Verfügbarkeit: The electromagnetic origin of quantum theory and light /

The electromagnetic origin of quantum theory and light /:

This book presents a rigorous application of modern electromagnetic field theory to atomic theory. The historical view of quantum theory was developed before four major physical principles were known, or understood. These are (1) the standing energy that accompanies and encompasses electromagnetical...

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Bibliographische Detailangaben
1. Verfasser:	Grimes, Dale M. (Dale Mills), 1926-
Weitere Verfasser:	Grimes, Craig A.
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	New Jersey : World Scientific, ©2002.
Schlagworte:	Quantum theory. Quantum optics. Electromagnetism. Quantum Theory Théorie quantique. Optique quantique. Électromagnétisme. electromagnetism. SCIENCE > Physics > Quantum Theory. Electromagnetism Quantum optics Quantum theory
Online-Zugang:	Volltext
Zusammenfassung:	This book presents a rigorous application of modern electromagnetic field theory to atomic theory. The historical view of quantum theory was developed before four major physical principles were known, or understood. These are (1) the standing energy that accompanies and encompasses electromagnetically active, electrically small volumes, (2) the power-frequency relationships in nonlinear systems, (3) the possible directivity of modal fields, and (4) electron nonlocality. The inclusion of these four effects yields a deterministic interpretation of quantum theory that is consistent with those of other sciences; the quixotic axioms of the historically accepted view of quantum theory are not needed. The new interpretation preserves the full applicability of electromagnetic field theory within atoms, showing that the status of all physical phenomena - including that within atoms - at any instant does completely specify the status an instant later.
Beschreibung:	1 online resource (xvi, 447 pages) : illustrations
Bibliographie:	Includes bibliographical references and index.
ISBN:	9789812778284 9812778284 9789810247850 9810247850

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505	0		\|a 1. Classical electrodynamics. 1.1. Introductory comments. 1.2. Space and time dependence upon speed. 1.3. Four-dimensional space time. 1.4. Newton's laws. 1.5. Electrodynamics. 1.6. The field equations. 1.7. Accelerating charges. 1.8. The Maxwell stress tensor. 1.9. Kinematic properties of fields. 1.10. A lemma for calculation of electromagnetic fields. 1.11. The scalar differential equation. 1.12. Radiation fields in spherical coordinates. 1.13. Electromagnetic fields in a box -- 2. Selected boundary value problems. 2.1. Traveling waves. 2.2. Scattering of a plane wave by a sphere. 2.3. Ideal spherical scatterers. 2.4. General comments. 2.5. Fields. 2.6. TEM mode. 2.7. Boundary conditions. 2.8. The defining integral equations. 2.9. Solution of the biconical antenna problem. 2.10. Power. 2.11. Field expansion for y-directed exponential. 2.12. Incoming TE fields. 2.13. Incoming TM fields. 2.14. Exterior fields, powers, and forces. 2.15. The cross sections. 2.16. General comments. 2.17. Fields of receiving antennas. 2.18. Boundary conditions. 2.19. Zero degree solution. 2.20. Non-zero degree solutions. 2.21. Surface current densities. 2.22. Power -- 3. Antenna Q. 3.1. Instantaneous and complex power in circuits. 3.2. Instantaneous and complex power in fields. 3.3. Time varying power in actual radiation fields. 3.4. Comparison of complex and instantaneous powers. 3.5. Radiation Q. 3.6. Chu's Q analysis, TM fields. 3.7. Chu's Q analysis, exact for TM fields. 3.8. Chu's Q analysis, TE field. 3.9. Chu's Q analysis, collocated TM and TE modes. 3.10. Q the easy way, electrically small antennas. 3.11. Q on the basis of time-dependent field theory. 3.12. Q of a radiating electric dipole. 3.13. Surface pressure on dipolar source. 3.14. Q of radiating magnetic dipoles. 3.15. Q of collocated electric and magnetic dipole pair. 3.16. Q of collocated, perpendicular electric dipoles. 3.17. Four collocated electric and magnetic dipoles and multipoles. 3.18. Numerical characterization of antennas. 3.19. Experimental characterization of antennas. 3.20. Q of collocated electric and Magnetic dipoles: Numerical and experimental characterizations -- 4. Quantum theory. 