{"id":1796,"date":"2019-07-02T15:52:32","date_gmt":"2019-07-02T15:52:32","guid":{"rendered":"https:\/\/labsites.wdev.rochester.edu\/agrawal\/?page_id=1796"},"modified":"2019-10-24T18:10:46","modified_gmt":"2019-10-24T18:10:46","slug":"complete-list-of-publications","status":"publish","type":"page","link":"https:\/\/labsites.rochester.edu\/agrawal\/people\/group-members\/govind-agrawal\/complete-list-of-publications\/","title":{"rendered":"Complete List of Publications"},"content":{"rendered":"\n<h2 class=\"wp-block-heading\"><strong>Authored Books<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal and N. K. Dutta, <em>Semiconductor Lasers<\/em> (Van Nostrand Reinhold, 1986); 2nd ed.&nbsp;1993; reprinted in 2002 by Springer. <\/li><li>G. P. Agrawal, <em>Nonlinear Fiber Optics<\/em> (Academic Press, Elsevier,  1989); Chinese translation, 1992; Russian translation, 1996; Japanese  translation, 1997; 2nd ed.&nbsp;1995; 3rd ed.&nbsp;2001; 4th ed.&nbsp;2007, 5th  ed.&nbsp;2013; 6th ed. 2019. <\/li><li>G. P. Agrawal, <em>Fiber-Optic Communication Systems<\/em> (Wiley, 1992); 2nd ed.&nbsp;1997; Greek translation, 2000; 3rd ed.&nbsp;2002; 4th ed.&nbsp;2010. <\/li><li>G. P. Agrawal, <em>Applications of Nonlinear Fiber Optics<\/em>, (Academic Press, Elsevier, 2001), 2nd ed.&nbsp;2008; Chinese translation, 2010. <\/li><li>Y. S. Kivshar and G. P. Agrawal, <em>Optical Solitons: From Fibers to Photonic Crystals<\/em> (Academic Press, Elsevier, 2003); Russian translation, 2005. <br>G. P. Agrawal, <em>Lightwave Technology: Components and Devices<\/em> (Wiley, Hoboken, NJ, 2004). <\/li><li>G. P. Agrawal, <em>Lightwave Technology: Telecommunication Systems<\/em> (Wiley, Hoboken, NJ 2005). <br>M. Premaratne and G. P. Agrawal, <em>Light Propagation in Gain Media: Optical Amplifiers<\/em> (Cambridge University Press, 2011). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Edited Works<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal and R. W. Boyd, Eds., <em>Contemporary Nonlinear Optics<\/em> (Academic Press, Elsevier, 1992). <\/li><li>G. P. Agrawal, Ed., <em>Semiconductor Lasers: Past, Present and Future<\/em> (American Institute of Physics, New York, 1995). <\/li><li>G. P. Agrawal, C.-Z. Ning, and M. San Miguel, Eds., Special issues on &#8220;Spatial and Polarization Dynamics of Semiconductor Lasers,&#8221; <em>Optics Express<\/em>, July 1999; <em>J. Opt. Soc. Am. B<\/em>, Oct.&nbsp;1999. <\/li><li>J. Capmany, P. A. Krug, G. P. Agrawal, and M. N. Zervas, Eds., Special  issue on &#8220;Fiber and integrated gratings: fundamentals, devices and applications,&#8221; <em>Fiber and Integrated Optics<\/em>, June 2000. <\/li><li>G. P. Agrawal, A. Hasegawa, Y. Kivshar, and S. Wabnitz, Eds., Special issue on &#8220;Nonlinear Optics,&#8221; <em>IEEE J. Sel.&nbsp;Topics in Quantum Electron.<\/em>, June 2002. <\/li><li>C. Headley and G. P. Agrawal, Eds., <em>Raman Amplification in Fiber Optical Communication Systems<\/em> (Academic Press, San Diego, CA, 2005). <\/li><li>B. P. Pal, A. Sharma, G. P. Agrawal, and C. Fabre, Eds., Special issue  on &#8220;Guided Wave Optics: Physics, Technology, and Applications,&#8221; <em>Applied Optics<\/em>, November 2009. <\/li><li>P. Kelly, G. P. Agrawal, M. Bass, J. Hecht. and C. Stroud, Eds., OSA Century of Optics Optics (The Optical Society, 2016); to celebrate OSA\u2019s Centennial Anniversary.<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Patents Granted<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal and N. A. Olsson, &#8220;Saturated semiconductor laser amplifier for compensation of optical fiber dispersion,&#8221; U. S. Patent 4,979,234, issued Dec.&nbsp;18, 1990. <\/li><li>G. P. Agrawal and J. R. Marciante, &#8220;Design of filamentation-free, broad-area semiconductor laser,&#8221; Option by Research Corporation Technologies, RCT Disclosure No.&nbsp;060-B007-97, Jan.&nbsp;17, 1997. <\/li><li>G. P. Agrawal, D. N. Maywar, and Y. Nakano, &#8220;Robust All-optical  flip-flop device,&#8221; U.S. Patent No.&nbsp;6,456,417, filed June 9, 2000,  granted September 24, 2002. <\/li><li>H. Lee and G. P. Agrawal, &#8220;Wavelength-division multiplexing device capable of compensating for dispersion and dispersion slope using purely phase-sampled fiber Bragg grating,&#8221; U.S. Patent No.&nbsp;7,082,234, filed Aug.&nbsp;30, 2004; granted July&nbsp;25, 2006. <\/li><li>G. P. Agrawal and D. N. Maywar, &#8220;All-Optical Flip-Flop and Control  Methods Thereof,&#8221; U.S. Patent 7,684,708, filed Sept.&nbsp;8, 2008, issued  March 23, 2010. <\/li><li>G. P. Agrawal and B. Daniel, &#8220;Phase-switched optical flip-flops using  two-input bistable resonators and methods,&#8221; U.S. Patent, Application  14\/062,874, filed October 24, 2013. <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Book Chapters<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal, &#8220;Single-longitudinal-mode semiconductor lasers,&#8221; in <em> Progress in Optics<\/em>, Vol. 26, E.&nbsp;Wolf, Ed.&nbsp;(North-Holland, Amsterdam, 1988), Chap.&nbsp;3, pp.&nbsp;165-225. <\/li><li>G. P. Agrawal, &#8220;Pulse propagation in nonlinear dispersive fibers,&#8221; in <em>The Supercontinuum Laser Source<\/em>, R. R. Alfano, Ed.&nbsp;(Springer-Verlag, New York, 1989), Chap.&nbsp;3, pp.&nbsp;91-116. <\/li><li>G. P. Agrawal, &#8220;Optical solitons,&#8221; in <em>Contemporary Nonlinear Optics<\/em>, G. P. Agrawal and R. W. Boyd, Eds.&nbsp;(Academic Press, San Diego, CA, 1992), Chap.&nbsp;2, pp.&nbsp;41-83. <\/li><li>G. P. Agrawal, &#8220;Semiconductor lasers for optical fiber communications,&#8221; in <em>Fundamentals of Fiber Optics in Telecommunication and Sensor Systems<\/em>, B. P. Pal, Ed.&nbsp;(Wiley Eastern, New Delhi, 1992), Chap.&nbsp;14, pp.&nbsp;333-350. <\/li><li>G. P. Agrawal and N. K. Dutta, &#8220;Distributed feedback InGaAsP lasers,&#8221; in <em>Fundamentals of Fiber Optics in Telecommunication and Sensor Systems<\/em>, B. P. Pal, Ed.&nbsp;(Wiley Eastern, New Delhi, 1992), Chap.&nbsp;15, pp.&nbsp;351-371. <\/li><li>G. P. Agrawal &#8220;Erbium-doped fiber amplifiers,&#8221; in <em>Optoelectronics: Technologies and Applications<\/em>, A. Selvarajan, K. Senai, and V. K. Tripathi, Eds.&nbsp;(SPIE Press, Bellinghanm, WA, 1993), Chap.&nbsp;5, 91-112. <\/li><li>G. P. Agrawal, &#8220;Modern optical communication systems,&#8221; in <em>Trends in Optical Fiber Metrology and Standards<\/em>, O. D. D. Soares, Ed. (Kluwer Academic, Dordrecht, Germany, 1995), pp.&nbsp;593-616. <\/li><li>R.-J. Essiambre and G. P. Agrawal, &#8220;Soliton communication systems,&#8221; in <em>Progress in Optics<\/em>, Vol. 38, E. Wolf, Ed.&nbsp;(North-Holland, Amsterdam, 1997), Chap.&nbsp;4, pp.&nbsp;185-256. <\/li><li>G. P. Agrawal, &#8220;Non-linear refractive index of silica fibers,&#8221; in <em> Properties of Glass and Rare-Earth Doped Glasses for Optical Fibers<\/em>, D. Hewak, Ed.&nbsp;(INSPEC, IEE, London, UK, 1998), pp.&nbsp;17-21. <\/li><li>G. P. Agrawal, &#8220;Nonlinear Fiber Optics,&#8221; in <em>Nonlinear Science at the Dawn of the 21th Century<\/em>, P. L. Christiansen, M. P. S\u00f8rensen, and A. C. Scott, Eds.&nbsp;(Springer, New York, 2000), Chap.&nbsp;9, pp.&nbsp;195-212. <\/li><li>G. P. Agrawal, &#8220;Nonlinear Effects in Optical Fibers,&#8221; in <em> Encyclopedia of Materials: Science and Technology<\/em>, K. H. J. Buschow et al., Eds.&nbsp;(Elsevier, Oxford, UK, 2001). <\/li><li>G. P. Agrawal and D. N. Maywar, &#8220;Semiconductor Optical Amplifiers with Bragg Gratings,&#8221; in <em>Nonlinear Photonic Crystals<\/em>, Eds.&nbsp;R. E. Slusher and B. H. Eggleton (Springer, New York, 2003), Chap.&nbsp;13. <\/li><li>G. P. Agrawal, &#8220;Theory of Raman amplifiers,&#8221; in <em>Raman Amplification in Fiber Optical Communication Systems<\/em>, C. Headley and G. P. Agrawal, Eds.&nbsp;(Academic Press, San Diego, CA, 2005), Chap.&nbsp;2. <\/li><li>F. Yaman, Q. Lin, and G. P. Agrawal, &#8220;Fiber-optic parametric amplifiers for lightwave systems,&#8221; in <em>Guided Wave Optical Components and Devices<\/em>, B. P. Pal, Ed.&nbsp;(Academic Press, San Diego, CA, 2005), Chap.&nbsp;7. <\/li><li>G. P. Agrawal, &#8220;Fiber-Optic Raman Amplifiers,&#8221; in <em>Guided Wave Optical Components and Devices<\/em>, B. P. Pal, Ed.&nbsp;(Academic Press, San Diego, CA, 2005), Chap.&nbsp;9. <\/li><li>G. P. Agrawal, &#8220;Ultrashort pulse propagation in nonlinear dispersive fibers,&#8221; in <em>The Supercontinuum Laser Source<\/em>, 3rd ed., R. R. Alfano, Ed. (Springer, 2016), Chap. 3.<\/li><li>G. P. Agrawal, &#8220;Optical Communication: Its History and Recent Progress,&#8221; in <em>Optics in Our Time<\/em>, M. D. Al-Amri, M. M. El-Gomati and M. S. Zubairy, Eds. (Springer, 2016), Chap. 8.<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Invited Review Papers<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>J. J. Roland and G. P. Agrawal, &#8220;Optical gyroscopes,&#8221; <em>Optics and Laser Technology<\/em><strong>13<\/strong>, 239-244 (1981). <\/li><li>G. P. Agrawal, &#8220;Semiconductor lasers and their applications in optical fiber communications,&#8221; <em>The Physics Teacher<\/em><strong>23<\/strong>, 478-484 (1985). <\/li><li>G. P. Agrawal and N. K. Dutta, &#8220;Distributed feedback InGaAsP lasers,&#8221; <em>J. Inst.&nbsp;Electron.&nbsp;Telecommun.&nbsp;Eng.<\/em><strong>32<\/strong>, 187-195 (1986). <\/li><li>G. P. Agrawal, &#8220;Semiconductor lasers for optical fiber communications,&#8221; <em>J. Inst.&nbsp;Electron.&nbsp;Telecommun.&nbsp;Eng.<\/em><strong>32<\/strong>, 178-186 (1986). <\/li><li>G. H. M. van Tartwijk and G. P. Agrawal, &#8220;Laser instabilities: A modern perspective,&#8221; <em>Prog.&nbsp;Quantum Electron.<\/em><strong>22<\/strong>, 43-122 (1998). <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Nonlinear silicon photonics: Analytical tools (Invited),&#8221; <em>IEEE J. Sel.&nbsp;Topics Quantum Electron.<\/em><strong>16<\/strong>, 200-215 (2010). <\/li><li>G. P. Agrawal, &#8220;Nonlinear fiber optics: Its history and recent progress,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>28<\/strong>, A1-A10 (2011). <\/li><li>A. Barh, B. P. Pal, G. P. Agrawal,  R. K. Varshney, and B. M. A. Rahman, &#8220;Specialty fibers for terahertz generation and transmission: A review,&#8221; IEEE J. Sel. Topics Quantum Electron. <strong>22<\/strong>, 8500215, 1-15 (2016).<\/li><li>G. P. Agrawal, &#8220;Self-imaging in multimode graded-index fibers and its impact on the nonlinear phenomena,&#8221; <em>Opt. Fiber Technol<\/em>. <strong>50<\/strong>, 309-316 (2019).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Invited Conference Papers<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal and C. Flytzanis, &#8220;Active two-beam optical bistability,&#8221; <em>Optical Bistability<\/em>, ed.&nbsp;by C. M. Bowden et al. (Plenum, 1981) pp. 221-236. <\/li><li>H. J. Carmichael and G. P. Agrawal, &#8220;Absorptive and dispersive bistability for a Doppler-broadened medium in a Fabry Perot,&#8221; <em>Optical Bistability<\/em>, ed.&nbsp;by C. M. Bowden et al. (Plenum, 1981) pp. 237-264. <\/li><li>G. P. Agrawal, &#8220;Zeeman-coherence effects in absorptive polarization bistability,&#8221; <em>Optical Bistability II<\/em>, ed.&nbsp;by C. M. Bowden, H. M. Gibbs, and S. L. McCall (Plenum, 1984) pp. 25-30. <\/li><li>G. P. Agrawal, &#8220;Nonperturbative analysis of optical double resonance with application to phase conjugation,&#8221; in <em>Coherence and Quantum Optics V<\/em>, ed.