The general form of the Stefan-Boltzmann law for the energy density of black-body radiation is generalized to a spacetime with extra dimensions using standard kinetic and thermodynamic arguments. From statistical mechanics one obtains an exact formula. In a field-theoretic derivation, the Maxwell field must be quantized. The notion of electric and magnetic fields is different in spacetimes with more than four dimensions. While the energy-momentum tensor for the Maxwell field is traceless in four dimensions, it is not so when there are extra dimensions. But it is shown that its thermal average is traceless and in agreement with the thermodynamic results
The blackbody theory is revisited in the case of thermal electromagnetic fields inside uniaxial anis...
The Planck’s law of blackbody radiation is derived in several methods in this paper. The original Pl...
Within the framework of nonextensive statistical mechanics (NSM), we generalize the radiat...
The blackbody radiation is analyzed in a universe with D spatial dimensions. Using the classical ele...
In this work, we present the generalization of some thermodynamic properties of the black body radia...
We generalize Planck's law for black-bodies, classically described by Maxwell-Boltzmann distribution...
The Stefan-Boltzmann (SB) law relates the emissivity $q$, given in $Wm^{-2}$, of an ideal black-body...
We give an exact information-theory treatment of the n-dimensional black-body radiation process in a...
The Stefan-Boltzmann (SB) law relates the radiant emittance of an ideal black-bodycavity at thermal ...
The Feynman-Vernon formalism is used to obtain a microscopic, quantum mechanical derivation of black...
Here, we demonstrate that the power spectral density of thermal radiation at a specific wavelength p...
In this work we apply superstatistics, in a rather novel way, to derive the blackbody radiation laws...
We study the blackbody properties and the thermodynamic equilibrium quantities of a photon gas in th...
The generalized uncertainty principle (GUP) modifies the uncertainty relation between momentum and p...
We investigate the thermodynamics of a photon gas in an effective field theory model that describes ...
The blackbody theory is revisited in the case of thermal electromagnetic fields inside uniaxial anis...
The Planck’s law of blackbody radiation is derived in several methods in this paper. The original Pl...
Within the framework of nonextensive statistical mechanics (NSM), we generalize the radiat...
The blackbody radiation is analyzed in a universe with D spatial dimensions. Using the classical ele...
In this work, we present the generalization of some thermodynamic properties of the black body radia...
We generalize Planck's law for black-bodies, classically described by Maxwell-Boltzmann distribution...
The Stefan-Boltzmann (SB) law relates the emissivity $q$, given in $Wm^{-2}$, of an ideal black-body...
We give an exact information-theory treatment of the n-dimensional black-body radiation process in a...
The Stefan-Boltzmann (SB) law relates the radiant emittance of an ideal black-bodycavity at thermal ...
The Feynman-Vernon formalism is used to obtain a microscopic, quantum mechanical derivation of black...
Here, we demonstrate that the power spectral density of thermal radiation at a specific wavelength p...
In this work we apply superstatistics, in a rather novel way, to derive the blackbody radiation laws...
We study the blackbody properties and the thermodynamic equilibrium quantities of a photon gas in th...
The generalized uncertainty principle (GUP) modifies the uncertainty relation between momentum and p...
We investigate the thermodynamics of a photon gas in an effective field theory model that describes ...
The blackbody theory is revisited in the case of thermal electromagnetic fields inside uniaxial anis...
The Planck’s law of blackbody radiation is derived in several methods in this paper. The original Pl...
Within the framework of nonextensive statistical mechanics (NSM), we generalize the radiat...