4.1. Electrons. 4.2. Radiation reaction force. 4.3. The time-independent Schrodinger equation. 4.4. The uncertainty principle. 4.5. The time-dependent Schrodinger equation. 4.6. Quantum operator properties. 4.7. Orthogonality. 4.8. Electron angular momentum, central force fields. 4.9. The Coulomb potential source. 4.10. Hydrogen atom Eigenfunctions. 4.11. Perturbation analysis. 4.12. Non-ionizing transitions. 4.13. Absorption and emission of radiation. 4.14. Electric dipole selection rules for one electron atoms. 4.15. Electron spin. 4.16. Many-electron problems. 4.17. Electron photo effects -- 5. Photons. 5.1. Power-frequency relationships. 5.2. Length of the wave train and radiation Q. 5.3. Phase and radial dependence of field magnitude. 5.4. Gain and radiation pattern. 5.5. Kinematic values of the radiation. 5.6. Telefields and far fields. 5.7. Evaluation of sum S12 on the axes. 5.8. Evaluation of sums S22 and S32 on the polar axes. 5.9. Evaluation of sum S32 inthe equatorial plane. 5.10. Evaluation of sum S22 in the equatorial plane. 5.11. The axial fields, summary. 5.12. Infinite radius radiation pattern. 5.13. Self-consistent field analysis. 5.14. Power and energy exchange. 5.15. The wave train. 5.16. Multipolar moments. 5.17. Field stress on the active region. 5.18. Summary.
520			\|a This book presents a rigorous application of modern electromagnetic field theory to atomic theory. The historical view of quantum theory was developed before four major physical principles were known, or understood. These are (1) the standing energy that accompanies and encompasses electromagnetically active, electrically small volumes, (2) the power-frequency relationships in nonlinear systems, (3) the possible directivity of modal fields, and (4) electron nonlocality. The inclusion of these four effects yields a deterministic interpretation of quantum theory that is consistent with those of other sciences; the quixotic axioms of the historically accepted view of quantum theory are not needed. The new interpretation preserves the full applicability of electromagnetic field theory within atoms, showing that the status of all physical phenomena - including that within atoms - at any instant does completely specify the status an instant later.
650		0	\|a Quantum theory. \|0 http://id.loc.gov/authorities/subjects/sh85109469
650		0	\|a Quantum optics. \|0 http://id.loc.gov/authorities/subjects/sh85109465
650		0	\|a Electromagnetism. \|0 http://id.loc.gov/authorities/subjects/sh85042184
650		2	\|a Quantum Theory \|0 https://id.nlm.nih.gov/mesh/D011789
650		6	\|a Théorie quantique.
650		6	\|a Optique quantique.
650		6	\|a Électromagnétisme.
650		7	\|a electromagnetism. \|2 aat
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700	1		\|a Grimes, Craig A. \|0 http://id.loc.gov/authorities/names/n2002014426
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contents	1. Classical electrodynamics. 1.1. Introductory comments. 1.2. Space and time dependence upon speed. 1.3. Four-dimensional space time. 1.4. Newton's laws. 1.5. Electrodynamics. 1.6. The field equations. 1.7. Accelerating charges. 1.8. The Maxwell stress tensor. 1.9. Kinematic properties of fields. 1.10. A lemma for calculation of electromagnetic fields. 1.11. The scalar differential equation. 1.12. Radiation fields in spherical coordinates. 1.13. Electromagnetic fields in a box -- 2. Selected boundary value problems. 2.1. Traveling waves. 2.2. Scattering of a plane wave by a sphere. 2.3. Ideal spherical scatterers. 2.4. General comments. 2.5. Fields. 2.6. TEM mode. 2.7. Boundary conditions. 2.8. The defining integral equations. 2.9. Solution of the biconical antenna problem. 2.10. Power. 2.11. Field expansion for y-directed exponential. 2.12. Incoming TE fields. 2.13. Incoming TM fields. 2.14. Exterior fields, powers, and forces. 2.15. The cross sections. 2.16. General comments. 2.17. Fields of receiving antennas. 2.18. Boundary conditions. 2.19. Zero degree solution. 2.20. Non-zero degree solutions. 2.21. Surface current densities. 2.22. Power -- 3. Antenna Q. 3.1. Instantaneous and complex power in circuits. 3.2. Instantaneous and complex power in fields. 3.3. Time varying power in actual radiation fields. 3.4. Comparison of complex and instantaneous powers. 