&nbsp;by L. Mandel and E. Wolf (Plenum, 1984) pp. 31-36. <\/li><li>P. L. Baldeck, R. R. Alfano, and G. P. Agrawal. &#8220;Generation of  sub-100-fs pulses at 532 nm from modulation instability induced by  cross-phase modulation in optical fibers,&#8221; in <em>Ultrafast Phenomena V<\/em>, ed.&nbsp;by T. Yajima et al. (Springer, 1988) pp. 53-55. <\/li><li>G. P. Agrawal, &#8220;Cooperative modulation instability in dispersive nonlinear media,&#8221; <em>Coherence and Quantum Optics VI<\/em>, ed.&nbsp;by J. H. Eberly et al. (Plenum, 1990), pp. 17-21. <\/li><li>G. P. Agrawal, &#8220;Noise in Semiconductor lasers and its impact on optical communication systems,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>1376<\/strong>, 224-235 (1991). <\/li><li>G. R. Gray, A. T. Ryan, G. P. Agrawal, and E. C. Gage, &#8220;Optical  feedback-induced chaos and its control in semiconductor lasers,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>2039<\/strong>, 45-57 (1993). <\/li><li>C. M. Bowden and G. P. Agrawal, &#8220;Maxwell-Bloch formulation for semiconductors,&#8221; in <em>Condensed Matter Theories<\/em>, Vol. 10, ed.&nbsp;by M. Casa et al. (Nova Science Publishers, New York, 1995). <\/li><li>G. P. Agrawal and A. T. Ryan, &#8220;Ultrashort pulse propagation in nonlinear planar optical waveguides,&#8221; in <em>Guided-Wave Optoelectronics<\/em>, ed.&nbsp;by T. Tamir et al. (Plenum, New York, 1995), pp. 391-398. <\/li><li>S. Radic, N. George, and G. P. Agrawal, &#8220;Phase-shifted nonlinear periodic structures,&#8221; in <em>Guided-Wave Optoelectronics<\/em>, ed.&nbsp;by T. Tamir et al. (Plenum, New York, 1995), pp. 399-406. <\/li><li>J. R. Marciante and G. P. Agrawal, &#8220;Beam filamentation and its control in high-power semiconductor lasers,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>3283<\/strong>, 302-313 (1998). <\/li><li>J. Law and G. P. Agrawal, &#8220;Noise Properties of index-guided vertical-cavity surface-emitting semiconductor lasers,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>3625<\/strong>, 404-413 (1999). <\/li><li>P. M. Goorjian, C. Z. Ning, and G. P. Agrawal, &#8220;Transverse mode dynamics of VCSELs undergoing current modulation,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>3944<\/strong>, 284-291 (2000). <\/li><li>P. M. Goorjian, C. Z. Ning, and G. P. Agrawal, &#8220;Spatial dynamics of VCSEL arrays,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>4283<\/strong>, 287-292  (2001). <\/li><li>J. Zhang&nbsp;Q. Lin, G. Piredda, R. W. Boyd, G. P. Agrawal, and P. M.  Fauchet, &#8220;Optical soliton in silicon-on-insulator waveguides,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>6898<\/strong>, 68980X(1-8) (2008). <\/li><li>P. P. Baveja, A. M. Kaplan, D. M. Maywar, and G. P. Agrawal, &#8220;Pulse  amplification in semiconductor optical amplifiers with ultrafast  gain-recovery times,&#8221; <em>Proc.&nbsp;SPIE <\/em><strong>7598<\/strong>, 759817(1-11) (2010). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published from 1973-1976<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li> A. K. Jaiswal, G. P. Agrawal, and C. L. Mehta, &#8220;Coherence Functions in the far-field diffraction plane,&#8221; <em>Nouvo Cimento<\/em><strong>15<\/strong>, 295-307 (1973).  <\/li><li>G. P. Agrawal and C. L. Mehta, &#8220;Higher-order angular coherence functions,&#8221; <em>Nouvo Cimento<\/em><strong>18<\/strong>, 265-276 (1973).  <\/li><li>G. P. Agrawal, A. K. Ghatak, and C. L. Mehta, &#8220;Propagation of partially coherent beams through SELFOC fibers,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>12<\/strong>, 333-337 (1974).  <\/li><li>G. P. Agrawal and C. L. Mehta, &#8220;Dynamics of parametric processes with a trilinear Hamiltonian,&#8221; <em>J. Phys. A<\/em><strong>7<\/strong>, 607-616 (1974).  <\/li><li>G. P. Agrawal and C. L. Mehta, &#8220;Parametric interaction of an arbitrary incident signal,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>12<\/strong>, 1513-1518 (1975).   <\/li><li>G. P. Agrawal and C. L. Mehta, &#8220;Angular spectrum approach to wave propagation in inhomogeneous media,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>14<\/strong>, 88-91 (1975).  <\/li><li>G. P. Agrawal, &#8220;Imaging characteristics of square-law media,&#8221; <em> Nouv.&nbsp;Rev.&nbsp;Optique<\/em><strong>7<\/strong>, 299-303 (1976).   <\/li><li>G. P. Agrawal and C. Flytzanis, &#8220;Delocalization and superalternation effects in the nonlinear susceptibilities of one-dimensional systems,&#8221; <em>Chem.&nbsp;Phys.&nbsp;Lett.<\/em><strong>44<\/strong>, 366-370 (1976). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published from 1977-1980<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>C. Cojan, G. P. Agrawal, and C. Flytzanis, &#8220;Optical properties of one-dimensional semiconductors and conjugated polymers,&#8221; <em>Phys.&nbsp;Rev. B <\/em><strong>15<\/strong>, 909-925 (1977).<\/li><li>G. P. Agrawal and C. L. Mehta, &#8220;Ordering of the exponential of a quadratic in boson operators,&#8221; <em>J. Math.&nbsp;Phys.<\/em><strong>18<\/strong>, 408-412 (1977).   <\/li><li>G. P. Agrawal, C. Cojan, and C. Flytzanis, &#8220;Chain-pairing effects in one-dimensional conjugated polymers and semiconductors,&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>38<\/strong>, 711-715 (1977).   <\/li><li>C. Flytzanis, G. P. Agrawal and C. Cojan, &#8220;Optical nonlinearities in polydiacetylene polymers: Chain-pairing effects,&#8221; <em>Nuovo Cimento<\/em><strong>39<\/strong>, 488-493 (1977).   <\/li><li>G. P. Agrawal and C. L. Mehta, &#8220;Evanescent waves and the van Cittert-Zernike theorem in cylindrical geometry,&#8221; <em>Pramana<\/em><strong>9<\/strong>, 155-161 (1977).   <\/li><li>G. P. Agrawal, C. Cojan, and C. Flytzanis, &#8220;Nonlinear optical properties of one-dimensional semiconductors and conjugated polymers,&#8221; <em>Phys.&nbsp;Rev. B <\/em><strong>17<\/strong>, 776-789 (1978).   <\/li><li>G. P. Agrawal, &#8220;Phase determination by conjugate wavefront generation,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>68<\/strong>, 1135 (1978).   <\/li><li>G. P. Agrawal and D. N. Pattanayak, &#8220;Gaussian beam propagation beyond the paraxial approximation,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>69<\/strong>, 575-578 (1979).   <\/li><li>G. P. Agrawal and H. J. Carmichael, &#8220;Optical bistability through nonlinear dispersion and absorption,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>19<\/strong>, 2074-2086 (1979).   <\/li><li>W. H. Louisell, M. Lax, G. P. Agrawal, and H. W. Gatzke, &#8220;Simultaneous forward and backward integration for standing waves in a resonator,&#8221; <em>Appl.&nbsp;Opt.<\/em><strong>18<\/strong>, 2730-2731 (1979).   <\/li><li>M. Lax, G. P. Agrawal, and W. H. Louisell, &#8220;Continuous Fourier-transform spline solution of unstable resonator field distribution,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>4<\/strong>, 303-305 (1979).   <\/li><li>G. P. Agrawal and M. Lax, &#8220;Effects of interference on gain saturation in laser resonators,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>69<\/strong>, 1717-1719 (1979).   <\/li><li>G. P. Agrawal, M. Lax and J. H. Batteh, &#8220;Electromagnetic pulse propagation in the atmosphere,&#8221; <em>Modeling and Simulation<\/em>, vol. 10, part 3, ed. by W. G. Vogt and M. H. Mickle (Instrument Society of America, Pittsburgh, 1979) pp. 1241-1244.   <\/li><li>G. P. Agrawal and C. Flytzanis, &#8220;Two-photon double-beam optical bistability,&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>44<\/strong>, 1058-1061 (1980).   <\/li><li>G. P. Agrawal and H. J. Carmichael, &#8220;Inhomogeneous broadening and the mean-field approximation for optical bistability in a Fabry-Perot,&#8221; <em>Opt. Acta.<\/em><strong>27<\/strong>, 651-660 (1980).   <\/li><li>D. N. Pattanayak and G. P. Agrawal, &#8220;Representation of vector electromagnetic beams,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>22<\/strong>, 1159-1164 (1980).   <\/li><li>H. J. Carmichael and G. P. Agrawal, &#8220;Steady-state formulation of optical bistability for a Doppler-broadened medium in a Fabry-Perot,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>34<\/strong>, 293-299 (1980). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1981<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>D. N. Pattanayak, G. P. Agrawal, and J. L. Birman, &#8220;Resonance-enhanced transient reflectivity via exciton polaritons,&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>46<\/strong>, 174-177 (1981).   <\/li><li>M. Lax, J. H. Batteh and G. P. Agrawal, &#8220;Channeling of intense electromagnetic beams,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>52<\/strong>, 109-125 (1981).   <\/li><li>G. P. Agrawal and C. Flytzanis, &#8220;Bistability and hysteresis in phase-conjugated reflectivity,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-17<\/strong>, 374-380 (1981).   <\/li><li>G. P. Agrawal, &#8220;Second-harmonic generation with arbitrary pump-beam profiles,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>23<\/strong>, 1863-1868 (1981).   <\/li><li>G. P. Agrawal, C. Flytzanis, R. Frey, and F. Pradere, &#8220;Bistable reflectivity of phase-conjugated signal using intracavity four-wave mixing,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>38<\/strong>, 492-494 (1981).   <\/li><li>G. P. Agrawal, &#8220;Effect of mode coupling on optical bistability in a bidirectional ring cavity,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>38<\/strong>, 505-507 (1981).   <\/li><li>G. P. Agrawal and M. Lax, &#8220;End correction in the quasi-fast Hankel transform for optical propagation problems,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>6<\/strong>, 171-173 (1981).   <\/li><li>G. P. Agrawal and M. Lax, &#8220;Analytic evaluation of interference effects on laser output in a Fabry-Perot resonator,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>71<\/strong>, 515-519 (1981).   <\/li><li>G. P. Agrawal, &#8220;Atmospheric propagation of high power laser pulses by self-channeling,&#8221; <em>Optics and Laser Tech.<\/em><strong>13<\/strong>, 141-144 (1981).   <\/li><li>G. P. Agrawal, &#8220;Optical bistability in a phase-conjugate Fabry-Perot cavity,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>37<\/strong>, 366-368 (1981).   <\/li><li>P. Aubourg, J. P. Bettini, G. P. Agrawal, P. Cottin, D. Guerin, O. Meunier, and J. L. Boulnois, &#8220;Doppler-free continuous-wave phase-conjugate spectrum of SF<sub>6<\/sub> by resonant degenerate four-wave mixing,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>6<\/strong>, 383-385 (1981).   <\/li><li>G. P. Agrawal and C. Flytzanis, &#8220;Propagation of two optical beams in a two-photon resonant medium,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>38<\/strong>, 216-220 (1981).   <\/li><li>G. P. Agrawal, &#8220;Lasers with three-level absorbers,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>24<\/strong>, 1399-1403 (1981).   <\/li><li>G. P. Agrawal, &#8220;Phase conjugation through two-photon resonant nondegenerate four-wave mixing,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>38<\/strong>, 272-276 (1981).    <\/li><li>J. L. Boulnois, P. Aubourg, and G. P. Agrawal, &#8220;Doppler-free CW phase-conjugate spectrum of SF<sub>6<\/sub> by degenerate four-wave mixing,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-17<\/strong>, Part II, 229-230 (1981).    <\/li><li>G. P. Agrawal and C. Flytzanis, &#8220;Theory of two-photon double-beam optical bistability,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>24<\/strong>, 3173-3181 (1981).   <\/li><li>G. P. Agrawal, &#8220;Phase conjugation and degenerate four-wave mixing in three-level systems,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-17<\/strong>, 2335-2340 (1981). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1982<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal and M. Lax,  &#8220;Fraunhofer diffraction in the beam approximation from two longitudinally separated slits, <em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>72<\/strong>, 164-166 (1982).   <\/li><li>G. P. Agrawal, &#8220;Use of a bidirectional ring cavity for optical bistable devices,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-18<\/strong>, 214-218 (1982).   <\/li><li>G. P. Agrawal, J. L. Birman, D. N. Pattanayak, and A. Puri, &#8220;Transient optical reflectivity from bounded nonlocal media,&#8221; <em>Phys.&nbsp;Rev. B <\/em><strong>25<\/strong>, 2715-2729 (1982).   <\/li><li>G. P. Agrawal and J. L. Boulnois, &#8220;Waveguide resonators with a phase-conjugate mirror,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>7<\/strong>, 159-161 (1982).    <\/li><li>J. L. Boulnois and G. P. Agrawal, &#8220;Mode discrimination and coupling losses in rectangular waveguide resonators with conventional and phase-conjugate mirrors,&#8221;<em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>72<\/strong>, 853-860 (1982).   <\/li><li>P. Mandel and G. P. Agrawal, &#8220;Mode instabilities in a homogeneously broadened ring laser,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>42<\/strong>, 269-274 (1982).   <\/li><li>G. P. Agrawal, &#8220;Phase conjugation in biharmonically pumped two-photon resonant systems,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>42<\/strong>, 366-370 (1982).    <\/li><li>G. P. Agrawal, A. Van Lerberghe, P. Aubourg, and J. L. Boulnois, &#8220;Saturation splitting in the spectrum of resonant degenerate four-wave mixing,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>7<\/strong>, 540-542 (1982).    <\/li><li>G. P. Agrawal and M. Lax, &#8220;Evaluation of Fourier integrals using B-splines,&#8221; <em>Math. Comput.<\/em><strong>39<\/strong>, 535-548 (1982). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1983<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal, &#8220;Resonant intracavity phase conjugation in two and three-level systems,&#8221; <em>J. de Phys.<\/em><strong>44<\/strong>, 125-131 (1983).   <\/li><li>J. L. Boulnois, P. Aubourg, A. Van Lerberghe, and G. P. Agrawal, &#8220;Saturation splitting of phase-conjugate line through resonant degenerate four-wave mixing in SF<sub>6<\/sub>,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>42<\/strong>, 225-227 (1983).   <\/li><li>G. P. Agrawal and M. Lax, &#8220;Free-space wave propagation beyond the paraxial approximation,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>27<\/strong>, 1693-1695 (1983).   <\/li><li>G. P. Agrawal, &#8220;Intracavity resonant degenerate four-wave mixing: Bistability in phase conjugation,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.<\/em><strong>73<\/strong>, 654-660 (1983).   <\/li><li>G. P. Agrawal, W. B. Joyce, R. W. Dixon, and M. Lax, &#8220;Beam-propagation analysis of stripe-geometry semiconductor lasers: Threshold behavior,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>43<\/strong>, 11-13 (1983).   <\/li><li>G. P. Agrawal, &#8220;Phase conjugation in three-level systems,&#8221; <em> Quantum Electronics and Electro-Optics<\/em>, ed. by P. L. Knight (Wiley, Chichester, 1983), pp. 379-383.   <\/li><li>G. P. Agrawal, &#8220;Nonperturbative analysis of Zeeman-coherence effects on resonant phase conjugation,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>8<\/strong>, 359-371 (1983).   <\/li><li>G. P. Agrawal, &#8220;Effect of index antiguiding on the far-field distribution of stripe-geometry lasers,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>47<\/strong>, 283-287 (1983).   <\/li><li>G. P. Agrawal, &#8220;Saturation effects in degenerate four-wave mixing on homogeneously broadened coupled transitions,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>28<\/strong>, 2286-2295 (1983).   <\/li><li>G. P. Agrawal and N. K. Dutta, &#8220;Effect of Auger recombination on the threshold characteristics of gain-guided InGaAsP lasers,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>18<\/strong>, 974-976 (1983). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1984<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>N. K. Dutta, G. P. Agrawal, and M.W. Focht, &#8220;Bistability in coupled-cavity semiconductor lasers,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>44<\/strong>, 30-32 (1984).   <\/li><li>G. P. Agrawal, &#8220;Nonlinear saturated absorption in resonant media: Level-degeneracy-induced polarization effects,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>29<\/strong>, 994-996 (1984).   <\/li><li>G. P. Agrawal, &#8220;Level-degeneracy effects in resonant nonlinear phenomena: Three-level atomic model,&#8221; <em>Pramana<\/em><strong>22<\/strong>, 293-301 (1984).   <\/li><li>G. P. Agrawal, &#8220;Line narrowing in a single-mode injection laser due to external optical feedback,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-20<\/strong>, 468-471 (1984).   <\/li><li>G. P. Agrawal, &#8220;Heuristic approach to spontaneous emission factor of gain-guided lasers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>1<\/strong>, 406-408 (1984).   <\/li><li>G. P. Agrawal and N. K. Dutta, &#8220;Optical bistability in coupled-cavity semiconductor lasers,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>56<\/strong>, 664-669 (1984).   <\/li><li>G. P. Agrawal, N. A. Olsson, N. K. Dutta, &#8220;Reduced chirping in coupled-cavity semiconductor lasers,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>45<\/strong>, 119-121 (1984).   <\/li><li>G. P. Agrawal, &#8220;Lateral analysis of quasi-index-guided injection lasers: Transition from gain to index guiding,&#8221; <em>J. Lightwave Technol.<\/em><strong>2<\/strong>, 537-543 (1984).   <\/li><li>G. P. Agrawal,\u00c4tomic coherence effects in a two-mode laser with coupled transitions,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>30<\/strong>, 884-889 (1984).   <\/li><li>G. P. Agrawal, N. A. Olsson, and N. K. Dutta, &#8220;Effect of fiber-far-end reflections on intensity and phase noise in InGaAsP semiconductor lasers,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>45<\/strong>, 597-599 (1984).   <\/li><li>G. P. Agrawal, &#8220;Fast-Fourier-transform based beam-propagation model for stripe-geometry semiconductor lasers: Inclusion of axial effects,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>56<\/strong>, 3100-3109 (1984).   <\/li><li>G. P. Agrawal, &#8220;Generalized rate equations and modulation characteristics of external-cavity semiconductor lasers,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>56<\/strong>, 3110-3115 (1984). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1985<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>J. L. Boulnois, G. Bret, P. Cottin, A. Van Lerberghe, and G. P. Agrawal, &#8220;Gas-flow-induced controlled unidirectional operation of a CO<sub>2<\/sub> ring laser,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>10<\/strong>, 13-15 (1985).   <\/li><li>G. P. Agrawal, &#8220;Chirp minimization and optimum biasing for current-modulated coupled-cavity semiconductor lasers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>10<\/strong>, 10-13 (1985).   <\/li><li>G. P. Agrawal and N. K. Dutta, &#8220;Polarization characteristics of distributed feedback semiconductor lasers,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>46<\/strong>, 213-215 (1985).   <\/li><li>G. P. Agrawal, &#8220;Coupled-cavity semiconductor lasers under current modulation: Small-signal analysis,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-21<\/strong>, 255-263 (1985).   <\/li><li>M. Lax, G. P. Agrawal, M. Belic, B. J. Coffey, and W. H. Louisell, &#8220;Electromagnetic field distribution in loaded unstable resonators,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;A <\/em><strong>2<\/strong>, 731-742 (1985).   <\/li><li>G. P. Agrawal, &#8220;Power spectrum of directly modulated single-mode semiconductor lasers: Chirp-induced fine structure,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-21<\/strong>, 680-686 (1985).   <\/li><li>G. P. Agrawal and N. K. Dutta, &#8220;Analysis of ridge-waveguide distributed feedback lasers,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-21<\/strong>, 534-538 (1985).   <\/li><li>G. P. Agrawal, &#8220;Lateral-mode analysis of gain-guided and index-guided semiconductor-laser arrays,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>58<\/strong>, 2922-2931 (1985). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1986<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>T. M. Shen and G. P. Agrawal, &#8220;Theoretical analysis of mode-partition noise in single-frequency semiconductor lasers,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>21<\/strong>, 1220-1221 (1986).   <\/li><li>G. P. Agrawal and T. M. Shen, &#8220;Effect of fiber-far-end reflections on the bit error rate in optical communications with single-frequency semiconductor lasers,&#8221; <em>J. Lightwave Technol.<\/em><strong>LT-4<\/strong>, 58-63 (1986).   <\/li><li>M. J. Potasek, G. P. Agrawal, and S. C. Pinault, &#8220;Analytic and numerical study of pulse broadening in nonlinear dispersive optical fibers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>4<\/strong>, 205-212 (1986).   <\/li><li>G. P. Agrawal, N. K. Dutta, P. J. Anthony, &#8220;Linewidth of distributed feedback semiconductor lasers with reflecting facets,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>48<\/strong>, 457-459 (1986).   <\/li><li>G. P. Agrawal and M. J. Potasek, &#8220;Nonlinear pulse distortion in single-mode optical fibers at the zero-dispersion wavelength,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>33<\/strong>, 1765-1776 (1986).   <\/li><li>G. P. Agrawal and T. M. Shen, &#8220;Power penalty due to decision-time jitter in optical communication systems,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>22<\/strong>, 450-451 (1986).   <\/li><li>T. M. Shen and G. P. Agrawal, &#8220;Pulse-shape effects on frequency chirping in single-frequency semiconductor lasers under current modulation,&#8221; <em>J. Lightwave Technol.<\/em><strong>LT-4<\/strong>, 497-503 (1986).   <\/li><li>G. P. Agrawal and M. J. Potasek, &#8220;Effect of frequency chirping on the performance of optical communication systems,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>11<\/strong>, 318-320 (1986).   <\/li><li>G. P. Agrawal, &#8220;Effect of nonlinear gain on single-frequency behavior of semiconductor lasers,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>22<\/strong>, 696-687 (1986).   <\/li><li>G. P. Agrawal, &#8220;Longitudinal-mode stabilization in semiconductor lasers with wavelength-selective feedback,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>59<\/strong>, 3958-3961 (1986).   <\/li><li>M. J. Potasek and G. P. Agrawal, &#8220;Power-dependent enhancement in repeater spacing for dispersion-limited optical communication systems,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>22<\/strong>, 759-760 (1986).   <\/li><li>G. P. Agrawal and T. M. Shen, &#8220;Importance of rapid damping of relaxation oscillations for high-performance optical communication systems,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>22<\/strong>, 1087-1088 (1986).   <\/li><li>C. L. Reynolds, W. R. Holbrook, J. A. Shimer, S. M. Tharaldsen, G. P. Agrawal, and H. Temkin, &#8220;Experimental verification of the transition from gain- to index-guiding in a rib-waveguide AlGaAs laser,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>22<\/strong>, 1286-1287 (1986).   <\/li><li>G. P. Agrawal, &#8220;Effect of gain nonlinearities on period doubling and chaos in directly modulated semiconductor lasers,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>49<\/strong>, 1013-1015 (1986). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1987<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal, &#8220;Four-wave mixing and Phase conjugation in semiconductor laser media,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>12<\/strong>, 260-262 (1987).   <\/li><li>T. M. Shen and G. P. Agrawal, &#8220;Computer simulation and noise analysis of system performance of 1.55-\u03bcm single-frequency semiconductor lasers,&#8221; <em>J. Lightwave Technol.<\/em><strong>LT-5<\/strong>, 653-659 (1987).   <\/li><li>G. P. Agrawal, &#8220;Gain nonlinearities in semiconductor lasers: Theory and application to distributed feedback lasers,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-2<\/strong>, 860-868 (1987).   <\/li><li>G. P. Agrawal, &#8220;Highly nondegenerate four-wave mixing in semiconductor lasers due to spectral hole-burning,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>51<\/strong>, 302-304 (1987).   <\/li><li>G. P. Agrawal, &#8220;Modulation instability induced by cross-phase modulation,&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>59<\/strong>, 880-883 (1987).   <\/li><li>G. P. Agrawal, &#8220;Evaluation of cross-talk penalty in multichannel ASK heterodyne optical communication systems,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>23<\/strong>, 906-908 (1987).   <\/li><li>A. W. Yu, G. P. Agrawal, and R. Roy, &#8220;Noise propagation from pump to secondary lasers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>12<\/strong>, 806-808 (1987).   <\/li><li>M. J. Potasek and G. P. Agrawal, &#8220;Self-amplitude modulation of optical pulses in nonlinear dispersive fibers,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>36<\/strong>, 3862-3867 (1987).   <\/li><li>G. P. Agrawal, &#8220;Amplifier-induced crosstalk in multichannel coherent lightwave systems,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>22<\/strong>, 1175-1177 (1987). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1988<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>G. P. Agrawal, &#8220;Population pulsations and nondegenerate four-wave mixing in semiconductor lasers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>5<\/strong>, 149-159 (1988).  <\/li><li>G. P. Agrawal and C. H. Henry, &#8220;Modulation performance of a semiconductor laser coupled to an external high-Q resonator,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>QE-24<\/strong>, 134-142 (1988).  <\/li><li>G. P. Agrawal, &#8220;Spectral hole-burning and gain saturation in semiconductor lasers: strong-signal theory,&#8221; <em>J. Appl.&nbsp;Phys.<\/em><strong>63<\/strong>, 1232-1235 (1988).  <\/li><li>G. P. Agrawal, &#8220;Mode-partition noise and intensity correlation in a two-mode semiconductor laser,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>37<\/strong>, 2488-2494 (1988).  <\/li><li>G. P. Agrawal and R. Roy, &#8220;Effect of injection-current fluctuations on the spectral linewidth of semiconductor lasers,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>37<\/strong>, 2495-2501 (1988).  <\/li><li>G. P. Agrawal, P. J. Anthony, and T. M. Shen, &#8220;Dispersion penalty for lightwave systems with multimode semiconductor lasers,&#8221; <em>J. Lightwave Technol.<\/em><strong>LT-6<\/strong>, 620-625 (1988).  <\/li><li>P. L. Baldeck, R. R. Alfano, and G. P. Agrawal. &#8220;Induced-frequency shift of copropagating ultrashort optical pulses,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>52<\/strong>, 1939-1941 (1988).  <\/li><li>G. P. Agrawal, J. E. Geusic, and P. J. Anthony, &#8220;Distributed feedback lasers with multiple phase-shift regions,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>53<\/strong>, 178-179 (1988).  <\/li><li>G. P. Agrawal and A. H. Bobeck, &#8220;Modeling of distributed feedback semiconductor lasers with axially varying parameters,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>24<\/strong>, 2407-2414 (1988). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 1999<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>N. M. Litchinister, B. J. Eggleton, C. M. de Srerke, A. Aceves, and G. P. Agrawal, &#8220;Interaction of Bragg solitons in fiber gratings,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>16<\/strong>, 18-23 (1999). <\/li><li>M. Vallet, M. Brunel, F. Bretenaker, M. Alouini, A. Le Floch, and  G. P. Agrawal, &#8220;Polarization and self-modulated lasers with circular  eigenstates,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>74<\/strong>, 3266-3268 (1999).   <\/li><li>Z. M. Liao and G. P. Agrawal, &#8220;High-bit-rate soliton transmission using distributed amplification and dispersion management,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>11<\/strong>, 818-820 (1999).  <\/li><li>N. M. Litchinister, W. Kr\u00f3likowaski, N. N. Akhmediev, and G. P.  Agrawal, &#8220;Asymmetric partially coherent solitons in saturable nonlinear  media,&#8221; <em>Phys.&nbsp;Rev. E <\/em><strong>60<\/strong>, 2377-2380 (1999).   <\/li><li>T. Lakoba and G. P. Agrawal, Effect of third-order dispersion on dispersion-managed solitons,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>16<\/strong>, 1332-1343 (1999).   <\/li><li>G. P. Agrawal, &#8220;Far-field diffraction of pulsed optical beams in dispersive media,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>167<\/strong>, 15-22 (1999). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2000<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>D. N. Maywar, G. P. Agrawal, and Y. Nakano, &#8220;Robust optical control of an optical-amplifier-based flip-flop,&#8221; <em>Opt.&nbsp;Express<\/em><strong>6<\/strong>, 75-81 (2000).   <\/li><li>Z. M. Liao, C. J. McKinstrie, and G. P. Agrawal, &#8220;Importance of  prechirping in constant-dispersion fiber links with large amplifier  spacing,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>17<\/strong>, 514-518 (2000).  <\/li><li>S. Raghavan and G. P. Agrawal, &#8220;Switching and self-trapping dynamics of Bose-Einstein solitons,&#8221; <em>J. Mod.&nbsp;Opt.<\/em><strong>47<\/strong>, 1155-1169 (2000).  <\/li><li>D. N. Maywar, Y. Nakano, and G. P. Agrawal, &#8220;1.31-to-1.55 \u03bcm  wavelength conversion by optically pumping a distributed feedback  amplifier,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>12<\/strong>, 858-860 (2000).  <\/li><li>S. Raghavan and G. P. Agrawal, &#8220;Spatiotemporal solitons in inhomogeneous nonlinear media,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>180<\/strong>, 377-382 (2000).   <\/li><li>Z. M. Liao and G. P. Agrawal, &#8220;Mode-partition noise in fiber lasers,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>36<\/strong>, 1188-1189 (2000).  <\/li><li>G. P. Agrawal and E. Wolf, &#8220;Propagation-induced polarization changes in partially coherent optical beams&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;A <\/em><strong>17<\/strong>, 2019-2023 (2000).  <\/li><li>T. Lakoba and G. P. Agrawal, &#8220;Optimization of the average-dispersion range for long-haul dispersion-managed soliton systems,&#8221; <em>J. Lightwave Technol.<\/em><strong>18<\/strong>, 1504-1512 (2000). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2001<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>N. M. Litchinister, C. J. McKinstrie, C. M. de Sterke, and G. P.  Agrawal, &#8220;Spatiotemporal instabilities in nonlinear bulk media with  Bragg gratings,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>18<\/strong>, 45-54 (2001).  <\/li><li>D. N. Maywar, G. P. Agrawal, and Y. Nakano, &#8220;All-optical hysteresis  control via cross-phase modulation in semiconductor optical  amplifiers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>18<\/strong>, 1003-1013 (2001).  <\/li><li>Z. M. Liao and G. P. Agrawal, &#8220;Role of distributed amplification in designing high-capacity soliton communication systems,&#8221; <em>Opt.&nbsp;Express<\/em><strong>9<\/strong>, 66-71 (2001).  <\/li><li>J. Santhanam, C. J. McKinstrie, T. Lakoba, and G. P. Agrawal,  &#8220;Effects of pre- and post-compensation on timing jitter in  dispersion-managed systems,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>26<\/strong>, 1131-1133 (2001). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2002<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>E. Poutrina and G. P. Agrawal, &#8220;Effect of distributed Raman  amplification on timing jitter in dispersion-managed lightwave systems,&#8221;  <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>14<\/strong>, 39-40 (2002).  <\/li><li>C. J. McKinstrie, J. Santhanam, and G. P. Agrawal, &#8220;Gordon-Haus  timing jitter in dispersion-managed systems with lumped amplification:  analytical approach,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>19<\/strong>, 640-649 (2002).   <\/li><li>E. Poutrina and G. P. Agrawal, &#8220;Design rules for dispersion-managed soliton Systems,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>206<\/strong>, 193-200 (2002).  <\/li><li>J. Santhanam and G. P. Agrawal, &#8220;Raman-induced timing jitter in dispersion-managed optical communication systems,&#8221; <em>IEEE J. Sel.&nbsp;Topics Quantum Electron.<\/em><strong>7<\/strong>, 632-639 (2002).   <\/li><li>E. Poutrina and G. P. Agrawal, &#8220;Timing jitter in  dispersion-managed systems with distributed, lumped, and hybrid  amplification,&#8221; <em>J. Lightwave Technol.<\/em><strong>20<\/strong>, 762-769 (2002).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Pulse broadening induced by dispersion fluctuations in optical fibers,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>206<\/strong>, 313-317 (2002).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Polarization mode dispersion-induced fluctuations during Raman amplification in optical fibers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>27<\/strong>, 2194-2196 (2002). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2003<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>A. Levent, S. G. Rajeev, F. Yaman, and G. P. Agrawal, &#8220;Nonlinear theory of polarization-mode dispersion for fiber solitons,&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>90<\/strong>, 013902 (2003).  <\/li><li>J. Santhanam and G. P. Agrawal, &#8220;Reduced timing jitter in  dispersion-managed lightwave systems through parametric amplification,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>20<\/strong>, 284-291 (2003).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Correlation theory of polarization-mode dispersion in optical fibers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>19<\/strong>, 292-301 (2003).