In the classical regime, thermodynamic state transformations are governed by the free energy. This is also called as the second law of thermodynamics. Previous works showed that, access to a catalytic system allows us to restore the second law in the quantum regime when we ignore coherence. However, in the quantum regime, coherence and free energy are two independent resources. Therefore, coherence places additional non-trivial restrictions on the the state transformations, that remains elusive. In order to close this gap, we isolate and study the nature of coherence, i.e. we assume access to a source of free energy. We show that allowing catalysis along with a source of free energy allows us to amplify any quantum coherence present in the ...
The interplay between quantum-mechanical properties, such as coherence, and classical notions, such ...
Recent studies have pointed out the intrinsic dependence of figures of merit of thermodynamic releva...
© 2018, The Author(s). What does it mean for one quantum process to be more disordered than another?...
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
Planck found, when attempting to describe the way in which hot bodies glow, that energy at microscop...
In the framework of quantum thermodynamics preparing a quantum system in a general state requires th...
We find necessary and sufficient conditions to determine the inter-convertibility of quantum systems...
Quantum coherence is one of the fundamental aspects distinguishing classical and quantum theories. C...
Quantum coherence, the ability to control the phases in superposition states is a resource, and it i...
Quantum resource manipulation may include an ancillary state called a catalyst, which aids the trans...
In thermodynamics, quantum coherences—superpositions between energy eigenstates—behave in distinctly...
Quantum decoherence is seen as an undesired source of irreversibility that destroys quantum resource...
In this quantum thermodynamics [1] talk, I will discuss work extraction in the quantum regime. We se...
Thermodynamics is a highly successful macroscopic theory widely used across the natural sciences and...
The interplay between quantum-mechanical properties, such as coherence, and classical notions, such ...
Recent studies have pointed out the intrinsic dependence of figures of merit of thermodynamic releva...
© 2018, The Author(s). What does it mean for one quantum process to be more disordered than another?...
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
Planck found, when attempting to describe the way in which hot bodies glow, that energy at microscop...
In the framework of quantum thermodynamics preparing a quantum system in a general state requires th...
We find necessary and sufficient conditions to determine the inter-convertibility of quantum systems...
Quantum coherence is one of the fundamental aspects distinguishing classical and quantum theories. C...
Quantum coherence, the ability to control the phases in superposition states is a resource, and it i...
Quantum resource manipulation may include an ancillary state called a catalyst, which aids the trans...
In thermodynamics, quantum coherences—superpositions between energy eigenstates—behave in distinctly...
Quantum decoherence is seen as an undesired source of irreversibility that destroys quantum resource...
In this quantum thermodynamics [1] talk, I will discuss work extraction in the quantum regime. We se...
Thermodynamics is a highly successful macroscopic theory widely used across the natural sciences and...
The interplay between quantum-mechanical properties, such as coherence, and classical notions, such ...
Recent studies have pointed out the intrinsic dependence of figures of merit of thermodynamic releva...
© 2018, The Author(s). What does it mean for one quantum process to be more disordered than another?...