3.5. Radiation Q. 3.6. Chu's Q analysis, TM fields. 3.7. Chu's Q analysis, exact for TM fields. 3.8. Chu's Q analysis, TE field. 3.9. Chu's Q analysis, collocated TM and TE modes. 3.10. Q the easy way, electrically small antennas. 3.11. Q on the basis of time-dependent field theory. 3.12. Q of a radiating electric dipole. 3.13. Surface pressure on dipolar source. 3.14. Q of radiating magnetic dipoles. 3.15. Q of collocated electric and magnetic dipole pair. 3.16. Q of collocated, perpendicular electric dipoles. 3.17. Four collocated electric and magnetic dipoles and multipoles. 3.18. Numerical characterization of antennas. 3.19. Experimental characterization of antennas. 3.20. Q of collocated electric and Magnetic dipoles: Numerical and experimental characterizations -- 4. Quantum theory. 4.1. Electrons. 4.2. Radiation reaction force. 4.3. The time-independent Schrodinger equation. 4.4. The uncertainty principle. 4.5. The time-dependent Schrodinger equation. 4.6. Quantum operator properties. 4.7. Orthogonality. 4.8. Electron angular momentum, central force fields. 4.9. The Coulomb potential source. 4.10. Hydrogen atom Eigenfunctions. 4.11. Perturbation analysis. 4.12. Non-ionizing transitions. 4.13. Absorption and emission of radiation. 4.14. Electric dipole selection rules for one electron atoms. 4.15. Electron spin. 4.16. Many-electron problems. 4.17. Electron photo effects -- 5. Photons. 5.1. Power-frequency relationships. 5.2. Length of the wave train and radiation Q. 5.3. Phase and radial dependence of field magnitude. 5.4. Gain and radiation pattern. 5.5. Kinematic values of the radiation. 5.6. Telefields and far fields. 5.7. Evaluation of sum S12 on the axes. 5.8. Evaluation of sums S22 and S32 on the polar axes. 5.9. Evaluation of sum S32 inthe equatorial plane. 5.10. Evaluation of sum S22 in the equatorial plane. 5.11. The axial fields, summary. 5.12. Infinite radius radiation pattern. 5.13. Self-consistent field analysis. 5.14. Power and energy exchange. 5.15. The wave train. 5.16. Multipolar moments. 5.17. Field stress on the active region. 5.18. Summary.
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"><subfield code="a">Grimes, Dale M.</subfield><subfield code="q">(Dale Mills),</subfield><subfield code="d">1926-</subfield><subfield code="1">https://id.oclc.org/worldcat/entity/E39PBJpYxgTgvhRRhT7TmRHgrq</subfield><subfield code="0">http://id.loc.gov/authorities/names/n90628495</subfield></datafield><datafield tag="245" ind1="1" ind2="4"><subfield code="a">The electromagnetic origin of quantum theory and light /</subfield><subfield code="c">Dale M. 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Grimes.</subfield></datafield><datafield tag="260" ind1=" " ind2=" "><subfield code="a">New Jersey :</subfield><subfield code="b">World Scientific,</subfield><subfield code="c">©2002.</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 online resource (xvi, 447 pages) :</subfield><subfield code="b">illustrations</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="a">text</subfield><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="a">computer</subfield><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="a">online resource</subfield><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="504" ind1=" " ind2=" "><subfield code="a">Includes bibliographical references and index.</subfield></datafield><datafield tag="588" ind1="0" ind2=" "><subfield code="a">Print version record.</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">1. Classical electrodynamics. 1.1. Introductory comments. 1.2. Space and time dependence upon speed. 1.3. Four-dimensional space time. 1.4. Newton's laws. 1.5. Electrodynamics. 1.6. The field equations. 1.7. Accelerating charges. 1.8. The Maxwell stress tensor. 1.9. Kinematic properties of fields. 1.10. A lemma for calculation of electromagnetic fields. 1.11. The scalar differential equation. 1.12. Radiation fields in spherical coordinates. 1.13. Electromagnetic fields in a box -- 2. Selected boundary value problems. 2.1. Traveling waves. 2.2. Scattering of a plane wave by a sphere. 2.3. Ideal spherical scatterers. 2.4. General comments. 2.5. Fields. 2.6. TEM mode. 2.7. Boundary conditions. 2.8. The defining integral equations. 2.9. Solution of the biconical antenna problem. 2.10. Power. 