If we assume that the source of thermodynamic system, ρ and p, are also the source of gravity, then either thermal quantities, such as entropy, temperature, and chemical potential, can induce gravitational effects, or gravity can induce thermal effects. We find that gravity can be seen as entropic force only for systems with constant temperature and zero chemical potential. The case for Newtonian approximation is discussed
We discuss a thermodynamic identity which helps explain why (Hiss(Too) at finite temperature. In add...
The paper introduces the notion of “entropy harvesting” in physical and biological systems. Various ...
We discuss a thermodynamic identity which helps explain why ≠ at finite temperature. In addition we ...
The remarkable connections between gravity and thermodynamics seem to imply that gravity is not fund...
In the scenario of entropic gravity, entropy varies as a function of the location of the matter, whi...
Motivated by Verlinde's theory of entropic gravity, we give a tentative explanation to the Coul...
In Verlinde's formalism, gravity is an emergent phenomenon which can be interpreted as an entropic f...
Abstract Explicit tests are presented of the conjectured entropic origin of the gravitational force....
AbstractWe generalize the study of entropic force to a general static spherical spacetime and examin...
Following Verlinde’s conjecture, we show that Tsallis’ classical free particle distribution at tempe...
We clarify the problem in which occasions can gravitational force be regarded emergent from thermody...
We consider the formulation of entropic gravity in two spacetime dimensions. The usual gravitational...
The main objective of this work is to develop an integral theory for a wide class of fluid systems t...
Under natural assumptions on the thermodynamic properties of space and time with the holo-graphic pr...
In accordance with the special theory of relativity all forms of energy, including heat, have inerti...
We discuss a thermodynamic identity which helps explain why (Hiss(Too) at finite temperature. In add...
The paper introduces the notion of “entropy harvesting” in physical and biological systems. Various ...
We discuss a thermodynamic identity which helps explain why ≠ at finite temperature. In addition we ...
The remarkable connections between gravity and thermodynamics seem to imply that gravity is not fund...
In the scenario of entropic gravity, entropy varies as a function of the location of the matter, whi...
Motivated by Verlinde's theory of entropic gravity, we give a tentative explanation to the Coul...
In Verlinde's formalism, gravity is an emergent phenomenon which can be interpreted as an entropic f...
Abstract Explicit tests are presented of the conjectured entropic origin of the gravitational force....
AbstractWe generalize the study of entropic force to a general static spherical spacetime and examin...
Following Verlinde’s conjecture, we show that Tsallis’ classical free particle distribution at tempe...
We clarify the problem in which occasions can gravitational force be regarded emergent from thermody...
We consider the formulation of entropic gravity in two spacetime dimensions. The usual gravitational...
The main objective of this work is to develop an integral theory for a wide class of fluid systems t...
Under natural assumptions on the thermodynamic properties of space and time with the holo-graphic pr...
In accordance with the special theory of relativity all forms of energy, including heat, have inerti...
We discuss a thermodynamic identity which helps explain why (Hiss(Too) at finite temperature. In add...
The paper introduces the notion of “entropy harvesting” in physical and biological systems. Various ...
We discuss a thermodynamic identity which helps explain why ≠ at finite temperature. In addition we ...
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