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Statistics of polarization-dependent gain in fiber-based Raman amplifiers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>28<\/strong>, 227-229 (2003).  <\/li><li>H. Lee and G. P. Agrawal, &#8220;Nonlinear switching of optical pulses in fiber Bragg gratings,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>39<\/strong>, 508-515 (2003).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Vector theory of stimulated Raman scattering and its application to fiber-based Raman amplifiers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>20<\/strong>, 1616-1631 (2003).   <\/li><li>E. Poutrina and G. P. Agrawal, &#8220;Impact of dispersion fluctuations on 40-Gb\/s dispersion-managed lightwave systems,&#8221; <em>J. Lightwave Technol.<\/em><strong>21<\/strong>, 990-996 (2003).   <\/li><li>S. Radic, C. J. McKinstrie, R. M. Jopson, J. C. Centanni, Q. Lin  and G. P. Agrawal, &#8220;Record performance of parametric amplifier  constructed with highly nonlinear fiber,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>39<\/strong>, 838-840 (2003).  <\/li><li>H. Lee and G. P. Agrawal, &#8220;Purely phase-sampled fiber Bragg  gratings for broadband dispersion and dispersion-slope compensation,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>15<\/strong>, 1091-1093 (2003).  <\/li><li>J. Santhanam and G. P. Agrawal, &#8220;Raman-induced spectral shifts in optical fibers: General theory based on the moment method,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>222<\/strong>, 413-420 (2003).  <\/li><li>H. Lee and G. P. Agrawal, &#8220;Suppression of stimulated Brillouin scattering in optical fibers using fiber Bragg gratings,&#8221; <em>Opt.&nbsp;Express<\/em><strong>11<\/strong>, 3467-3474 (2003).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Impact of polarization mode dispersion  on measurements of zero-dispersion wavelength through four-wave mixing,&#8221;  <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>16<\/strong>, 1719-1721 (2003). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2004<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>F. Yaman, Q. Lin, and G. P. Agrawal, &#8220;Effects of polarization-mode  dispersion in dual-pump fiber-optic parametric amplifiers,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>16<\/strong>, 431-433 (2004).  <\/li><li>H. Lee and G. P. Agrawal, &#8220;Add-drop multiplexers and interleavers  with broadband chromatic dispersion compensation based on purely  phase-sampled fiber Bragg gratings,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>16<\/strong>, 635-637 (2004).  <\/li><li>S. A. Ponomarenko, G. P. Agrawal and E. Wolf, &#8220;Energy spectrum of a non-stationary ensemble of pulses&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>29<\/strong>, 394-396 (2004).   <\/li><li>F. Yaman, Q. Lin, and G. P. Agrawal, &#8220;Impact of dispersion fluctuations on dual-pump fiber-optic parametric amplifiers,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>16<\/strong>, 1292-1294 (2004).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Effects of polarization-mode dispersion  on cross-phase modulation in dispersion-managed WDM systems,&#8221; <em>J. Lightwave Technol.<\/em><strong>22<\/strong>, 977-987 (2004).  <\/li><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Asymmetric incoherent vector solitons&#8221; <em>Phys.&nbsp;Rev. E <\/em><strong>69<\/strong>, 036604 (2004).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Effects of polarization-mode dispersion  on fiber-Based parametric amplification and wavelength conversion,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>29<\/strong>, 1114-1116 (2004).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Vector theory of four-wave mixing: Polarization effects in fiber-optic parametric amplifiers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>21<\/strong>, 1216-1224 (2004).  <\/li><li>N. G. Usechak, J. D, Zuegel and G. P. Agrawal, &#8220;Tunable, high repetition-rate, mode-locked, ytterbium fiber laser,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>29<\/strong>, 1360-1362 (2004).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Vector Theory of Cross-Phase Modulation: Role of Nonlinear Polarization Rotation,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>40<\/strong>, 958-964 (2004).  <\/li><li>S. A. Ponomarenko, N. M.&nbsp;Litchinitser and G. P. Agrawal, &#8220;Theory of  incoherent optical solitons: Beyond the mean-field approximation&#8221; <em>Phys.&nbsp;Rev. E <\/em><strong>70<\/strong>, 015603 (2004).  <\/li><li>F. Lu, Q. Lin, W. H. Knox, and G. P. Agrawal, &#8220;Vector soliton fission,&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>93<\/strong>, Article 183901 (2004).  <\/li><li>Q. Lin, K. Wright, G. P. Agrawal, and C. Guo, &#8220;Spectral  responsivity and efficiency of metal-based femtosecond autocorrelation  technique,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>242<\/strong>, 279-283 (2004).  <\/li><li>H. Lee and G. P. Agrawal, &#8220;Bandwidth equalization of purely  phase-sampled fiber Bragg gratings for broadband dispersion and  dispersion slope compensation,&#8221; <em>Opt.&nbsp;Express<\/em><strong>12<\/strong>, 5595-5602 (2004).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Impact of Fiber Birefringence on Optical Switching with Nonlinear Optical Loop Mirrors,&#8221; <em>IEEE J. Sel.&nbsp;Topics Quantum Electron.<\/em><strong>10<\/strong>, 1107-1114 (2004).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2005<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>N. G. Usechak and G. P. Agrawal, &#8220;Semi-analytic technique for analyzing mode-locked lasers,&#8221; <em>Opt.&nbsp;Express<\/em><strong>13<\/strong>, 2075-2081 (2005).   <\/li><li>Q. Lin and G. P. Agrawal, &#8220;Intrapulse depolarization in optical fibers: A classical analog of spin decoherence,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>30<\/strong>, 821-823 (2005).  <\/li><li>G. Ropars, M. Vallet, M. Brunel, A. Le Floch, and G. P. Agrawal, &#8220;Asymmetric Russian-doll model for semiconductor lasers, <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>17<\/strong>, 747-749 (2005).   <\/li><li>F. Yaman, Q. Lin, G. P. Agrawal, and S. Radic &#8220;Pump-Noise Transfer  in Dual-Pump Fiber-Optic Parametric Amplifiers: Walk-off Effects,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>30<\/strong>, 1048-1050 (2005).  <\/li><li>Y. Deng, Q. Lin, F. Lu, G. P. Agrawal and W. H. Knox, &#8220;Broadly  tunable femtosecond parametric oscillator using a photonic crystal  fiber,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>30<\/strong>, 1234-1236 (2005).  <\/li><li>N. G. Usechak, G. P. Agrawal, and J. D, Zuegel, &#8220;FM mode-locked fiber lasers in the autosoliton regime,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>41<\/strong>, 753-761 (2005).   <\/li><li>F. Yaman, Q. Lin, G. P. Agrawal, and S. Radic, &#8220;Impact of  pump-phase modulation on dual-pump fiber-optic parametric amplifiers and  wavelength convertors,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>17<\/strong>, 2053-2055 (2005).  <\/li><li>Q. Lin, R. Jiang, C. F. Marki, C. J. McKinstrie, R. Jopson, J.  Ford, G. P. Agrawal, and S. Radic, &#8220;40-Gb\/s optical switching and  wavelength multicasting in a two-pump parametric device,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>17<\/strong>, 2376-2378 (2005).  <\/li><li>N. G. Usechak and G. P. Agrawal, &#8220;Rate-equation approach for mode-locked lasers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>22<\/strong>, 2570-2580 (2005). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2006<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>A. N. Pinto, J. F. da Rocha, Q. Lin, and G. P. Agrawal, &#8220;Optical     versus electrical dispersion compensation: Role of Timing Jitter,&#8221; <em>J. Lightwave Technol.<\/em><strong>24<\/strong>, 387-395 (2006).   <\/li><li>Q. Lin, F. Yaman, and G. P. Agrawal, &#8220;Raman-Induced polarization-dependent gain in parametric amplifiers pumped with orthogonally polarized Lasers,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>18<\/strong>, 197-199 (2006).  <\/li><li>H. Roychowdhury, G. P. Agrawal, and E. Wolf, &#8220;Changes in the spectrum, in the spectral degree of polarization and in the spectral degree of coherence of a partially coherent beam propagating through a gradient-index fiber,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;A<\/em>, <strong>23<\/strong>, 940-948 (2006).  <\/li><li>Q. Lin, F. Yaman, and G. P. Agrawal, &#8220;Photon-Pair Generation by Four-Wave Mixing inside Optical Fibers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>31<\/strong>, 1286-1288 (2006).  <\/li><li>L. Yin, Q. Lin, and G. P. Agrawal, &#8220;Dispersion tailoring and soliton propagation in silicon waveguides,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>31<\/strong>, 1295-1297 (2006).  <\/li><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Linear optical bullets&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>261<\/strong>, 1-4 (2006).  <\/li><li>Q. Lin, J. Zhang, P. M. Fauchet, and G. P. Agrawal, &#8220;Ultrabroadband parametric generation and wavelength conversion in silicon waveguides,&#8221; <em>Opt.&nbsp;Express<\/em><strong>14<\/strong>, 4786-4799 (2006).  <\/li><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Do spatial soliton-like     self-similar waves exist in nonlinear optical media?&#8221; <em>Phys.&nbsp;Rev.&nbsp;Lett.<\/em><strong>97<\/strong>, 013901 (2006).  <\/li><li>F. Yaman, Q. Lin, S. Radic, and G. P. Agrawal, &#8220;Fiber-Optic parametric amplifiers in the presence of polarization-mode dispersion and polarization-dependent loss,&#8221; <em>J. Lightwave Technol.<\/em><strong>24<\/strong>, 3088-3096 (2006).  <\/li><li>Q. Lin, and G. P. Agrawal, &#8220;Raman response function for silica fibers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>31<\/strong>, 3086-3088 (2006).  <\/li><li>Q. Lin, and G. P. Agrawal, &#8220;Silicon waveguides for creating quantum-correlated photon pairs,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>31<\/strong>, 3140-3142 (2006).  <\/li><li>F. Yaman, Q. Lin, and G. P. Agrawal, &#8220;A novel design for polarization-independent single-pump fiber-optic parametric amplifiers,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>15<\/strong>, 2335-2337 (2006).  <\/li><li>G. Ropars, A. Le Floch, and G. P. Agrawal, &#8220;Spectral and spatial     dynamics in InGaN blue-violet lasers, <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>89<\/strong>, 241128(1-3) (2006). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2007<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>Q. Lin, F. Yaman, and G. P. Agrawal, &#8220;Photon-Pair Generation in Optical Fibers through Four-Wave Mixing: Role of Raman Scattering and Pump Polarization,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>75<\/strong>, 023803(1-20) (2007).  <\/li><li>L. Yin, Q. Lin, and G. P. Agrawal, &#8220;Soliton fission and supercontinuum generation in silicon waveguides,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>32<\/strong>, 391-393 (2007).  <\/li><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Interactions of chirped and chirp-free similaritons in optical fiber amplifiers,&#8221; <em>Opt.&nbsp;Express<\/em><strong>15<\/strong>, 2963-2973 (2007).  <\/li><li>J. Zhang, Q. Lin, G. Piredda, R. W. Boyd, G. P. Agrawal, and P. M. Fauchet, &#8220;Observation of optical solitons in a silicon waveguide,&#8221; <em>Opt.