2.11. Field expansion for y-directed exponential. 2.12. Incoming TE fields. 2.13. Incoming TM fields. 2.14. Exterior fields, powers, and forces. 2.15. The cross sections. 2.16. General comments. 2.17. Fields of receiving antennas. 2.18. Boundary conditions. 2.19. Zero degree solution. 2.20. Non-zero degree solutions. 2.21. Surface current densities. 2.22. Power -- 3. Antenna Q. 3.1. Instantaneous and complex power in circuits. 3.2. Instantaneous and complex power in fields. 3.3. Time varying power in actual radiation fields. 3.4. Comparison of complex and instantaneous powers. 3.5. Radiation Q. 3.6. Chu's Q analysis, TM fields. 3.7. Chu's Q analysis, exact for TM fields. 3.8. Chu's Q analysis, TE field. 3.9. Chu's Q analysis, collocated TM and TE modes. 3.10. Q the easy way, electrically small antennas. 3.11. Q on the basis of time-dependent field theory. 3.12. Q of a radiating electric dipole. 3.13. Surface pressure on dipolar source. 3.14. Q of radiating magnetic dipoles. 3.15. Q of collocated electric and magnetic dipole pair. 3.16. Q of collocated, perpendicular electric dipoles. 3.17. Four collocated electric and magnetic dipoles and multipoles. 3.18. Numerical characterization of antennas. 3.19. Experimental characterization of antennas. 3.20. Q of collocated electric and Magnetic dipoles: Numerical and experimental characterizations -- 4. Quantum theory. 4.1. Electrons. 4.2. Radiation reaction force. 4.3. The time-independent Schrodinger equation. 4.4. The uncertainty principle. 4.5. The time-dependent Schrodinger equation. 4.6. Quantum operator properties. 4.7. Orthogonality. 4.8. Electron angular momentum, central force fields. 4.9. The Coulomb potential source. 4.10. Hydrogen atom Eigenfunctions. 4.11. Perturbation analysis. 4.12. Non-ionizing transitions. 4.13. Absorption and emission of radiation. 4.14. Electric dipole selection rules for one electron atoms. 4.15. Electron spin. 4.16. Many-electron problems. 4.17. Electron photo effects -- 5. Photons. 5.1. Power-frequency relationships. 5.2. Length of the wave train and radiation Q. 5.3. Phase and radial dependence of field magnitude. 5.4. Gain and radiation pattern. 5.5. Kinematic values of the radiation. 5.6. Telefields and far fields. 5.7. Evaluation of sum S12 on the axes. 5.8. Evaluation of sums S22 and S32 on the polar axes. 5.9. Evaluation of sum S32 inthe equatorial plane. 5.10. Evaluation of sum S22 in the equatorial plane. 5.11. The axial fields, summary. 5.12. Infinite radius radiation pattern. 5.13. Self-consistent field analysis. 5.14. Power and energy exchange. 5.15. The wave train. 5.16. Multipolar moments. 5.17. Field stress on the active region. 5.18. Summary.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">This book presents a rigorous application of modern electromagnetic field theory to atomic theory. The historical view of quantum theory was developed before four major physical principles were known, or understood. These are (1) the standing energy that accompanies and encompasses electromagnetically active, electrically small volumes, (2) the power-frequency relationships in nonlinear systems, (3) the possible directivity of modal fields, and (4) electron nonlocality. The inclusion of these four effects yields a deterministic interpretation of quantum theory that is consistent with those of other sciences; the quixotic axioms of the historically accepted view of quantum theory are not needed. The new interpretation preserves the full applicability of electromagnetic field theory within atoms, showing that the status of all physical phenomena - including that within atoms - at any instant does completely specify the status an instant later.</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Quantum theory.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85109469</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Quantum optics.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85109465</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Electromagnetism.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85042184</subfield></datafield><datafield tag="650" ind1=" " ind2="2"><subfield code="a">Quantum Theory</subfield><subfield code="0">https://id.nlm.nih.gov/mesh/D011789</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Théorie quantique.