-Brillouin forerunners (or precursors),\u201d<\/a> <\/strong>Quantum Studies: Mathematics and Foundations<\/em>, pp1-25 (2019), doi:10.1007\/s40509-019-00210-9.<\/li>\n
  273. M. Mansuripur, \u201cThe ubiquity of Fourier transformation in optical sciences<\/a><\/strong>,\u201d to appear in Applied Optics<\/em> (2020).<\/li>\n
  274. Mansuripur and P.K. Jakobsen, \u201cElectromagnetic radiation and the self-field of a spherical dipole oscillator<\/a>,\u201d<\/strong> submitted to the American Journal of Physics <\/em>(April 2020).<\/li>\n
  275. M. Mansuripur and P.K. Jakobsen, \u201cElectromagnetic radiation and the self torque of an oscillating magnetic dipole<\/a>,\u201d<\/strong> Proceedings of SPIE <\/em>11462<\/strong>, pp1-12 (2020); doi: 10.1117\/12.2569137.<\/li>\n
  276. M. Mansuripur, \u201cEnergy, linear momentum, and spin and orbital angular momenta of circularly polarized Laguerre-Gaussian wave-packets,\u201d<\/a><\/strong> Proceedings of SPIE<\/em> 11463<\/strong>, pp1-14 (2020); doi: 10.1117\/12.2569131.<\/li>\n
  277. M. Mansuripur, \u201cDispersion of electromagnetic waves in linear, homogeneous, and isotropic media,\u201d<\/a><\/strong> Proceedings of SPIE <\/em>(Roland V. Shack Memorial Session) 11479<\/strong>, pp1-12 (2020); doi: 10.1117\/12.2567846.<\/li>\n
  278. M. Mansuripur, \u201cAn exact derivation of the Thomas precession rate using the Lorentz transformation,\u201d<\/a><\/strong> Proceedings of SPIE<\/em> 11470<\/strong>, pp1-10 (2020); doi: 10.1117\/12.2569025.<\/li>\n
  279. M. Mansuripur, \u201cA Tutorial on the Classical Theories of Electromagnetic Scattering and Diffraction,\u201d<\/strong><\/a> Nanophotonics<\/em> 20200348<\/strong>, pp1-28 (2020); doi: 10.1515\/nanoph-2020-0348.<\/li>\n
  280. M. Mansuripur and P.K. Jakobsen, \u201cTheoretical analysis of Fresnel reflection and transmission in the presence of gain media,\u201d<\/strong> Optical Review<\/em><\/a>, pp1-24 (2021); doi: 10.1007\/s10043-021-00690-4.<\/li>\n
  281. M. Mansuripur and P.K. Jakobsen, \u201cFresnel reflection and transmission in the presence of gain media,\u201d<\/strong> Proceedings of SPIE<\/em><\/a> 11797<\/strong>, Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX, 117971G (2021); doi: 10.1117\/12.2595188.<\/li>\n
  282. M. Mansuripur, \u201cElectromagnetic force and torque derived from a Lagrangian in conjunction with the Maxwell-Lorentz equations,\u201d<\/strong><\/a> Proceedings of SPIE<\/em> 11798<\/strong>, Optical Trapping & Optical Micromanipulation XVIII, 1179810<\/strong> (2021); doi: 10.1117\/12.2595187.<\/li>\n
  283. M. Mansuripur, \u201cUbiquity of Fourier Transformation in Optical Sciences (Part II),”<\/strong><\/a> \u00a0Proceedings of SPIE <\/em>11813<\/strong>, Tribute to James C. Wyant (2021).<\/li>\n
  284. M. Mansuripur, \u201cSpin-1 photons, spin-1\/2 electrons, Bell\u2019s inequalities, and Feynman\u2019s special perspective on quantum mechanics,\u201d<\/a> <\/strong>Proceedings of SPIE<\/em> 12205<\/strong>, Spintronics XV, 122050B (2022); doi: 10.1117\/12.2633646.<\/li>\n
  285. M. Mansuripur, \u201cLinear and angular momenta of photons in the context of \u2018which path\u2019 experiments of quantum mechanics,\u201d<\/a><\/strong> Proceedings of SPIE<\/em> 12198<\/strong>, Optical Trapping and Optical Micromanipulation XIX, 1219807 (2022); doi: 10.1117\/12.2632866.<\/li>\n
  286. M. Mansuripur, \u201cInsights into the behavior of certain optical systems gleaned from Feynman\u2019s approach to quantum electrodynamics,\u201d<\/a><\/strong> Proceedings of SPIE<\/em> 12197<\/strong>, Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XX, 1219703 (2022); doi: 10.1117\/12.2632902.<\/li>\n
  287. M. Mansuripur and Ewan M. Wright, \u201cFundamental properties of beam-splitters in classical and quantum optics,\u201d<\/a><\/strong> American Journal of Physics<\/em> 91<\/strong> (2023); doi: 10.1119\/5.0102760.<\/li>\n
  288. M. Mansuripur, \u201cElectromagnetic angular momentum of quantized wavepackets in free space,\u201d<\/strong><\/a> submitted to Proceedings of SPIE<\/em>, Optical Trapping & Optical Micromanipulation XX (2023).<\/li>\n
  289. M. Mansuripur, \u201cSpin and orbital angular momenta of electromagnetic waves in classical and quantum electrodynamics,\u201d<\/strong><\/a> submitted to Proceedings of SPIE<\/em>, Spintronics XVI, (2023).<\/li>\n
  290. M. Mansuripur, \u201cA comparison of the classical and quantum theories of light interacting with nano-materials,\u201d<\/strong><\/a> submitted to Proceedings of SPIE<\/em>, Molecular and Nanophotonic Machines VI (2023).<\/li>\n<\/ol>\n\n\n

    <\/p>\n","protected":false},"excerpt":{"rendered":"

    M. Mansuripur, J.W. Goodman, E.G. Rawson, R.J. Norton, “Fiber optics receiver error rate prediction using the Gram-Charlier series,”\u00a0IEEE Trans. Comm. 28, 402-407 (1980). M. Mansuripur,\u00a0 “Magnetization reversal in thin magnetic films with perpendicular anisotropy,”\u00a0J. Appl. Phys. 53, 1660-1663, (1982). M. Mansuripur, G.A.N. Connell, and J.W. Goodman, “Laser-induced local heating of multilayers,” Appl. Opt. 21, 1106, (1982). M. Mansuripur, G.A.N. Connell,<\/p>\n","protected":false},"author":3,"featured_media":0,"parent":0,"menu_order":7,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-21","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/pages\/21","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/users\/3"}],"replies":[{"embeddable":true,"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/comments?post=21"}],"version-history":[{"count":317,"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/pages\/21\/revisions"}],"predecessor-version":[{"id":1145,"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/pages\/21\/revisions\/1145"}],"wp:attachment":[{"href":"https:\/\/wp.optics.arizona.edu\/masud\/wp-json\/wp\/v2\/media?parent=21"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}