Add to ORKGThere is a well-known analogy between statistical and quantum mechanics. In statistical mechanics, Boltzmann realized that the probability for a system in thermal equilibrium to occupy a given state is proportional to exp(-E=kT), where E is the energy of that state. In quantum mechanics, Feynman realized that the amplitude for a system to undergo a given history is proportional to exp(-S=ih), where S is the action of that history. In statistical mechanics, we can recover Boltzmann's formula by maximizing entropy subject to a constraint on the expected energy. This raises the question: what is the quantum mechanical analogue of entropy? We give a formula for this quantity, which we call "quantropy". We recover Feynman's formula from assuming...
Classical statistical equilibrium, for a Maxwell-Boltzmann gas for example, is based on localizing t...
A bound quantum state wavefunction has a factor exp(iEt), where E is the energy, but in the calculat...
We show that the quantum statistical mechanics (QSM) describing quantum and thermal properties of ob...
There is a well-known analogy between statistical and quantum mechanics. In statistical mechanics, B...
There is a well-known analogy between statistical and quantum mechanics. In statistical mechanics, B...
Is there a link between the macroscopic description of the irreversibility and microscopic behaviour...
There is a focus in classical statistical mechanics on maximizing an entropy function subject to con...
The quantum entropy is usually defined using von Neumann's formula, which measures lack of informati...
Equilibrium classical statistical mechanical distributions are often derived from maximizing (in a v...
We argue that classical statistical mechanics (say of an ideal gas) is based on a single equilibrati...
What is the physical significance of entropy? What is the physical origin of irreversibility? Do ent...
Historically, thermodynamics was formulated for macroscopic systems followed by the development of s...
In this thesis we develop an approach to nonequilibrium quantum-statistical mechanics which is based...
Entropy is the distinguishing and most important concept of our efforts to understand and regularize...
Classical statistical mechanical density maximizes entropy subject to constraints i.e. one has the M...
Classical statistical equilibrium, for a Maxwell-Boltzmann gas for example, is based on localizing t...
A bound quantum state wavefunction has a factor exp(iEt), where E is the energy, but in the calculat...
We show that the quantum statistical mechanics (QSM) describing quantum and thermal properties of ob...
There is a well-known analogy between statistical and quantum mechanics. In statistical mechanics, B...
There is a well-known analogy between statistical and quantum mechanics. In statistical mechanics, B...
Is there a link between the macroscopic description of the irreversibility and microscopic behaviour...
There is a focus in classical statistical mechanics on maximizing an entropy function subject to con...
The quantum entropy is usually defined using von Neumann's formula, which measures lack of informati...
Equilibrium classical statistical mechanical distributions are often derived from maximizing (in a v...
We argue that classical statistical mechanics (say of an ideal gas) is based on a single equilibrati...
What is the physical significance of entropy? What is the physical origin of irreversibility? Do ent...
Historically, thermodynamics was formulated for macroscopic systems followed by the development of s...
In this thesis we develop an approach to nonequilibrium quantum-statistical mechanics which is based...
Entropy is the distinguishing and most important concept of our efforts to understand and regularize...
Classical statistical mechanical density maximizes entropy subject to constraints i.e. one has the M...
Classical statistical equilibrium, for a Maxwell-Boltzmann gas for example, is based on localizing t...
A bound quantum state wavefunction has a factor exp(iEt), where E is the energy, but in the calculat...
We show that the quantum statistical mechanics (QSM) describing quantum and thermal properties of ob...