</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Optique quantique.</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Électromagnétisme.</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">electromagnetism.</subfield><subfield code="2">aat</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">SCIENCE</subfield><subfield code="x">Physics</subfield><subfield code="x">Quantum Theory.</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Electromagnetism</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Quantum optics</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Quantum theory</subfield><subfield code="2">fast</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Grimes, Craig A.</subfield><subfield code="0">http://id.loc.gov/authorities/names/n2002014426</subfield></datafield><datafield tag="758" ind1=" " ind2=" "><subfield code="i">has work:</subfield><subfield code="a">The electromagnetic origin of quantum theory and light (Text)</subfield><subfield code="1">https://id.oclc.org/worldcat/entity/E39PCFDjHyDrwCW7J9MXk8hp8y</subfield><subfield code="4">https://id.oclc.org/worldcat/ontology/hasWork</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Grimes, Dale M. 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spelling	Grimes, Dale M. (Dale Mills), 1926- https://id.oclc.org/worldcat/entity/E39PBJpYxgTgvhRRhT7TmRHgrq http://id.loc.gov/authorities/names/n90628495 The electromagnetic origin of quantum theory and light / Dale M. Grimes & Craig A. Grimes. New Jersey : World Scientific, ©2002. 1 online resource (xvi, 447 pages) : illustrations text txt rdacontent computer c rdamedia online resource cr rdacarrier Includes bibliographical references and index. Print version record. 1. Classical electrodynamics. 1.1. Introductory comments. 1.2. Space and time dependence upon speed. 1.3. Four-dimensional space time. 1.4. Newton's laws. 1.5. Electrodynamics. 1.6. The field equations. 1.7. Accelerating charges. 1.8. The Maxwell stress tensor. 1.9. Kinematic properties of fields. 1.10. A lemma for calculation of electromagnetic fields. 1.11. The scalar differential equation. 1.12. Radiation fields in spherical coordinates. 1.13. Electromagnetic fields in a box -- 2. Selected boundary value problems. 2.1. Traveling waves. 2.2. Scattering of a plane wave by a sphere. 2.3. Ideal spherical scatterers. 2.4. General comments. 2.5. Fields. 2.6. TEM mode. 2.7. Boundary conditions. 2.8. The defining integral equations. 2.9. Solution of the biconical antenna problem. 2.10. Power. 2.11. Field expansion for y-directed exponential. 2.12. Incoming TE fields. 2.13. Incoming TM fields. 2.14. Exterior fields, powers, and forces. 2.15. The cross sections. 2.16. General comments. 2.17. Fields of receiving antennas. 2.18. Boundary conditions. 2.19. Zero degree solution. 2.20. Non-zero degree solutions. 2.21. Surface current densities. 2.22. Power -- 3. Antenna Q. 3.1. Instantaneous and complex power in circuits. 3.2. Instantaneous and complex power in fields. 3.3. Time varying power in actual radiation fields. 3.4. Comparison of complex and instantaneous powers. 3.5. Radiation Q. 3.6. Chu's Q analysis, TM fields. 3.7. Chu's Q analysis, exact for TM fields. 3.8. Chu's Q analysis, TE field. 3.9. Chu's Q analysis, collocated TM and TE modes. 3.10. Q the easy way, electrically small antennas. 3.11. Q on the basis of time-dependent field theory. 3.12. Q of a radiating electric dipole. 3.13. Surface pressure on dipolar source. 3.14. Q of radiating magnetic dipoles. 3.15. Q of collocated electric and magnetic dipole pair. 3.16. Q of collocated, perpendicular electric dipoles. 3.17. Four collocated electric and magnetic dipoles and multipoles. 3.18. Numerical characterization of antennas. 3.19. Experimental characterization of antennas. 3.20. Q of collocated electric and Magnetic dipoles: Numerical and experimental characterizations -- 4. Quantum theory. 4.1. Electrons. 4.2. Radiation reaction force. 4.3. The time-independent Schrodinger equation. 4.4. The uncertainty principle. 4.5. The time-dependent Schrodinger equation. 4.6. Quantum operator properties. 4.7. Orthogonality. 4.8. Electron angular momentum, central force fields. 4.9. The Coulomb potential source. 4.10. Hydrogen atom Eigenfunctions. 4.11. Perturbation analysis. 4.12. Non-ionizing transitions. 4.13. Absorption and emission of radiation. 