Your search keyword '"Major, Seth"' showing total 15 results

1. On energy for accelerating observers in black hole spacetimes

Author

Major, Seth A. and Major, Seth A.

Abstract

Quasi-local energies for constantly accelerating observers in Ba\~nados, Teitelboim, and Zanelli (BTZ), Schwarzschild and Schwarzschild-de Sitter spacetimes are derived. The energies are expressed in terms of acceleration, cosmological constant, and area, quantities measurable by the observers. Based on results from quantum fields in curved spacetime for the redshifted Hawking temperature, entropy and thermodynamic-like laws are briefly explored in the three spacetimes., Comment: Comments welcome. v2: description of the approach and derivation clarified. v3: updated referencing, typos corrected, close to published version

Published

2022

2. On energy for accelerating observers in black hole spacetimes

Author

Major, Seth A. and Major, Seth A.

Abstract

Quasi-local energies for constantly accelerating observers in Ba\~nados, Teitelboim, and Zanelli (BTZ), Schwarzschild and Schwarzschild-de Sitter spacetimes are derived. The energies are expressed in terms of acceleration, cosmological constant, and area, quantities measurable by the observers. Based on results from quantum fields in curved spacetime for the redshifted Hawking temperature, entropy and thermodynamic-like laws are briefly explored in the three spacetimes., Comment: Comments welcome. v2: description of the approach and derivation clarified. v3: updated referencing, typos corrected, close to published version

Published

2022

3. On Modified Dispersion Relations and the Chandrasekhar Mass Limit

Author

Gregg, Michael, Major, Seth A., Gregg, Michael, and Major, Seth A.

Abstract

Modified dispersion relations from effective field theory are shown to alter the Chandrasekhar mass limit. At exceptionally high densities, the modifications affect the pressure of a degenerate electron gas and can increase or decrease the mass limit, depending on the sign of the modifications. These changes to the mass limit are unlikely to be relevant for the astrophysics of white dwarf or neutron stars due to well-known dynamical instabilities that occur at lower densities. Generalizations to frameworks other than effective field theory are discussed., Comment: 14 pages, 2 figures; v2: version accepted for publication, minor changes; v3: note added correcting comments on the applicability of the calculation to the DSR context, references added, results unchanged

Published

2008

4. On Modified Dispersion Relations and the Chandrasekhar Mass Limit

Author

Gregg, Michael, Major, Seth A., Gregg, Michael, and Major, Seth A.

Abstract

Modified dispersion relations from effective field theory are shown to alter the Chandrasekhar mass limit. At exceptionally high densities, the modifications affect the pressure of a degenerate electron gas and can increase or decrease the mass limit, depending on the sign of the modifications. These changes to the mass limit are unlikely to be relevant for the astrophysics of white dwarf or neutron stars due to well-known dynamical instabilities that occur at lower densities. Generalizations to frameworks other than effective field theory are discussed., Comment: 14 pages, 2 figures; v2: version accepted for publication, minor changes; v3: note added correcting comments on the applicability of the calculation to the DSR context, references added, results unchanged

Published

2008

5. On Recovering Continuum Topology from a Causal Set

Author

Major, Seth, Rideout, David, Surya, Sumati, Major, Seth, Rideout, David, and Surya, Sumati

Abstract

An important question that discrete approaches to quantum gravity must address is how continuum features of spacetime can be recovered from the discrete substructure. Here, we examine this question within the causal set approach to quantum gravity, where the substructure replacing the spacetime continuum is a locally finite partial order. A new topology on causal sets using ``thickened antichains'' is constructed. This topology is then used to recover the homology of a globally hyperbolic spacetime from a causal set which faithfully embeds into it at sufficiently high sprinkling density. This implies a discrete-continuum correspondence which lends support to the fundamental conjecture or ``Hauptvermutung'' of causal set theory., Comment: The statement of a lemma has been simplified and the proof rewritten. Errors have been corrected. One figure has been removed. All results remain unchanged. Accepted for publication in JMP. 31 pages, 4 figs

Published

2006

6. On Recovering Continuum Topology from a Causal Set

Author

Major, Seth, Rideout, David, Surya, Sumati, Major, Seth, Rideout, David, and Surya, Sumati

