How to Install and Uninstall CheMPS2.i686 Package on Fedora 34
Last updated: November 17,2024
1. Install "CheMPS2.i686" package
Please follow the steps below to install CheMPS2.i686 on Fedora 34
$
sudo dnf update
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$
sudo dnf install
CheMPS2.i686
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2. Uninstall "CheMPS2.i686" package
Please follow the steps below to uninstall CheMPS2.i686 on Fedora 34:
$
sudo dnf remove
CheMPS2.i686
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$
sudo dnf autoremove
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3. Information about the CheMPS2.i686 package on Fedora 34
Last metadata expiration check: 3:25:02 ago on Tue Sep 6 08:10:37 2022.
Available Packages
Name : CheMPS2
Version : 1.8.9
Release : 11.fc34
Architecture : i686
Size : 561 k
Source : CheMPS2-1.8.9-11.fc34.src.rpm
Repository : fedora
Summary : A spin-adapted implementation of DMRG for ab initio quantum chemistry
URL : https://github.com/SebWouters/CheMPS2
License : GPLv2+
Description : The CheMPS2 library provides a free open-source spin-adapted
: implementation of the density matrix renormalization group (DMRG) for ab initio
: quantum chemistry. This method allows to obtain numerical accuracy in active
: spaces beyond the capabilities of full configuration interaction. For the
: input Hamiltonian and targeted symmetry sector, the library performs successive
: DMRG sweeps according to a user-defined convergence scheme. As output, the
: library returns the minimal encountered energy as well as the 2-RDM of the
: active space. The latter allows to calculate various properties, as well as
: the gradient and Hessian for orbital rotations or nuclear displacements.
Available Packages
Name : CheMPS2
Version : 1.8.9
Release : 11.fc34
Architecture : i686
Size : 561 k
Source : CheMPS2-1.8.9-11.fc34.src.rpm
Repository : fedora
Summary : A spin-adapted implementation of DMRG for ab initio quantum chemistry
URL : https://github.com/SebWouters/CheMPS2
License : GPLv2+
Description : The CheMPS2 library provides a free open-source spin-adapted
: implementation of the density matrix renormalization group (DMRG) for ab initio
: quantum chemistry. This method allows to obtain numerical accuracy in active
: spaces beyond the capabilities of full configuration interaction. For the
: input Hamiltonian and targeted symmetry sector, the library performs successive
: DMRG sweeps according to a user-defined convergence scheme. As output, the
: library returns the minimal encountered energy as well as the 2-RDM of the
: active space. The latter allows to calculate various properties, as well as
: the gradient and Hessian for orbital rotations or nuclear displacements.