4.14. Electric dipole selection rules for one electron atoms. 4.15. Electron spin. 4.16. Many-electron problems. 4.17. Electron photo effects -- 5. Photons. 5.1. Power-frequency relationships. 5.2. Length of the wave train and radiation Q. 5.3. Phase and radial dependence of field magnitude. 5.4. Gain and radiation pattern. 5.5. Kinematic values of the radiation. 5.6. Telefields and far fields. 5.7. Evaluation of sum S12 on the axes. 5.8. Evaluation of sums S22 and S32 on the polar axes. 5.9. Evaluation of sum S32 inthe equatorial plane. 5.10. Evaluation of sum S22 in the equatorial plane. 5.11. The axial fields, summary. 5.12. Infinite radius radiation pattern. 5.13. Self-consistent field analysis. 5.14. Power and energy exchange. 5.15. The wave train. 5.16. Multipolar moments. 5.17. Field stress on the active region. 5.18. Summary. This book presents a rigorous application of modern electromagnetic field theory to atomic theory. The historical view of quantum theory was developed before four major physical principles were known, or understood. These are (1) the standing energy that accompanies and encompasses electromagnetically active, electrically small volumes, (2) the power-frequency relationships in nonlinear systems, (3) the possible directivity of modal fields, and (4) electron nonlocality. The inclusion of these four effects yields a deterministic interpretation of quantum theory that is consistent with those of other sciences; the quixotic axioms of the historically accepted view of quantum theory are not needed. The new interpretation preserves the full applicability of electromagnetic field theory within atoms, showing that the status of all physical phenomena - including that within atoms - at any instant does completely specify the status an instant later. Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Quantum optics. http://id.loc.gov/authorities/subjects/sh85109465 Electromagnetism. http://id.loc.gov/authorities/subjects/sh85042184 Quantum Theory https://id.nlm.nih.gov/mesh/D011789 Théorie quantique. Optique quantique. Électromagnétisme. electromagnetism. aat SCIENCE Physics Quantum Theory. bisacsh Electromagnetism fast Quantum optics fast Quantum theory fast Grimes, Craig A. http://id.loc.gov/authorities/names/n2002014426 has work: The electromagnetic origin of quantum theory and light (Text) https://id.oclc.org/worldcat/entity/E39PCFDjHyDrwCW7J9MXk8hp8y https://id.oclc.org/worldcat/ontology/hasWork Print version: Grimes, Dale M. (Dale Mills), 1926- Electromagnetic origin of quantum theory and light. River Edge, NJ : World Scientific, ©2002 9810247850 9789810247850 (DLC) 2002280600 (OCoLC)50035434 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=210741 Volltext
spellingShingle	Grimes, Dale M. (Dale Mills), 1926- The electromagnetic origin of quantum theory and light / 1. Classical electrodynamics. 1.1. Introductory comments. 1.2. Space and time dependence upon speed. 1.3. Four-dimensional space time. 1.4. Newton's laws. 1.5. Electrodynamics. 1.6. The field equations. 1.7. Accelerating charges. 1.8. The Maxwell stress tensor. 1.9. Kinematic properties of fields. 1.10. A lemma for calculation of electromagnetic fields. 1.11. The scalar differential equation. 1.12. Radiation fields in spherical coordinates. 1.13. Electromagnetic fields in a box -- 2. Selected boundary value problems. 2.1. Traveling waves. 2.2. Scattering of a plane wave by a sphere. 2.3. Ideal spherical scatterers. 2.4. General comments. 2.5. Fields. 2.6. TEM mode. 2.7. Boundary conditions. 2.8. The defining integral equations. 2.9. Solution of the biconical antenna problem. 2.10. Power. 2.11. Field expansion for y-directed exponential. 2.12. Incoming TE fields. 2.13. Incoming TM fields. 2.14. Exterior fields, powers, and forces. 2.15. The cross sections. 2.16. General comments. 2.17. Fields of receiving antennas. 2.18. Boundary conditions. 2.19. Zero degree solution. 2.20. Non-zero degree solutions. 2.21. Surface current densities. 2.22. Power -- 3. Antenna Q. 3.1. Instantaneous and complex power in circuits. 3.2. Instantaneous and complex power in fields. 3.3. Time varying power in actual radiation fields. 3.4. Comparison of complex and instantaneous powers. 3.5. Radiation Q. 3.6. Chu's Q analysis, TM fields. 3.7. Chu's Q analysis, exact for TM fields. 