Using a configuration-interaction variational method, we accurately compute the reduced, single-electron von Neumann and linear entropy for several low-energy, singlet and triplet eigenstates of helium atom. We estimate the amount of electron-electron orbital entanglement for such eigenstates and show that it decays with energy
ABSTRACT: Shannon entropies and Fisher information calculated from one-particle density distribution...
We use the concept of quantum entanglement to give a physical meaning to the electron correlation e...
We explore ground-state entanglement properties of helium atom confined at the center of an impenetr...
Using a configuration-interaction variational method, we accurately compute the reduced, single-elec...
Using a configuration-interaction variational method, we accurately compute the reduced, single-elec...
Using a configuration-interaction variational method, we accurately compute the reduced, single-elec...
Using a configuration-interaction variational method, we accurately compute the reduced, s...
We compute the entanglement of the ground state and several singlet and triplet excited states of th...
In this work we have performed state-of-the-art configuration-interaction (CI) calculations to deter...
We compute the entanglement of the ground state and several singlet and triplet excited states of th...
We compute the entanglement of the ground state and several singlet and triplet excited states of th...
ABSTRACT: Shannon entropy and Fisher information calculated from one-particle density distributions ...
With a model of a one-dimensional two-electron atom we study the entanglement properties between two...
Entanglement is a concept commonly used with reference to the existence of certain correlations in q...
The thesis aims to study the applicability of techniques of Quantum Information theory to complex sy...
ABSTRACT: Shannon entropies and Fisher information calculated from one-particle density distribution...
We use the concept of quantum entanglement to give a physical meaning to the electron correlation e...
We explore ground-state entanglement properties of helium atom confined at the center of an impenetr...
Using a configuration-interaction variational method, we accurately compute the reduced, single-elec...
Using a configuration-interaction variational method, we accurately compute the reduced, single-elec...
Using a configuration-interaction variational method, we accurately compute the reduced, single-elec...
Using a configuration-interaction variational method, we accurately compute the reduced, s...
We compute the entanglement of the ground state and several singlet and triplet excited states of th...
In this work we have performed state-of-the-art configuration-interaction (CI) calculations to deter...
We compute the entanglement of the ground state and several singlet and triplet excited states of th...
We compute the entanglement of the ground state and several singlet and triplet excited states of th...
ABSTRACT: Shannon entropy and Fisher information calculated from one-particle density distributions ...
With a model of a one-dimensional two-electron atom we study the entanglement properties between two...
Entanglement is a concept commonly used with reference to the existence of certain correlations in q...
The thesis aims to study the applicability of techniques of Quantum Information theory to complex sy...
ABSTRACT: Shannon entropies and Fisher information calculated from one-particle density distribution...
We use the concept of quantum entanglement to give a physical meaning to the electron correlation e...
We explore ground-state entanglement properties of helium atom confined at the center of an impenetr...
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