[ProfSBPalmer]

comprising a Special Topic issue as Vol. 114, I. Prigogine and S. A. Rice (series eds.), Advances in Chemical Physics, Wiley, ongoing. In that reference, particularly see M. W. Evans, "O(3) Electrodynamics," a review of some 250 pages; M. W. Evans, "The Link Between the Sachs and O(3) Theories of Electrodynamics," M. W. Evans, "Link Between the Topological Theory of Ranada and Trueba, the Sachs Theory, and O(3) Electrodynamics," T. E. Bearden, "Extracting and Using Electromagnetic Energy from the Active Vacuum," T. E. Bearden, "Energy from the Active Vacuum: The Motionless Electromagnetic Generator," Hal Fox, "Energy for the Future: High Density Charge Clusters," Mendel Sachs, "Symmetry in Electrodynamics: From Special to General Relativity, Macro to Quantum Domains," B. Lehnert, "Optical Effects of an Extended Electromagnetic Theory," Lawrence B. Crowell, "Non-Abelian Electrodynamics: Progress and Problems," S. Jeffers, J.-P. Vigier, and M.W. Evans, "Current Status of the Quantum Theory of Light," Petar K. Anastasovski and David. B. Hamilton, "The Superluminal Theory and Effects," and Terence W. Barrett, "Topological Approaches to Electromagnetism." Also see M. W. Evans, P. K. Anastasovski, T. E. Bearden et al., "Explanation of the Motionless Electromagnetic Generator with O(3) Electrodynamics," Foundations of Physics Letters, 14(1), Feb. 2001, p. 87-94; — "Explanation of the Motionless Electromagnetic Generator with the Sachs Theory of Electrodynamics," Foundations of Physics Letters, 14(4), 2001, p. 387-393 (in press), — "Operator
Derivation of the Gauge Invariant Proca and Lehnert Equation: Elimination of the Lorentz Condition," Foundations of Physics, 39(7), 2000, p. 1123-1130; — "Effect of Vacuum Energy on the Atomic Spectra," Foundations of Physics Letters, 13(3), June 2000, p. 289-296; — "Runaway Solutions of the Lehnert Equations: The Possibility of Extracting Energy from the Vacuum," Optik, 111(9), 2000, p. 407-409; —"Classical Electrodynamics Without the Lorentz Condition: Extracting Energy from the Vacuum," Physica Scripta 61(5), May 2000, p. 513-517. Particularly see M. W. Evans, P. K. Anastasovski, T. E. Bearden et al., "The New Maxwell Electrodynamic Equations: New Tools for New Technologies. A Collection of 60 papers from the Alpha Foundation's Institute for Advanced Study. Published as a Special Issue of the Journal of New Energy, 4(3), Winter 1999. 335 p
W. K. H. Panofsky and M. Phillips, Classical Electricity and Magnetism, Addison-Wesley, Reading, MA, 1962, 2nd edition, p. 181
T. E. Bearden, “Energy Flow, Collection, and Dissipation in Overunity EM Devices,” Proceedings of the 4th International Energy Conference, Academy for New Energy, Denver, CO, May 23-27, 1997, p. 5-51
John D. Kraus, Electromagnetics, Fourth Edn., McGraw-Hill, New York, 1992, Figure 12-60a and 12-60b, p. 578
Floyd Sweet and T. E. Bearden, "Utilizing Scalar Electromagnetics to Tap Vacuum Energy," Proceedings of the 26th Intersociety Energy Conversion Engineering Conference (IECEC '91), Boston, Massachusetts, p. 370-375.
V. S. L'vov, Wave Turbulence Under Parametric Excitation: Applications to Magnets, Springer Series in Nonlinear Dynamics, Springer-Verlag, New York, 1994
Robert C. O'Handley, Modern Magnetic Materials; Principles and Applications, Wiley, New York, 1999
B. D. Cullity, Introduction to Magnetic Materials, Addison-Wesley, Reading, MA, 1972
Harry E. Burke, Handbook of Magnetic Phenomena, Van Nostrand, New York, 1985
T. E. Bearden, “Use of Asymmetrical Regauging and Multivalued Potentials to Achieve Overunity Electromagnetic Engines,” Journal of New Energy, 1(2), Summer 1996, p. 60-78
S. Itoh et al., "Simulational and experimental studies on anomalous reflectivity of phase conjugate wave," Ferroelectrics, Vol. 170, 1995, p. 209-217
"Wiegand effect: A new pulse-generating option," Automotive Engineering, 86(2), Feb. 1978, p. 44-48; SAE paper 780208, "The Wiegand Effect and its Automotive Applications," by J. David Marks and Michael J. Sinko, The Echlin Manufacturing Co.; "The Wiegand Effect. Some Properties of Wiegand Wire under Asymmetric Sine Wave Drive," by R.C. Barker and J.H. Liaw, Dept. of Engineering and Applied Science, Yale University; D. Botnick, "Access control systems offer programming flexibility," Bank Systems and Equipment, 21( , Aug. 1984, p. 66-68; J. Buj, "The 'Wiegand effect' enables various devices to be operated with the minimum of electric power," Revista Espanola de Electronica (Spain), 24(267), Feb. 1977, p. 14-17; Phillip E. Wigen, “Wiegand Wire: New Material for Magnetic-Based Devices,” Electronics, July 10, 1975, p. 100-105.; Gerald M. Walker, “Wiegand’s Wonderful Wires,” Popular Science, May 1979, p. 102-104, 109; B. Dance, "The Wiegand effect – its applications," Electron (UK), No. 139, June 5, 1978, p. 23-24; H.J. Gevatter and W.A. Merl, "The Wiegand wire—a new magnetic sensor," Regelungstechnische Praxis (Germany), 22(3), Mar. 1980, p. 81-85 [In German]. See also Guenter H. Kuers, "Wiegand effect in theory and practice," Proceedings of SPIE, vol. 392, Proceedings of the 2nd International Conference on Robot Vision and Sensory Controls, Stuttgart, West Germany, Nov. 2-4, 1982, p. 123-132.
G. W. O. Howe, "Effect of Torsion on a Longitudinally-Magnetized Iron Wire," Wireless Engineer 29(344), May 1952, p. 115-117.
F. Mandl and G. Shaw, Quantum Field Theory, Wiley, 1984
Lewis H. Ryder, Quantum Field Theory, Second Edition, Cambridge University Press, 1996, p. 147+.