Abstract

An important question that discrete approaches to quantum gravity must address is how continuum features of spacetime can be recovered from the discrete substructure. Here, we examine this question within the causal set approach to quantum gravity, where the substructure replacing the spacetime continuum is a locally finite partial order. A new topology on causal sets using ``thickened antichains'' is constructed. This topology is then used to recover the homology of a globally hyperbolic spacetime from a causal set which faithfully embeds into it at sufficiently high sprinkling density. This implies a discrete-continuum correspondence which lends support to the fundamental conjecture or ``Hauptvermutung'' of causal set theory., Comment: The statement of a lemma has been simplified and the proof rewritten. Errors have been corrected. One figure has been removed. All results remain unchanged. Accepted for publication in JMP. 31 pages, 4 figs

Published

2006

7. Observational Limits on Quantum Geometry Effects

Author

Konopka, Tomasz J., Major, Seth A., Konopka, Tomasz J., and Major, Seth A.

Abstract

Using a form of modified dispersion relations derived in the context of quantum geometry, we investigate limits set by current observations on potential corrections to Lorentz invariance. We use a phenomological model in which there are separate parameters for photons, leptons, and hadrons. Constraints on these parameters are derived using thresholds for the processes of photon stability, photon absorption, vacuum Cerenkov radiation, pion stability, and the GZK cutoff. Although the allowed region in parameter space is tightly constrained, non-vanishing corrections to Lorentz symmetry due to quantum geometry are consistent with current astrophysical observations., Comment: 17 pages, 4 eps figures; v2: references updated, revision in wording; v3: version to be published in New Jounral of Physics; v4: ref added

Published

2002

8. Observational Limits on Quantum Geometry Effects

Author

Konopka, Tomasz J., Major, Seth A., Konopka, Tomasz J., and Major, Seth A.

Abstract

Using a form of modified dispersion relations derived in the context of quantum geometry, we investigate limits set by current observations on potential corrections to Lorentz invariance. We use a phenomological model in which there are separate parameters for photons, leptons, and hadrons. Constraints on these parameters are derived using thresholds for the processes of photon stability, photon absorption, vacuum Cerenkov radiation, pion stability, and the GZK cutoff. Although the allowed region in parameter space is tightly constrained, non-vanishing corrections to Lorentz symmetry due to quantum geometry are consistent with current astrophysical observations., Comment: 17 pages, 4 eps figures; v2: references updated, revision in wording; v3: version to be published in New Jounral of Physics; v4: ref added

Published

2002

9. Observational Limits on Quantum Geometry Effects

Author

Konopka, Tomasz J., Major, Seth A., Konopka, Tomasz J., and Major, Seth A.

Abstract

Using a form of modified dispersion relations derived in the context of quantum geometry, we investigate limits set by current observations on potential corrections to Lorentz invariance. We use a phenomological model in which there are separate parameters for photons, leptons, and hadrons. Constraints on these parameters are derived using thresholds for the processes of photon stability, photon absorption, vacuum Cerenkov radiation, pion stability, and the GZK cutoff. Although the allowed region in parameter space is tightly constrained, non-vanishing corrections to Lorentz symmetry due to quantum geometry are consistent with current astrophysical observations., Comment: 17 pages, 4 eps figures; v2: references updated, revision in wording; v3: version to be published in New Jounral of Physics; v4: ref added

Published

2002

10. Gravitational Statistical Mechanics: A model

Author

Major, Seth A., Setter, Kevin L., Major, Seth A., and Setter, Kevin L.

Abstract

Using the quantum Hamiltonian for a gravitational system with boundary, we find the partition function and derive the resulting thermodynamics. The Hamiltonian is the boundary term required by functional differentiability of the action for Lorentzian general relativity. In this model, states of quantum geometry are represented by spin networks. We show that the statistical mechanics of the model reduces to that of a simple non-interacting gas of particles with spin. Using both canonical and grand canonical descriptions, we investigate two temperature regimes determined by the fundamental constant in the theory, m. In the high temperature limit (kT > m), the model is thermodynamically stable. For low temperatures (kT < m) and for macroscopic areas of the bounding surface, the entropy is proportional to area (with logarithmic correction), providing a simple derivation of the Bekenstein-Hawking result. By comparing our results to known semiclassical relations we are able to fix the fundamental scale. Also in the low temperature, macroscopic limit, the quantum geometry on the boundary forms a `condensate' in the lowest energy level (j=1/2)., Comment: 19 pages, 1 figure; v2: typos corrected, first law discussion removed, geometric particle description revised

Published

2001

11. Gravitational Statistical Mechanics: A model

Author

Major, Seth A., Setter, Kevin L., Major, Seth A., and Setter, Kevin L.

