[ProfSBPalmer]

"Others [terrorists] are engaging even in an eco-type of terrorism whereby they can alter the climate, set off earthquakes, and volcanoes remotely through the use of electromagnetic waves… So there are plenty of ingenious minds out there that are at work finding ways in which they can wreak terror upon other nations…It's real, and that's the reason why we have to intensify our [counterterrorism] efforts." Secretary of Defense William Cohen at an April 1997 counterterrorism conference sponsored by former Senator Sam Nunn. Quoted from DoD News Briefing, Secretary of Defense William S. Cohen, Q&A at the Conference on Terrorism, Weapons of Mass Destruction, and U.S. Strategy, University of Georgia, Athens, Apr. 28, 1997.
W. A. Rodrigues, Jr. and J.-Y. Lu, “On the existence of undistorted progressive waves (UPWs) of arbitrary speeds 0 £ v <¥ in nature,” Foundations of Physics, 27(3), 1997, p. 435-508
W. A. Rodrigues, Jr. and J. Vaz Jr., “Subluminal and Superluminal Solutions in Vacuum of the Maxwell Equations and the Massless Dirac Equation,” Advances in Applied Clifford Algebras, Vol. 7(S), 1997, p. 457-466
T. E. Bearden, "Mind Control and EM Wave Polarization Transductions, Part I, Explore, 9(2), 1999, p. 59; Part II, Explore, 9(3), 1999, p. 61, Part III, Explore
T. E. Bearden, "EM Corrections Enabling a Practical Unified Field Theory with Emphasis on Time-Charging Interactions of Longitudinal EM Waves," Journal of New Energy, 3(2/3), 1998, p. 12-28
T. E. Bearden, “Toward a Practical Unified Field Theory and a Deep Experimental Example,” Proc. INE Symposium, Univ. Utah, Aug. 14-15, 1998
EM Corrections Enabling a Practical Unified Field Theory with Emphasis on Time-Charging Interactions of Longitudinal EM Waves," Explore, 8(6), 1998, p. 7-16.
Owen Flynn, "Parametric arrays: A new concept for sonar," Electronic Warfare Magazine, June 1977, p. 107-112
M. I. Dykman et al., "Noise-enhanced heterodyning in bistable systems," Physical Review E, 49(3), Mar. 1994, p. 1935-1942
Gabriel Kron, "Numerical solution of ordinary and partial differential equations by means of equivalent circuits." Journal of Applied Physics, Vol. 16, Mar. 1945a, p. 173
Gabriel Kron, “Electric circuit models of the Schrödinger equation,” Phys. Rev. 67(1-2), Jan. 1 and 15, 1945, p. 39. See also S. Austen Stigant, "Gabriel Kron on Tensor Analysis, A Bibliographical Record," BEAMA Journal, Aug. 1948, for a full bibliography of Kron's outstanding publications
Gabriel Kron, "The frustrating search for a geometrical model of electrodynamic networks," Journal unk, circa 1962, p. 114. See also Gabriel Kron, “Invisible dual (n-1) networks induced by electric 1-networks,” IEEE Transactions on Circuit Theory, CT-12(4), Dec. 1965, p. 464-470.
