Peer Reviewd Publications :
  1. S. Glasgow, John Corson and Chris Verhaaren, Dispersive dielectrics and time reversal: Free energies, orthogonal spectra, and parity in dissipative media, Phys. Rev. E 82, 011115 (2010).

  2. S. Glasgow and M. Ware, Real-time dissipation of optical pulses in passive dielectrics, Phys. Rev. A. 80, 043817-827 (2009).

  3. S. Taylor and S. Glasgow, A Novel Reduction of the Simple Asian Option and Lie-Group Invariant Solutions, Int. J. Theoretical and Appl. Finance, 12, Issue 6 (2009).

  4. S. Glasgow, M. Meilstrup, J. Peatross, and M. Ware, Real-time recoverable energy allocation in dispersive dielectrics, Phys. Rev. E 75, 016616 (2007).

  5. B. R. Frandsen, S. A. Glasgow, and J. B. Peatross, Acceleration of Free Electrons in a Symmetric Evanescent Wave, Laser Physics, 16, No. 9, 1–4 (2006).

  6. S.A. Glasgow, M.A. Agrotis and N.M. Ercolani, An integrable reduction of inhomogeneously broadened optical equations, Physica D: Nonlinear Phenomena, 212, Issues 1-2, 82-99 (2005).

  7. M. Ware, S. A. Glasgow, and J. Peatross, Energy Transport in Linear Dielectrics, Opt. Express 9, 519-532 (2001).

  8. M. Ware, S. A. Glasgow, and J. Peatross, The Role of Group Velocity in Tracking Field Energy in Linear Dielectrics, Opt. Express 9, 506-518 (2001).

  9. S. A. Glasgow, M. Ware, and J. Peatross, Poynting's Theorem and Luminal Energy Transport Velocity in Causal Dielectrics, Phys. Rev. E 64, 046610-1 thru 046610-14 (2001).

  10. J. Peatross, M. Ware, and S. A. Glasgow, The Role of the Instantaneous Spectrum on Pulse Propagation in Causal Linear Dielectrics, J. Opt. Soc. of Am. A 18, 1719-1725 (2001).

  11. M. Ware, W. E. Dibble, S. A. Glasgow, and J. Peatross, Energy Flow in Angularly Dispersive Optical Systems, J. Opt. Soc. of Am. B 18, 839-845 (2001).

  12. J. Peatross, S. A. Glasgow, and M. Ware, Average Energy Flow of Optical Pulses in Dispersive Media, Phys. Rev. Lett. 84, 2370-2373 (2000).

  13. M. Agrotis, N. Ercolani, S.A. Glasgow, and J.V. Moloney, Complete Integrability of the Reduced Maxwell-Bloch Equations with Permanent Dipole, Physica D 138, 134-162 (2000).

  14. T.C. Newell, A. Gavrielides, V. Kovanis, D. Sukow, T. Erneux, and S. A. Glasgow, Unfolding of the Period-Two Bifurcation in a Fiber Laser Pumped With Two Modulation Tones, Phys. Rev. E 56, 7223-7231 (1997).

  15. S. Glasgow, P. Meystre, M. Wilkens, Doppleron-Catalyzed Bragg Resonances in Atom Optics, Opt. Lett. 17,1301-1303 (1992).

  16. E. Schumacher, M. Wilkens, P. Meystre, S. Glasgow, Spontaneous Emission in the Near-Resonant Kapitza-Dirac Effect, Appl. Phys. B 54, 451-466 (1992).

  17. S. Glasgow, P. Meystre, M. Wilkens, E. M. Wright, Theory of an Atomic Beam Splitter Based on Velocity-Tuned Resonances, Phys. Rev. A 43, 2455-2463 (1991).

Other Publications:
  1. S. A. Glasgow and M. Ware, Free Energies of Dielectrics, in Slow and Fast Light, OSA Technical Digest (CD) (Optical Society of America, 2009), paper SMA5.

  2. V. X. Dang, S. Glasgow, H. Potter and S. Taylor, Pricing the Asian Call Option. Elec. Proc. Undergraduate Math. Days, 3 (2008), No. 3, 26 pp.

  3. C. Broadbent, G. Hovhannisyan, J. Peatross, M. Clayton, S. Glasgow, Real-time determination of free energy and losses in optical absorbing media, Physics e-Print archive: physics/0207117 (see also

  4. M.A. Agrotis, N.M. Ercolani, and S.A. Glasgow, Inhomogeneously broadened Maxwell-Bloch equations, BULLETIN OF THE GREEK MATHEMATICAL SOCIETY, 51, 1-14, (2006).

  5. M. Agrotis, Nicholas Ercolani and Scott Glasgow , The Pseudo-Potential Technique for Nonlinear Optical Equations, Proceedings of 10th International Conference in MOdern GRoup Analysis (MOGRA X), 22-31, (2005).

  6. C. Broadbent, G. Hovhannisyan, M. Clayton, J. Peatross, S. A. Glasgow, Dynamical energy and loss in dispersive/dissipative dielectrics, Chapter 9 of Focus on Lasers and Electro-Optics Research, Nova Science Publishers, (2004).

  7. M. Ware, S. Glasgow and J. Peatross, Group Delay Context for Broadband Pulses, UWSP 6, Plenum, 1-10, (2002).

  8. C. Broadbent, G. Hovhannisyan, M. Clayton, J. Peatross, and S. Glasgow, Reversible and Irreversible Processes in Dispersive/Dissipative Media: Electro-Magnetic Free Energy and Heat Production, UWSP 6, Plenum,131-142, (2002).

  9. S. Glasgow, Velocity-Tuned Resonances in Atomic Diffraction by a Standing-Wave Light Field, Dissertation, March 1993.

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