Abstract

Using the quantum Hamiltonian for a gravitational system with boundary, we find the partition function and derive the resulting thermodynamics. The Hamiltonian is the boundary term required by functional differentiability of the action for Lorentzian general relativity. In this model, states of quantum geometry are represented by spin networks. We show that the statistical mechanics of the model reduces to that of a simple non-interacting gas of particles with spin. Using both canonical and grand canonical descriptions, we investigate two temperature regimes determined by the fundamental constant in the theory, m. In the high temperature limit (kT > m), the model is thermodynamically stable. For low temperatures (kT < m) and for macroscopic areas of the bounding surface, the entropy is proportional to area (with logarithmic correction), providing a simple derivation of the Bekenstein-Hawking result. By comparing our results to known semiclassical relations we are able to fix the fundamental scale. Also in the low temperature, macroscopic limit, the quantum geometry on the boundary forms a `condensate' in the lowest energy level (j=1/2)., Comment: 19 pages, 1 figure; v2: typos corrected, first law discussion removed, geometric particle description revised

Published

2001

12. Embedded graph invariants in Chern-Simons theory

Author

Major, Seth A. and Major, Seth A.

Abstract

Chern-Simons gauge theory, since its inception as a topological quantum field theory, has proved to be a rich source of understanding for knot invariants. In this work the theory is used to explore the definition of the expectation value of a network of Wilson lines - an embedded graph invariant. Using a slight generalization of the variational method, lowest-order results for invariants for arbitrary valence graphs are derived; gauge invariant operators are introduced; and some higher order results are found. The method used here provides a Vassiliev-type definition of graph invariants which depend on both the embedding of the graph and the group structure of the gauge theory. It is found that one need not frame individual vertices. Though, without a global projection of the graph, there is an ambiguity in the relation of the decomposition of distinct vertices. It is suggested that framing may be seen as arising from this ambiguity - as a way of relating frames at distinct vertices., Comment: 20 pages; RevTex; with approx 50 ps figures; References added, introduction rewritten, version to be published in Nuc. Phys. B

Published

1998

13. Embedded graph invariants in Chern-Simons theory

Author

Major, Seth A. and Major, Seth A.

Abstract

Chern-Simons gauge theory, since its inception as a topological quantum field theory, has proved to be a rich source of understanding for knot invariants. In this work the theory is used to explore the definition of the expectation value of a network of Wilson lines - an embedded graph invariant. Using a slight generalization of the variational method, lowest-order results for invariants for arbitrary valence graphs are derived; gauge invariant operators are introduced; and some higher order results are found. The method used here provides a Vassiliev-type definition of graph invariants which depend on both the embedding of the graph and the group structure of the gauge theory. It is found that one need not frame individual vertices. Though, without a global projection of the graph, there is an ambiguity in the relation of the decomposition of distinct vertices. It is suggested that framing may be seen as arising from this ambiguity - as a way of relating frames at distinct vertices., Comment: 20 pages; RevTex; with approx 50 ps figures; References added, introduction rewritten, version to be published in Nuc. Phys. B

Published

1998

14. Gravity and BF theory defined in bounded regions

Author

Husain, Viqar, Major, Seth, Husain, Viqar, and Major, Seth

Abstract

We study Einstein gravity in a finite spatial region. By requiring a well-defined variational principle, we identify all local boundary conditions, derive surface observables, and compute their algebra. The observables arise as induced surface terms, which contribute to a non-vanishing Hamiltonian. Unlike the asymptotically flat case, we find that there are an infinite number of surface observables. We give a similar analysis for SU(2) BF theory., Comment: References added

Published

1997

15. Gravity and BF theory defined in bounded regions

Author

Husain, Viqar, Major, Seth, Husain, Viqar, and Major, Seth

Abstract

We study Einstein gravity in a finite spatial region. By requiring a well-defined variational principle, we identify all local boundary conditions, derive surface observables, and compute their algebra. The observables arise as induced surface terms, which contribute to a non-vanishing Hamiltonian. Unlike the asymptotically flat case, we find that there are an infinite number of surface observables. We give a similar analysis for SU(2) BF theory., Comment: References added

Published

1997