; Banesh Hoffman, “Kron’s Non-Riemannian Electrodynamics,” Reviews of Modern Physics, 21(3), 1949, p. 535-540; K. Kondo and Y. Ishizuka, "Recapitulation of the Geometrical Aspects of Gabriel Kron's Non-Riemannian Electrodynamics," Research Association of Applied Geometry, Memoirs of the Unifying Study of Basic Problems in Engineering and Physical Sciences by Means of Geometry, Gakujutsu Bunken Fukyu-kai, Tokyo, Vol. I, 1955, p. 185-239
Nabil M. Lawandy, M. Balachandran, A. S. L. Gomes and E. Sauvain, "Laser action in strongly scattering media," Nature, 368(6470), Mar. 31, 1994, p. 436-438. For a good lay article complete with color pictures, see Ivars Peterson, "Boosted light: Laser action in white paint," Science News, 145(15), Apr. 9, 1994, p. 228-229. See also P. Mandel, "Lasing without inversion: A useful concept?" Contemporary Physics, Vol. 34, 1993, p. 235; O. Kocharovskaya, "Amplification and lasing without inversion," Physics Reports, Vol. 219, 1992, p. 175
Craig F. Bohren, "How can a particle absorb more than the light incident on it?", American Journal of Physics, 51(4), Apr. 1983, p. 323-327
V.S. Letokhov, "Laser Maxwell's demon," Contemporary Physics, 36(4), 1995, p. 235-243; — "Generation of light by a scattering medium with negative resonance absorption," Soviet Physics JETP, 26(4), Apr. 1968, p. 835-839
Double g - and optical resonance,” Physics Letters A, Vol. 43, 1973, p. 179-180.; — "Stimulated emission of an ensemble of scattering particles with negative absorption," ZhETF Plasma, 5( , Apr. 15, 1967, p. 262-265. Pappalardo, R. and A. Lempicki, “Brillouin and Rayleigh Scattering in Aprotic Laser Solutions Containing Neodymium,” Journal of Applied Physics, Apr. 1992, p. 1699-1708
L. Mandelstam [Mendel'shtam, L. I.], N. Papalexi, A. Andronov, S. Chaikin and A. Witt, "Report on Recent Research on Nonlinear Oscillations," Translation of "Expose Des Recherches Recentes Sur Les Oscillations Non Lineaires," Technical Physics of the USSR, Leningrad, Vol. 2, 1935, p. 81-134 [NASA Translation Doc. TT F-12,678, Nov. 1969]. See also A. Andronov, “The limiting cycles of Poincare and the theory of self-maintained oscillations,” Comptes-Rendus, Vol. 189, 1929, p. 559; — and A. Witt, , “On the mathematical theory of self-excitations,” Comptes-Rendus, Vol. 190, 1930, p. 256; — On the mathematical theory of self-excitation systems with two degrees of freedom,” Zhurnal Tekhnicheskioi Fiziki, 4(1), 1934
G. Nicolis and I. Prigogine, (1987), Exploring Complexity, Piper, Munich, 1987; — Exploring Complexity: An Introduction, Freeman, New York, 1989. For a good layman's treatise, see Gregoire Nicolis, "Physics of far-from-equilibrium systems and self-organization," Chapter 11 in Paul Davies, Ed., The New Physics, Cambridge University Press, Cambridge, 1989, p. 317-347. See particularly Ilya Prigogine, The End of Certainty: Time, Chaos, and the New Laws of Nature, Free Press, New York, 1996, 1997; — From Being to Becoming: Time and Complexity in the Physical Sciences, W.H. Freeman and Company, San Francisco, 1980.
Richard P. Feynman, Robert B. Leighton, and Matthew Sands, Lectures on Physics, Addison-Wesley, Reading, MA, Vol. 1, 1964, p. 4-2.
Hsu-Chieh Yeh, “Remark on the second law of thermodynamics,” American Journal of Physics, 52( , Aug. 1984, p. 720+.
A. A. Logunov and Yu. M. Loskutov, "Nonuniqueness of the predictions of the general theory of relativity," Sov. J. Part. Nucl., 18(3), May-June 1987, p. 179-187
Maciej J. Ogorzalek, Chaos and Complexity in Nonlinear Electronic Circuits, World Scientific, New Jersey, 1997
Maxwell's seminal EM paper was J. C. Maxwell, "A Dynamical Theory of the Electromagnetic Field," Royal Society Transactions, Vol. CLV, 1865, p 459. Read Dec. 8, 1864. Also in The Scientific Papers of James Clerk Maxwell, 2 vols. bound as one, edited by W. D. Niven, Dover, New York, 1952, Vol. 1, p. 526-597. In the latter, two errata are given on the unnumbered page prior to page 1 of Vol. 1. In this paper Maxwell presents his seminal theory of electromagnetism, containing 20 equations in 20 unknowns. His general equations of the electromagnetic field are given in Part III, General Equations of the Electromagnetic Field, p. 554-564. On p. 561, he lists his 20 variables. On p. 562, he summarizes the different subjects of the 20 equations, being three equations each for magnetic force, electric currents, electromotive force, electric elasticity, electric resistance, total currents; and one equation each for free electricity and continuity. In the paper, Maxwell adopts the approach of first arriving at the laws of induction and then deducing the mechanical attractions and repulsions.