&nbsp;Express<\/em><strong>15<\/strong>, 7682-7688 (2007).  <\/li><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Optical similaritons in nonlinear waveguides,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>32<\/strong>, 1659-1661 (2007).  <\/li><li>Q. Lin, J. Zhang, G. Piredda, R. W. Boyd, P. M. Fauchet, and G. P. Agrawal, &#8220;Dispersion of silicon nonlinearity in the near infrared region,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>91<\/strong>, 021111 (2007).  <\/li><li>L. Yin and G. P. Agrawal, &#8220;Impact of two-photon absorption on self-phase modulation in silicon waveguides&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>32<\/strong>, 2031-2033 (2007).  <\/li><li>J. Zhang, Q. Lin, G. Piredda, R. W. Boyd, P. M. Fauchet, and G. P. Agrawal, &#8220;Anisotropic nonlinear response of silicon in the near-infrared region,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>91<\/strong>, 071113 (2007).  <\/li><li>W. Huang, S. A. Ponomarenko, M. Cada, and G. P. Agrawal, &#8220;Polarization changes of partially coherent pulses propagating in optical fibers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>24<\/strong>, 3063-3068 (2007).  <\/li><li>D. N. Maywar, K. P. Solomon, and G. P. Agrawal, &#8220;Remote optical control of an optical flip-flop,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>32<\/strong>, 3260-3262 (2007).  <\/li><li>Q. Lin, O. J. Painter, and G. P. Agrawal, &#8220;Nonlinear optical phenomena in silicon waveguides: Modeling and applications (Invited Review),&#8221; <em>Opt.&nbsp;Express<\/em><strong>15<\/strong>, 16604-16644 (2007). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2008<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Phase-space quality factor for ultrashort-pulse beams,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>33<\/strong>, 767-769 (2008).  <\/li><li>M. Premaratne, D. Nesi\\&#8217;c, and G. P. Agrawal, &#8220;Pulse amplification  and gain recovery in semiconductor optical amplifiers: A systematic  analytical approach,&#8221; <em>J. Lightwave Technol.<\/em><strong>26<\/strong>, 1653-1660 (2008).  <\/li><li>S. A. Ponomarenko and G. P. Agrawal, &#8220;Nonlinear interaction of two  or more similaritons in loss- and dispersion-managed fibers,&#8221;  <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>25<\/strong>, 983-989 (2008).  <\/li><li>A. N. Pinto and G. P. Agrawal, &#8220;Nonlinear interaction betweens signal and noise in optical fibers,&#8221; <em>J. Lightwave Technol.<\/em><strong>26<\/strong>, 1847-1853 (2008).  <\/li><li>S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Femtosecond pulse  propagation in silicon waveguides: Variational approach and its  advantages,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>281<\/strong>, 5889-5893 (2008). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2009<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Raman amplification of  optical pulses in silicon waveguides: effects of finite gain bandwidth,  pulse width, and chirp,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>26<\/strong>, 17-25 (2009).  <\/li><li>A. M. Kaplan, G. P. Agrawal, D. N. Maywar, &#8220;All-optical flip-flop operation of a VCSOA,&#8221; <em>Electron.&nbsp;Lett.<\/em><strong>34<\/strong>, 127-128 (2009).  <\/li><li>L. Yin, J. Zhang, P. M. Fauchet, and G. P. Agrawal, &#8220;Optical  switching using nonlinear polarization rotation inside silicon  waveguides,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>34<\/strong>, 476-478 (2009). <\/li><li> I. D. Rukhlenko, M. Premaratne, C. Dissanayake, and G. P. Agrawal,  &#8220;Continuous-wave Raman amplification in silicon waveguides: beyond the  undepleted pump approximation,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>34<\/strong>, 536-538 (2009).  <\/li><li>S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Dispersive waves emitted  by solitons perturbed by third-order dispersion inside optical fibers,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>79<\/strong>, 023834(1-6) (2009).  <\/li><li>V. Lanticq, S. Jiang, R. Gabet, Y. Jaou\u00ebn, F. Taillade, G. Moreau,  and G. P. Agrawal, &#8220;Self-referenced and single-ended method to measure  Brillouin gain in monomode optical fibers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>34<\/strong>, 1018-1029 (2009).  I<\/li><li>. D. Rukhlenko, C. Dissanayake, M. Premaratne, and G. P. Agrawal,  &#8220;Maximization of net optical gain in silicon-waveguide Raman  amplifiers,&#8221; <em>Opt.&nbsp;Express<\/em><strong>17<\/strong>, 5807-5814 (2009).  <\/li><li>S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Effects of higher-order  dispersion on resonant dispersive waves emitted by solitons,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>34<\/strong>, 2072-2074 (2009).  <\/li><li>I. D. Rukhlenko, M. Premaratne, C. Dissanayake, and G. P. Agrawal,  &#8220;Nonlinear pulse evolution in silicon waveguides: An approximate  analytic approach,&#8221; <em>J. Lightwave Technol.<\/em><strong>27<\/strong>, 3241-3248 (2009).  <\/li><li>S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Perturbation of higher-order solitons by fourth-order dispersion in optical fibers,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>282<\/strong>, 3798-3803 (2009).  <\/li><li>M. Salem and G. P. Agrawal, &#8220;Coupling of stochastic electromagnetic beams into optical fibers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>34<\/strong>, 2829-2831 (2009).  <\/li><li>P. P. Baveja, D. N. Maywar, and G. P. Agrawal, &#8220;Optimization of  all-optical 2R Regenerators operating at 40 Gb\/s: Role of dispersion,&#8221; <em>J. Lightwave Technol.<\/em><strong>27<\/strong>, 3831-3836 (2009).  <\/li><li>C. Dissanayake, I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal,  &#8220;Raman-mediated nonlinear interactions in silicon waveguides:  copropagating and counterpropagating pulses,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>18<\/strong>, 1372-1374 (2009).  <\/li><li>M. Salem and G. P. Agrawal, &#8220;Effects of coherence and polarization  on the coupling of stochastic electromagnetic beams into optical  fibers,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;A <\/em><strong>26<\/strong>, 2452-2458 (2009).  <\/li><li>I. Udagedara, M. Premaratne, I. D. Rukhlenko, H. T. Hatori, and G.  P. Agrawal, &#8220;Unified perfectly matched layer for finite-difference  time-domain modeling of dispersive optical materials,&#8221; <em>Opt.&nbsp;Express<\/em><strong>17<\/strong>, 21179-21190 (2009).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Analytical study of optical bistability in silicon-waveguide resonators,&#8221; <em>Opt.&nbsp;Express<\/em><strong>17<\/strong>, 22124-22137 (2009). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2010<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Analytical study of optical bistability in silicon ring resonators,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>35<\/strong>, 55-57 (2010).  <\/li><li>B. A. Daniel and G. P. Agrawal, &#8220;Dependence of dispersive and  birefringence properties of silicon nanowires on waveguide dimensions,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>35<\/strong>, 190-192 (2010).  <\/li><li>P. P. Baveja, D. M. Maywar, A. M. Kaplan, and G. P. Agrawal,  &#8220;Spectral broadening in ultrafast semiconductor optical amplifiers  induced by gain dynamics and self-phase modulation,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>35<\/strong>, 294-296 (2010).  <\/li><li>I. D. Rukhlenko, C. Dissanayake, M. Premaratne, and G. P. Agrawal,  &#8220;Optimization of Raman Amplification in Silicon Waveguides with Finite  Facet Reflectivities,&#8221; <em>IEEE J. Sel.&nbsp;Topics Quantum Electron.<\/em><strong>16<\/strong>, 226-233 (2010).  <\/li><li>A. Pannipitiya, I. D. Rukhlenko M. Premaratne, H. T. Hattori, and  G. P. Agrawal, &#8220;Improved transmission model for metal-dielectric-metal  plasmonic waveguides with stub structure,&#8221; <em>Opt.&nbsp;Express<\/em><strong>18<\/strong>, 6191-6204 (2010).  <\/li><li>A. M. Kaplan, G. P. Agrawal, D. N. Maywar, &#8220;Optical square-wave clock generation based on an all-optical flip-flop,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>22<\/strong>, 489-491 (2010).  <\/li><li>B. A. Daniel and G. P. Agrawal, &#8220;Vectorial nonlinear pulse propagation in silicon nanowire waveguides: polarization effects,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>27<\/strong>, 956-965 (2010).  <\/li><li>B. Nagaraju, R. K. Varshney, G. P. Agrawal, and B. P. Pal,  &#8220;Parabolic pulse generation in a dispersion-decreasing solid-core  photonic bandgap Bragg fiber,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>283<\/strong>, 2525-2528 (2010).  <\/li><li>J. Y. Lee, L. Yin, G. P. Agrawal, and P. M. Fauchet, &#8220;Ultrafast  Optical switching based on nonlinear polarization rotation in silicon  waveguides,&#8221; <em>Opt.&nbsp;Express<\/em><strong>18<\/strong>, 11514-11523 (2010).  <\/li><li>I. D. Rukhlenko, I. L. Garanovich, M. Premaratne, A. A. Sukhorukov,  G. P. Agrawal, and Y. S. Kivshar, &#8220;Polarization rotation in silicon  waveguides: Analytical modeling and applications,&#8221; <em>IEEE Photonics J.<\/em><strong>2<\/strong>, 423-435 (2010).  <\/li><li>I. D. Rukhlenko, I. Udagedara, M. Premaratne, and G. P. Agrawal,  &#8220;Effect of free carriers on pump-to-signal noise transfer in silicon  Raman amplifiers,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>35<\/strong>, 2343-2345 (2010).  <\/li><li>S. Roy, D. Ghosh, S. K. Bhadra, and G. P. Agrawal, &#8220;Role of  dispersion profile in controlling emission of dispersive waves by  solitons in supercontinuum generation,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>283<\/strong>, 3081-3088 (2010).  <\/li><li>I. D. Rukhlenko, M. Premaratne, I. L. Garanovich, A. A. Sukhorukov,  and G. P. Agrawal, , &#8220;Analytical study of pulse amplification in  silicon Raman amplifiers,&#8221; <em>Opt.&nbsp;Express<\/em><strong>18<\/strong>, 18324-18338 (2010).  <\/li><li>P. P. Baveja, D. M. Maywar, A. M. Kaplan, and G. P. Agrawal,  &#8220;Self-Phase Modulation in semiconductor optical amplifiers: Impact of   amplified spontaneous emission,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>46<\/strong>, 1396-1403 (2010).  <\/li><li>C. Dissanayake, M. Premaratne, I. D. Rukhlenko, and G. P. Agrawal,  &#8220;FDTD modeling of anisotropic nonlinear optical phenomena in silicon  waveguides,&#8221; <em>Opt.&nbsp;Express<\/em><strong>18<\/strong>, 21427-21448 (2010).  <\/li><li>H. Lee and G. P. Agrawal, &#8220;Instabilities in fiber lasers induced by the self-phase modulation and their control,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>46<\/strong>, 1732-738 (2010).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Theory of negative refraction in periodic stratified metamaterials,&#8221; <em>Opt.&nbsp;Express<\/em><strong>18<\/strong>, 27916-27929 (2010). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2011<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li> S. Ghosh, G. P. Agrawal, B. P. Pal, and R. K. Varshney,  &#8220;Localization of light in evanescently coupled disordered waveguide  lattices: Dependence on the input beam profile,&#8221; <em>Opt.&nbsp;Commun.<\/em><strong>284<\/strong>, 201-206 (2011).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Nonlinear  propagation in silicon-based plasmonic waveguides from the standpoint of  applications,&#8221; <em>Opt.