There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution. TOC:A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz-Dirac Equation.- Extending the Lorentz-Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Summary.- Conclusion eBook Stephen N. Lyle PDF, Springer, 22.07.2008, Springer, 2008<
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There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution. TOC:A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz-Dirac Equation.- Extending the Lorentz-Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Summary.- Conclusion eBook Stephen N. Lyle PDF, Springer, 22.07.2008, Springer, 2008<
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(*) Derzeit vergriffen bedeutet, dass dieser Titel momentan auf keiner der angeschlossenen Plattform verfügbar ist.
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution. TOC:A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz-Dirac Equation.- Extending the Lorentz-Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Summary.- Conclusion eBook Stephen N. Lyle 22.07.2008, Springer, Springer<
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(*) Derzeit vergriffen bedeutet, dass dieser Titel momentan auf keiner der angeschlossenen Plattform verfügbar ist.
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution., Springer<
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution. TOC:A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz-Dirac Equation.- Extending the Lorentz-Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Summary.- Conclusion eBook Stephen N. Lyle PDF, Springer, 22.07.2008, Springer, 2008<
Nr. 24490371. Versandkosten:, Sofort per Download lieferbar, DE. (EUR 0.00)
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution. TOC:A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz-Dirac Equation.- Extending the Lorentz-Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Summary.- Conclusion eBook Stephen N. Lyle PDF, Springer, 22.07.2008, Springer, 2008<
Nr. 24490371. Versandkosten:, Sofort per Download lieferbar, DE. (EUR 0.00)
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution. TOC:A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz-Dirac Equation.- Extending the Lorentz-Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Summary.- Conclusion eBook Stephen N. Lyle 22.07.2008, Springer, Springer<
Nr. 24490371. Versandkosten:, Sofort per Download lieferbar, zzgl. Versandkosten. (EUR 16.99)
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., … Mehr…
There has been a long debate about whether uniformly accelerated charges should radiate electromagnetic energy and how one should describe their worldline through a flat spacetime, i.e., whether the Lorentz-Dirac equation is right. There are related questions in curved spacetimes, e.g., do different varieties of equivalence principle apply to charged particles, and can a static charge in a static spacetime radiate electromagnetic energy? The problems with the LD equation in flat spacetime are spelt out in some detail here, and its extension to curved spacetime is discussed. Different equivalence principles are compared and some vindicated. The key papers are discussed in detail and many of their conclusions are significantly revised by the present solution., Springer<
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Detailangaben zum Buch - Uniformly Accelerating Charged Particles
EAN (ISBN-13): 9783540684770 ISBN (ISBN-10): 3540684778 Erscheinungsjahr: 2008 Herausgeber: Springer Berlin 362 Seiten Sprache: eng/Englisch
Buch in der Datenbank seit 2010-07-01T16:54:01+02:00 (Berlin) Detailseite zuletzt geändert am 2023-09-18T17:41:55+02:00 (Berlin) ISBN/EAN: 3540684778
ISBN - alternative Schreibweisen: 3-540-68477-8, 978-3-540-68477-0 Alternative Schreibweisen und verwandte Suchbegriffe: Autor des Buches: minkowski Titel des Buches: uniformly accelerating charged particles, uniform, equivalence principle
Daten vom Verlag:
Autor/in: Stephen Lyle Titel: Fundamental Theories of Physics; Uniformly Accelerating Charged Particles - A Threat to the Equivalence Principle Verlag: Springer; Springer Berlin 361 Seiten Erscheinungsjahr: 2008-07-22 Berlin; Heidelberg; DE Sprache: Englisch 149,79 € (DE) 154,00 € (AT) 177,00 CHF (CH) Available XV, 361 p.
EA; E107; eBook; Nonbooks, PBS / Physik, Astronomie/Atomphysik, Kernphysik; Physik; Verstehen; Charged particle; Equivalence principles; Gravity; Lorentz-Dirac equation; Minkowski space; Relativity; Special relativity; general relativity; B; Nuclear and Particle Physics; Classical and Quantum Gravity; Theoretical, Mathematical and Computational Physics; Classical Electrodynamics; Physics and Astronomy; Gravitation; Mathematische Physik; Elektrizität, Magnetismus und Elektromagnetismus; BB
A Doubt about the Equivalence Principle.- From Minkowski Spacetime to General Relativity.- Gravity as a Force in Special Relativity.- Applying the Strong Equivalence Principle.- The Debate Continues.- A More Detailed Radiation Calculation.- Defining the Radiation from a Uniformly Accelerating Charge.- Energy Conservation for a Uniformly Accelerated Charge.- The Threat to the Equivalence Principle According to Fulton and Rohrlich.- Different Predictions of Special Relativity and General Relativity.- Derivation of the Lorentz–Dirac Equation.- Extending the Lorentz–Dirac Equation to Curved Spacetime.- Static Charge in a Static Spacetime.- A Radiation Detector.- The Definitive Mathematical Analysis.- Interpretation of Physical Quantities in General Relativity.- Charged Rocket.- Summary.- Conclusion. Addresses and even solves open questions in General Relativity Reviews wide range of partly conflicting literature Includes supplementary material: sn.pub/extras
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