We discuss a thermodynamic identity which helps explain why 〈H〉≠〈T00〉 at finite temperature. In addition we complete the discussion of the gravitational force by including the gravitational variation of the temperature. Gradients in the temperature induce extra forces not accounted for by the usual coupling to the energy-momentum tensor
We demonstrate that the equivalence principle is violated by radiative corrections to the gravitatio...
Richard C. Tolman analyzed the relation between a temperature gradient and a gravitational field in ...
We formulate the first law of global thermodynamics for stationary states of the ideal gas in the gr...
We discuss a thermodynamic identity which helps explain why 〈H〉≠〈T00〉 at finite temperature. In addi...
We discuss a thermodynamic identity which helps explain why ≠ at finite temperature. In addition we ...
We discuss a thermodynamic identity which helps explain why (Hiss(Too) at finite temperature. In add...
Gravitons are described by the propagator in teleparallel gravity in nearly flat space-time. Finite ...
Using the techniques of finite-temperature field theory we renormalize the electromagnetic and gravi...
Using the techniques of finite-temperature field theory we renormalize the electromagnetic and gravi...
Temperature effects in a scalar field non-minimally coupled to gravity are investigated. The Thermo ...
Using the techniques of finite-temperature field theory we renormalize the electromagnetic and gravi...
The Thermo Field Dynamics (TFD) formalism is used to investigate the regular black holes at finite t...
In accordance with the special theory of relativity all forms of energy, including heat, have inerti...
The consistency of the results of measuring the gravitational force temperature depend-ence obtained...
We demonstrate that the equivalence principle is violated by radiative corrections to the gravitatio...
We demonstrate that the equivalence principle is violated by radiative corrections to the gravitatio...
Richard C. Tolman analyzed the relation between a temperature gradient and a gravitational field in ...
We formulate the first law of global thermodynamics for stationary states of the ideal gas in the gr...
We discuss a thermodynamic identity which helps explain why 〈H〉≠〈T00〉 at finite temperature. In addi...
We discuss a thermodynamic identity which helps explain why ≠ at finite temperature. In addition we ...
We discuss a thermodynamic identity which helps explain why (Hiss(Too) at finite temperature. In add...
Gravitons are described by the propagator in teleparallel gravity in nearly flat space-time. Finite ...
Using the techniques of finite-temperature field theory we renormalize the electromagnetic and gravi...
Using the techniques of finite-temperature field theory we renormalize the electromagnetic and gravi...
Temperature effects in a scalar field non-minimally coupled to gravity are investigated. The Thermo ...
Using the techniques of finite-temperature field theory we renormalize the electromagnetic and gravi...
The Thermo Field Dynamics (TFD) formalism is used to investigate the regular black holes at finite t...
In accordance with the special theory of relativity all forms of energy, including heat, have inerti...
The consistency of the results of measuring the gravitational force temperature depend-ence obtained...
We demonstrate that the equivalence principle is violated by radiative corrections to the gravitatio...
We demonstrate that the equivalence principle is violated by radiative corrections to the gravitatio...
Richard C. Tolman analyzed the relation between a temperature gradient and a gravitational field in ...
We formulate the first law of global thermodynamics for stationary states of the ideal gas in the gr...
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