&nbsp;Express<\/em><strong>19<\/strong>, 206-217 (2011).  <\/li><li>Y. Xiao, G. P. Agrawal, and D. N. Maywar, &#8220;Spectral and temporal  changes of optical pulses propagating through time-varying linear  media,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>36<\/strong>, 505-507 (2011).  <\/li><li>S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Dispersive wave  generation in supercontinuum process inside nonlinear microstructured  fibres,&#8221; Current Science (Indian Acad.&nbsp;Sciences) <strong>100<\/strong>, 321-342 (2011).  <\/li><li>A. M. Kaplan, G. P. Agrawal, and D. N. Maywar, &#8220;All-optical phase control of a square-wave photonic clock,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>22<\/strong>, 405-407 (2011).  <\/li><li>S. Roy, S. K. Bhadra, K. Saitoh, M. Koshiba, and G. P. Agrawal,  &#8220;Dynamics of Raman soliton during supercontinuum generation near the  zero-dispersion wavelength of optical fibers,&#8221; <em>Opt.&nbsp;Express<\/em><strong>19<\/strong>, 10456-10461 (2011).  <\/li><li>A. Baron, N. Dubreuil, P. Delaye, R. Frey, and G. P. Agrawal,  &#8220;Raman amplification of optical pulses in silicon nanowaveguides: Impact  of spectral broadening of pump pulses,&#8221; <em>J. Europ.&nbsp;Opt.&nbsp;Soc.&nbsp;Rapid Public.<\/em><strong>6<\/strong>, 11030:1-11 (2011).  <\/li><li>Y. Xiao, D. N. Maywar, and G. P. Agrawal, &#8220;Optical pulse propagation in dynamic Fabry-Perot resonators,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>28<\/strong>, 1685-1692 (2011).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Maximization of gain in slow-light silicon Raman amplifiers,&#8221; <em>Int.&nbsp;J. Optics<\/em><strong>2011<\/strong>, 581810 (2011).  <\/li><li>P. P. Baveja, B. K\u00f6gel, P. Westbergh, J. S. Gustavsson, A. Haglund,  D. N. Maywar, G. P. Agrawal and A. Larsson, &#8220;Assessment of VCSEL  thermal rollover mechanisms from measurements and empirical modeling,&#8221; <em>Opt.&nbsp;Express<\/em><strong>19<\/strong>, 15490-15505 (2011).  <\/li><li>B. Daniel, D. N. Maywar, and G. P. Agrawal, &#8220;Dynamic mode Theory of optical resonators undergoing refractive index changes,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>28<\/strong>, 2207-2215 (2011).  <\/li><li>C. Dissanayake, I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal,  &#8220;Polarization-dependent spectral broadening of femtosecond pulses in  silicon waveguides,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>28<\/strong>, 2383-2389 (2011).  <\/li><li>I. D. Rukhlenko, A. Pannipitiya, M. Premaratne, and G. P. Agrawal,  &#8220;Exact dispersion relation for nonlinear plasmonic waveguides,&#8221; <em>Phys.&nbsp;Rev.&nbsp;B<\/em><strong>84<\/strong>, 113409:1-4 (2011).  <\/li><li>B. Daniel, D. N. Maywar, and G. P. Agrawal, &#8220;Efficient adiabatic wavelength conversion in Gires-Tournois resonators,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>36<\/strong>, 4155-4157 (2011).  <\/li><li>B. Daniel, J. Y. Lee, P. M. Fauchet, and G. P. Agrawal,  &#8220;Observation of spectral and temporal polarization oscillations of  optical pulses in a silicon nanowaveguide,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>99<\/strong>, 201104:1-3 (2011). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2012<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>P. P. Baveja, B. K\u00f6gel, P. Westbergh, J. S. Gustavsson, A. Haglund,  D. N. Maywar, G. P. Agrawal and A. Larsson, &#8220;Assessment of VCSEL  thermal rollover mechanisms from measurements and empirical modeling,&#8221; <em>IEEE J. Quantum Electron.<\/em><strong>48<\/strong>, 17-26 (2012).  <\/li><li>B. A. Daniel and G. P. Agrawal, &#8220;Phase-switched all-optical flip-flops using two-input bistable resonators,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>24<\/strong>, 479-481 (2012).  <\/li><li>P. P. Baveja, D. N. Maywar, and G. P. Agrawal, &#8220;Interband four-wave  mixing in semiconductor optical amplifiers with ASE-enhanced gain  recovery,&#8221; <em>IEEE J. Sel.&nbsp;Topics Quantum Electron.<\/em><strong>18<\/strong>, 899-908 (2012).  <\/li><li>Y. Xiao, G. P. Agrawal, and D. N. Maywar, &#8220;Nonlinear pulse propagation: A time-transformation approach,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>37<\/strong>, 1271-1273 (2012).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Effective mode  area and its optimization in silicon-nanocrystal waveguides,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>37<\/strong>, 2295-2297 (2012).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Plasmonic modes of metamaterial-based slot waveguides,&#8221; <em>Adv.&nbsp;in Optoelectron.<\/em><strong>2012<\/strong>, 907183:1-5 (2012).  <\/li><li>S. Ghosh, B. P. Pal, R. K. Varshney, and G. P. Agrawal, &#8220;Transverse  localization of light and its dependence on the phase-front curvature  of the input beam in a disordered optical waveguide lattice,&#8221; <em>J. Opt. (IOP)<\/em><strong>14<\/strong>, 075701:1-5 (2012).  <\/li><li>B. A. Daniel and G. P. Agrawal, &#8220;Design of phase-switched two-input Kerr flip-flops,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>29<\/strong>, 2288-2296 (2012).  <\/li><li>S. Coulibaly, Z. Liu, M. Taki, and G. P. Agrawal, &#8220;Parametric gain  control of a pulse in birefringent photonic crystal fibers,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>86<\/strong>, 033802:1-5 (2012).  <\/li><li>S. Mumtaz, R.-J. Essiambre, and G. P. Agrawal, &#8220;Reduction of  nonlinear penalties due to linear coupling in multicore optical fibers,&#8221;  <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>24<\/strong>, 1574-1576 (2012).  <\/li><li>Y. Xiao, D. N. Maywar, and G. P. Agrawal, &#8220;A new approach to pulse propagation in nonlinear dispersive optical media,&#8221; <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>29<\/strong>, 2958-2963 (2012).  <\/li><li>I. D. Rukhlenko, M. Premaratne, and G. P. Agrawal, &#8220;Guided Plasmonic modes of anisotropic slot waveguides,&#8221; <em>Nanotechnology<\/em><strong>23<\/strong>, 444006:1-8 (2012).  <\/li><li>I. D. Rukhlenko, W. Zhu, M. Premaratne, and G. P. Agrawal,  &#8220;Effective third-order susceptibility of silicon-nanocrystal-doped  silica,&#8221; <em>Opt.&nbsp;Express<\/em><strong>20<\/strong>, 26275-26284 (2012). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2013<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>P. P. Baveja, Y. Xiao, S. Arora, G. P. Agrawal, and D. N. Maywar,   &#8220;All-optical semiconductor optical amplifier-based wavelength converters  with sub-mW pumping,&#8221; <em>IEEE Photon.&nbsp;Technol.&nbsp;Lett.<\/em><strong>25<\/strong>, 78-80 (2013).  <\/li><li>S. Mumtaz, R.-J. Essiambre, and G. P. Agrawal, &#8220;Nonlinear  propagation in multimode and multicore fibers: Generalization of the  Manakov equations,&#8221; <em>J. Lightwave Technol.<\/em><strong>31<\/strong>, 398-406 (2013).  <\/li><li>Y. Xiao, D. N. Maywar, and G. P. Agrawal, &#8220;Propagation of few-cycle pulses in nonlinear Kerr media: Harmonic generation,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>38<\/strong>, 724-726 (2013).  <\/li><li>A. Barh, S. Ghosh,  G. P. Agrawal, R. K. Varshney, I. D. Aggarwal,  and B. P. Pal, &#8220;Design of an efficient mid-IR light source using  chalcogenide holey fibers: a numerical study,&#8221; <em>J. Opt.<\/em> (UK) <strong>15<\/strong>, 035205:1-7 (2013).  <\/li><li>S. Li, X. Zhang, and G. P. Agrawal, &#8220;Characteristics of photonic  crystal fibers designed with an annular core using a single material,&#8221; <em>Appl. Opt.<\/em><strong>53<\/strong>, 3088-3093  (2013).  <\/li><li>H. Pourbeyram, G. P. Agrawal, and A. Mafi, &#8220;SRS generation spanning  over two octaves in a graded-index multimode optical fiber,&#8221; <em>Appl.&nbsp;Phys.&nbsp;Lett.<\/em><strong>102<\/strong>, 201107:1-4 (2013).  <\/li><li>Y. Xiao, D. N. Maywar, and G. P. Agrawal, &#8220;Time transformation  approach to pulse propagation in nonlinear dispersive media: Inclusion  of delayed Raman nonlinearity,&#8221; <em>Phys.&nbsp;Rev. A <\/em><strong>87<\/strong>, 063816:1-6 (2013). <\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2014<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>Y. Xiao, D. N. Maywar, and G. P. Agrawal, &#8220;Reflection and transmission of electromagnetic waves at a temporal boundary,&#8221; <em>Opt.&nbsp;Lett.<\/em><strong>39<\/strong>, 574-477 (2014).  <\/li><li>T. Wijesinghe, M. Premaratne, and G. P. Agrawal, &#8220;Electrically pumped hybrid plasmonic waveguide,&#8221; <em>Opt.&nbsp;Express<\/em><strong> <\/strong><strong>22<\/strong>, 2681-2694 (2014).  <\/li><li>C. J. Kumarasinghe, M. Premaratne, and G. P. Agrawal, &#8220;Dielectric  function of spherical dome shells with quantum size effects,&#8221; <em>Opt.&nbsp;Express<\/em><strong> 22<\/strong>, 11966-11984 (2014).  <\/li><li>W. Zhu, M. Premaratne, S. D. Gunapala, G. P. Agrawal, and M. I.  Stockman, `Quasi-static analysis of controllable optical cross sections  of a nanoparticle with a sandwiched gain layer,&#8221; <em>J. Opt.<\/em> (UK) <strong>16<\/strong>, 075003, 1-6 (2014).<\/li><li> C. Flytzanis and G. P. Agrawal, &#8220;Parametric stimulated two-photon emission through a biphotonic cascade,&#8221; <em>Phys. Rev. A<\/em> <strong>89<\/strong>, 003800, 1-5 (2014).<\/li><li>M. R. Karim, B. M. A. Rahman, and G. P. Agrawal, &#8220;Dispersion engineered GeAsSe nanowires for supercontinuum generation: A parametric study,&#8221;  <em>Opt. Express <\/em><strong>22<\/strong> , 31029-31040 (2014).<\/li><li>Y. Xiao, R.-J. Essiambre, M. Desgroseilliers, A. M. Tulino, R. Ryf,  and G. P. Agrawal, &#8220;Theory of intermodal four-wave mixing with random  linear mode-coupling in few-mode fibers,&#8221; <em>Opt. Express <\/em><strong>22<\/strong>, 32039-32059 (2014).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2015<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>S. Buch and G. P. Agrawal, &#8220;`Soliton stability and trapping in multimode fibers,&#8221; Opt. Lett. <strong>40<\/strong>, 225-228 (2015).<\/li><li>M. R. Karim, B. M. A. Rahman, and G. P. Agrawal, &#8220;Mid-infrared supercontinuum generation using dispersion-engineered GeAsSe chalcogenide channel waveguides,&#8221;  <em>Opt. Express <\/em><strong>23<\/strong> , 6903-6914 (2015).<\/li><li>A. Barh, R. K. Varshney, G. P. Agrawal, B. M. A. Rahman, and B. P. Pal, &#8220;Plastic fiber design for THz generation through wavelength translation,&#8221;  Opt. Lett. <strong>40<\/strong> , 2107-2110 (2015).<\/li><li>T. M. Wijesinghe, M. Premaratne, and G. P. Agrawal, &#8220;`Low-loss dielectric-loaded graphene surface plasmon polariton waveguide based biochemical sensor,&#8221; <em>J. Appl. Phys<\/em>. <strong>117<\/strong>, 213105, 1-9 (2015).<\/li><li>B. W. Plansinis, W. R. Donaldson and G. P. Agrawal, &#8220;Spectral changes induced by a phase modulator acting as a time lens,&#8221;  <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>32<\/strong> , 1550-1554 (2015).<\/li><li>A. Antikainen and G. P. Agrawal, &#8220;Dual-pump frequency comb generation in normally dispersive optical fibers,&#8221;  <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>32<\/strong> , 1705-1711 (2015).<\/li><li>Y. Yao, G. P. Agrawal, and W. H. Knox, &#8220;Yb:fiber laser-based, spectrally coherent and efficient generation of femtosecond 1.3 um pulses from a fiber with two zero dispersion wavelengths,&#8221;  Opt. Lett. <strong>40<\/strong> , 3631-3634 (2015).