3.8. Chu's Q analysis, TE field. 3.9. Chu's Q analysis, collocated TM and TE modes. 3.10. Q the easy way, electrically small antennas. 3.11. Q on the basis of time-dependent field theory. 3.12. Q of a radiating electric dipole. 3.13. Surface pressure on dipolar source. 3.14. Q of radiating magnetic dipoles. 3.15. Q of collocated electric and magnetic dipole pair. 3.16. Q of collocated, perpendicular electric dipoles. 3.17. Four collocated electric and magnetic dipoles and multipoles. 3.18. Numerical characterization of antennas. 3.19. Experimental characterization of antennas. 3.20. Q of collocated electric and Magnetic dipoles: Numerical and experimental characterizations -- 4. Quantum theory. 4.1. Electrons. 4.2. Radiation reaction force. 4.3. The time-independent Schrodinger equation. 4.4. The uncertainty principle. 4.5. The time-dependent Schrodinger equation. 4.6. Quantum operator properties. 4.7. Orthogonality. 4.8. Electron angular momentum, central force fields. 4.9. The Coulomb potential source. 4.10. Hydrogen atom Eigenfunctions. 4.11. Perturbation analysis. 4.12. Non-ionizing transitions. 4.13. Absorption and emission of radiation. 4.14. Electric dipole selection rules for one electron atoms. 4.15. Electron spin. 4.16. Many-electron problems. 4.17. Electron photo effects -- 5. Photons. 5.1. Power-frequency relationships. 5.2. Length of the wave train and radiation Q. 5.3. Phase and radial dependence of field magnitude. 5.4. Gain and radiation pattern. 5.5. Kinematic values of the radiation. 5.6. Telefields and far fields. 5.7. Evaluation of sum S12 on the axes. 5.8. Evaluation of sums S22 and S32 on the polar axes. 5.9. Evaluation of sum S32 inthe equatorial plane. 5.10. Evaluation of sum S22 in the equatorial plane. 5.11. The axial fields, summary. 5.12. Infinite radius radiation pattern. 5.13. Self-consistent field analysis. 5.14. Power and energy exchange. 5.15. The wave train. 5.16. Multipolar moments. 5.17. Field stress on the active region. 5.18. Summary. Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Quantum optics. http://id.loc.gov/authorities/subjects/sh85109465 Electromagnetism. http://id.loc.gov/authorities/subjects/sh85042184 Quantum Theory https://id.nlm.nih.gov/mesh/D011789 Théorie quantique. Optique quantique. Électromagnétisme. electromagnetism. aat SCIENCE Physics Quantum Theory. bisacsh Electromagnetism fast Quantum optics fast Quantum theory fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85109469 http://id.loc.gov/authorities/subjects/sh85109465 http://id.loc.gov/authorities/subjects/sh85042184 https://id.nlm.nih.gov/mesh/D011789
title	The electromagnetic origin of quantum theory and light /
title_auth	The electromagnetic origin of quantum theory and light /
title_exact_search	The electromagnetic origin of quantum theory and light /
title_full	The electromagnetic origin of quantum theory and light / Dale M. Grimes & Craig A. Grimes.
title_fullStr	The electromagnetic origin of quantum theory and light / Dale M. Grimes & Craig A. Grimes.
title_full_unstemmed	The electromagnetic origin of quantum theory and light / Dale M. Grimes & Craig A. Grimes.
title_short	The electromagnetic origin of quantum theory and light /
title_sort	electromagnetic origin of quantum theory and light
topic	Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Quantum optics. http://id.loc.gov/authorities/subjects/sh85109465 Electromagnetism. http://id.loc.gov/authorities/subjects/sh85042184 Quantum Theory https://id.nlm.nih.gov/mesh/D011789 Théorie quantique. Optique quantique. Électromagnétisme. electromagnetism. aat SCIENCE Physics Quantum Theory. bisacsh Electromagnetism fast Quantum optics fast Quantum theory fast
topic_facet	Quantum theory. Quantum optics. Electromagnetism. Quantum Theory Théorie quantique. Optique quantique. Électromagnétisme. electromagnetism. SCIENCE Physics Quantum Theory. Electromagnetism Quantum optics Quantum theory
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=210741
work_keys_str_mv	AT grimesdalem theelectromagneticoriginofquantumtheoryandlight AT grimescraiga theelectromagneticoriginofquantumtheoryandlight AT grimesdalem electromagneticoriginofquantumtheoryandlight AT grimescraiga electromagneticoriginofquantumtheoryandlight

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