<\/li><li>C. S. Kumarasinghe, M. Premaratne, Q. Bao, and G. P. Agrawal, &#8220;Theoretical analysis of hot electron dynamics in nanorods,&#8221; Nature Scientific Rep. <strong>5<\/strong>, 12140, 1-15 (2015).<\/li><li>M. R. Karim, B. M. A. Rahman, Y. O. Azabi, A. Agrawal, and G. P. Agrawal, &#8220;Ultra-broadband mid-infrared supercontinuum generation through dispersion engineering of chalcogenide microstructured fibers,&#8221;  <em>J. Opt.&nbsp;Soc.&nbsp;Am.&nbsp;B <\/em><strong>32<\/strong> , 2343-2351 (2015).<\/li><li>T. Attanayake, M. Premaratne, and G. P. Agrawal, &#8220;Characterizing the optical response of symmetric hemispherical nano-dimers,&#8221; <em>Plasmonics<\/em>, DOI 10.1007\/s11468-015-9946-x, 1-15 (2015).<\/li><li>B. W. Plansinis, W. R. Donaldson and G. P. Agrawal, &#8220;What is the temporal analog of reflection and refraction of optical beams?,&#8221;  <em>Phys. Rev. Lett.<\/em> <strong>115<\/strong>, 183901 (2015).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2016<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>A. Barh, B. P. Pal, G. P. Agrawal,  R. K. Varshney, and B. M. A. Rahman, &#8220;Specialty fibers for terahertz generation and transmission: A review (invited),&#8221;  <em>IEEE J. Sel.\u00a0Topics in Quantum Electron.<\/em> <em>22<\/em>, 8500215, 1-15 (2016).<\/li><li>C. S. Kumarasinghe, M. Premaratne, S. D. Gunapala, and G. P. Agrawal, &#8220;Design of all-optical, hot-electron, current-direction-switching nanophotonic device based on geometrical asymmetry&#8221; <em>Nature Scientific Rep.<\/em>  <strong>6<\/strong>, 21470, 1-15 (2016).<\/li><li>B. W. Plansinis, W. R. Donaldson and G. P. Agrawal, &#8220;Temporal waveguides for optical pulses,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B <\/em><strong>3<\/strong>3 , 1112-1119 (2016).<\/li><li>A. Barh, R. K. Varshney, B. P. Pal, G. P. Agrawal, and B. M. A. Rahman, &#8220;Design of a polymer-based hollow-core band-gap fiber for low-loss terahertz transmission,&#8221; <em>IEEE Photon. Technol. Lett<\/em>. <strong>28<\/strong>, 1703-1706 (2016).<\/li><li>C. S. Kumarasinghe, M. Premaratne, S. D. Gunapala, and G. P. Agrawal, Theoretical analysis of hot electron injection from metallic nanotubes into a semiconductor interface,&#8221; Phys. Chem. Chem. Phys. <strong>18<\/strong>, 18227-18236 (2016).<\/li><li>S. Buch and G. P. Agrawal, &#8220;Intermodal soliton interaction in nearly degenerate modes of a multimode fiber,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B <\/em><strong>3<\/strong>3 , 2217-2224 (2016).<\/li><li>S. Bose, A. Sahoo, R. Chattopadhyay, S. Roy, S. K. Bhadra, and G. P. Agrawal, &#8220;Implications of a zero-nonlinearity wavelength in photonic crystal fibers doped with silver nanoparticles,&#8221;  <em>Phys. Rev. A<\/em>  <strong>94<\/strong>, 043835:1-8 (2016).<\/li><li>F. R. Arteaga-Sierra, A. Antikainen, and G. P. Agrawal, &#8220;Dynamics of soliton cascades in fiber amplifiers,&#8221; <em>Opt. Lett.  <\/em><strong>41<\/strong>, 5198-5201 (2016).<\/li><li>B. W. Plansinis, W. R. Donaldson, and G. P. Agrawal, &#8220;Spectral Splitting of optical pulses inside a dispersive medium at a temporal boundary,&#8221;  <em>IEEE J. Quantum Electron.<\/em>  <strong>52<\/strong>, 6100708:1-8 (2016).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2017<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>A. Antikainen, F. R. Arteaga-Sierra, and G. P. Agrawal, &#8220;Temporal reflection as a spectral broadening mechanism in dual-pumped dispersion-decreasing fibers and its connection to dispersive waves,&#8221;  <em>Phys. Rev. A<\/em>   <strong>95<\/strong>, 033813:1-5 (2017).<\/li><li>P. Balla, S. Buch, and G. P. Agrawal, &#8220;Effect of Raman scattering on soliton interactions in optical fibers,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B<\/em> <strong>34<\/strong>, 1247-1254 (2017).<\/li><li>H. Hapuarachchi, M. Premaratne, Q. Bao, W. Cheng S. D. Gunapala, and G. P. Agrawal, &#8220;Cavity QED analysis of an exciton-plasmon hybrid molecule via the generalized nonlocal optical response method,&#8221;  <em>Phys. Rev. B<\/em>   , <strong>95<\/strong>, 245419:1-12 (2017).<\/li><li>A. Sahoo, S. Roy, and G. P. Agrawal, &#8220;Perturbed dissipative solitons: A variational approach,&#8221;  <em>Phys. Rev. A<\/em>  <strong>96<\/strong>, 013838:1-7 (2017).<\/li><li>A. Le Floch, O. Emile, G. Ropars, and G. P. Agrawal, &#8220;Dynamics and detection of the Newton&#8211;Wigner time delays at interfaces using a swiveling method,&#8221; Nature Sci. Rep. <strong>7<\/strong>, 9083, DOI:10.1038\/s41598-017-09502-9 (2017).<\/li><li>B. W. Plansinis, W. R. Donaldson, and G. P. Agrawal, &#8220;Single-pulse interference caused by temporal reflection at a moving refractive-index boundary,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B<\/em> <strong>34<\/strong>, 2274-2280 (2017).<\/li><li>T. D. Visser, G. P. Agrawal, and P. W. Milloni, &#8220;Fourier processing with partially coherent fields,&#8221; <em>Opt. Lett. <\/em> <strong>42<\/strong>, 4600-4602 (2017).<\/li><li>A. Antikainen, R.-J. Essiambre, and G. P. Agrawal, &#8220;Determination of Modes of Elliptical Waveguides with Ellipse Transformation Perturbation Theory,&#8221; <em>Optica<\/em> <strong>4<\/strong>, 1510-1513 (2017).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2018<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>B. W. Plansinis, W. R. Donaldson, and G. P. Agrawal, &#8220;Cross-phase-modulation-induced temporal reflection and waveguiding of optical pulses,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B<\/em>  <strong>35<\/strong>, 436-445 (2018).<\/li><li>X. Zhao, T. D. Visser, and G. P. Agrawal, &#8220;Controlling the degree of polarization of partially coherent electromagnetic beams with lenses,&#8221;  <em>Opt. Lett. <\/em>  <strong>43<\/strong>, 2344-2347 (2018).<\/li><li>L. Kumarapperuma, M. Premaratne, P. K. Jha, M. I. Stockman, and G. P. Agrawal, &#8220;Complete characterization of the spasing (L-L) curve of a three-level quantum coherence enhanced spaser for design optimization,&#8221;  <em>Appl. Phys. Lett.<\/em>   <strong>112<\/strong>, 10.1063\/1.5025354 (2018).<\/li><li>A. Antikainen and G. P. Agrawal, &#8220;Femtosecond pulse trains through dual pumping of optical fibers: role of third-order dispersion,&#8221; <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B<\/em>  <strong>35<\/strong>, 1733-1740 (2018).<\/li><li>A. S. Ahsan and G. P. Agrawal, &#8220;Graded-index solitons in multimode fibers,&#8221;  <em>Opt. Lett. <\/em>  <strong>43<\/strong> , 3345-3348 (2018).<\/li><li>F. R. Arteaga-Sierra, A. Antikainen, and G. P. Agrawal, &#8220;Soliton dynamics in photonic-crystal fibers with frequency-dependent Kerr nonlinearity,&#8221;  <em>Phys. Rev. A<\/em>   <strong>98<\/strong>, 013830 (2018).<\/li><li>X. Zhao, T. D. Visser, and G. P. Agrawal, &#8220;Degree of polarization in the focal region of a lens,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0A<\/em>  <strong>35<\/strong>, 1518-1522 (2018).<\/li><li>P. Balla and G. P. Agrawal, &#8220;Nonlinear interaction of vector solitons inside birefringent optical fibers,&#8221;  <em>Phys. Rev. A<\/em>   <strong>98<\/strong>, 023822 (2018).<\/li><li>P. Balla and G. P. Agrawal, &#8220;Vector solitons and dispersive waves in birefringent optical fibers,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B<\/em>  <strong>35<\/strong>, 2302-2310 (2018).<\/li><\/ul>\n\n\n\n<h2 class=\"wp-block-heading\"><strong>Published in 2019<\/strong><\/h2>\n\n\n\n<ul class=\"wp-block-list\"><li>A. Antikainen, L. Rishoj, B. Tai, S. Ramachandran, and G. P. Agrawal, &#8220;The fate of a soliton in a high order spatial mode of a multimode fiber,&#8221;  <em>Phys. Rev. Lett.<\/em>  <strong>122<\/strong>, 023901 (2019).<\/li><li>S. Buch, S. Mumtaz , R.-J. Essiambre, A. M. Tulino, and G. P. Agrawal, &#8220;Averaged nonlinear equations for multimode fibers valid in all regimes of random linear coupling,&#8221; <em>Opt. Fiber Technol<\/em>. <strong>48<\/strong>, 123-127 (2019).<\/li><li>G. P. Agrawal, &#8220;Self-imaging in multimode graded-index fibers and its impact on the nonlinear phenomena,&#8221;  <em>Opt. Fiber Technol<\/em>. <strong>50<\/strong> , 309-316 (2019).<\/li><li>A. S. Ahsan and G. P. Agrawal, &#8220;Spatio-temporal enhancement of Raman-induced frequency shifts in graded-index multimode fibers,&#8221;  <em>Opt. Lett. <\/em> <strong>44<\/strong>, 2637-2640 (2019).<\/li><li>Y. Yang, S. Fan, X. Li, X. Liu, Y. Cai, G. P. Agrawal, and T.~D. Visser, &#8220;Fraunhofer diffraction and the state of polarization of partially coherent electromagnetic beams,&#8221;  <em>Opt. Lett. <\/em> <strong>44<\/strong>, 3330-3333 (2019).<\/li><li>B. W. Plansinis, W. R. Donaldson, and G. P. Agrawal, &#8220;A time-to-frequency converter for measuring shape of short optical pulses,&#8221; Rev. Sci.  Instrum. <strong>90<\/strong>, 083106 (2019).<\/li><li>A. Antikainen and G. P. Agrawal, &#8220;Soliton supermode transitions and total red shift suppression in multi-core fibers,&#8221;  <em>Opt. Lett. <\/em> <strong>44<\/strong> , 4159-4162 (2019).<\/li><li>B. A. Tennant, R. Ara, A. Atwiri, G. P. Agrawal, N. M. Litchinister, and D. Maywar, &#8220;Distributed feedback lasing based on a negative-index metamaterial waveguide,&#8221;  <em>Opt. Lett. <\/em> <strong>44<\/strong> , 4586-4589 (2019).<\/li><li>A. Antikainen and G. P. Agrawal, &#8220;Supercontinuum generation in seven-core fibers,&#8221;  <em>J. Opt.\u00a0Soc.\u00a0Am.\u00a0B<\/em>  <strong>36<\/strong>, 2927-2937 (2019).<\/li><li>G. P. Agrawal, &#8220;Light propagation through graded-index fibers: Impact of self-imaging on the nonlinear phenomena,&#8221; <em>Asian J. Phys. <\/em><strong>28<\/strong>, 487-498 (2019).<\/li><\/ul>\n","protected":false},"excerpt":{"rendered":"<p>Authored Books G. P. Agrawal and N. K. Dutta, Semiconductor Lasers (Van Nostrand Reinhold, 1986); 2nd ed.&nbsp;1993; reprinted in 2002 by Springer. G. P. Agrawal, Nonlinear Fiber Optics (Academic Press, Elsevier, 1989); Chinese translation, 1992; Russian translation, 1996; Japanese translation, 1997; 2nd ed.&nbsp;1995; 3rd ed.&nbsp;2001; 4th ed.&nbsp;2007, 5th ed.&nbsp;2013; 6th ed. 2019. G. P. Agrawal, &hellip; <\/p>\n<p class=\"link-more\"><a href=\"https:\/\/labsites.rochester.edu\/agrawal\/people\/group-members\/govind-agrawal\/complete-list-of-publications\/\" class=\"more-link\">Continue reading<span class=\"screen-reader-text\"> &#8220;Complete List of Publications&#8221;<\/span><\/a><\/p>\n","protected":false},"author":0,"featured_media":0,"parent":1506,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-1796","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/pages\/1796","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/types\/page"}],"replies":[{"embeddable":true,"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/comments?post=1796"}],"version-history":[{"count":34,"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/pages\/1796\/revisions"}],"predecessor-version":[{"id":12226,"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/pages\/1796\/revisions\/12226"}],"up":[{"embeddable":true,"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/pages\/1506"}],"wp:attachment":[{"href":"https:\/\/labsites.rochester.edu\/agrawal\/wp-json\/wp\/v2\/media?parent=1796"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}