套件:nwchem-mpich(7.2.3-6)
High-performance computational chemistry software (MPICH build)
NWChem is a computational chemistry program package. It provides methods which are scalable both in their ability to treat large scientific computational chemistry problems efficiently, and in their use of available parallel computing resources from high-performance parallel supercomputers to conventional workstation clusters.
NWChem can handle:
* Molecular electronic structure methods using gaussian basis functions for high-accuracy calculations of molecules * Pseudopotentials plane-wave electronic structure methods for calculating molecules, liquids, crystals, surfaces, semi-conductors or metals * Ab-initio and classical molecular dynamics simulations * Mixed quantum-classical simulations * Parallel scaling to thousands of processors
Features include:
* Molecular electronic structure methods, analytic second derivatives: - Restricted/unrestricted Hartree-Fock (RHF, UHF) - Restricted Density Functional Theory (DFT) using many local, non-local (gradient-corrected) or hybrid (local, non-local, and HF) exchange-correlation potentials * Molecular electronic structure methods, analytic gradients: - Restricted open-shell Hartree-Fock (ROHF) - Unrestricted Density Functional Theory (DFT) - Second-order Moeller-Plesset perturbation theory (MP2), using RHF and UHF reference - MP2 with resolution of the identity approximation (RI-MP2) - Complete active space SCF (CASSCF) - Time-Dependent Density Functional Theory (TDDFT) * Molecular electronic structure methods, single-point energies: - MP2 spin-component scaled approach (SCS-MP2) - Coupled cluster singles and doubles, triples or pertubative triples (CCSD, CCSDT, CCSD(T)), with RHF and UHF reference - Configuration interaction (CISD, CISDT, and CISDTQ) - Second-order approximate coupled-cluster singles doubles (CC2) - State-specific multireference coupled cluster methods (MRCC) (Brillouin-Wigner (BW-MRCC) and Mukherjee (Mk-MRCC) approaches) * Further molecular electronic structure features: - Geometry optimization including transition state searches, constraints and minimum energy paths (via the Nudged Elastic Band (NEB) and Zero Temperature String methods) - Vibrational frequencies - Equation-of-motion (EOM)-CCSD, EOM-CCSDT, EOM-CCSD(T), CC2, Configuration-Interaction singles (CIS), time-dependent HF (TDHF) and TDDFT, for excited states with RHF, UHF, RDFT, or UDFT reference - Solvatisation using the Conductor-like screening model (COSMO) for RHF, ROHF and DFT, including analytical gradients - Hybrid calculations using the two- and three-layer ONIOM method - Relativistic effects via spin-free and spin-orbit one-electron Douglas-Kroll and zeroth-order regular approximations (ZORA) and one-electron spin-orbit effects for DFT via spin-orbit potentials * Pseudopotential plane-wave electronic structure: - Pseudopotential Plane-Wave (PSPW), Projector Augmented Wave (PAW) or band structure methods for calculating molecules, liquids, crystals, surfaces, semi-conductors or metals - Geometry/unit cell optimization including transition state searches - Vibrational frequencies - LDA, PBE96, and PBE0 exchange-correlation potentials (restricted and unrestricted) - SIC, pert-OEP, Hartree-Fock, and hybrid functionals (restricted and unrestricted) - Hamann, Troullier-Martins and Hartwigsen-Goedecker-Hutter norm-conserving pseudopotentials with semicore corrections - Wavefunction, density, electrostatic and Wannier plotting - Band structure and density of states generation * Car-Parrinello ab-initio molecular dynamics (CPMD): - Constant energy and constant temperature dynamics - Verlet algorithm for integration - Geometry constraints in cartesian coordinates * Classical molecular dynamics (MD): - Single configuration energy evaluation - Energy minimization - Molecular dynamics simulation - Free energy simulation (multistep thermodynamic perturbation (MSTP) or multiconfiguration thermodynamic integration (MCTI) methods with options of single and/or dual topologies, double wide sampling, and separation- shifted scaling) - Force fields providing effective pair potentials, first order polarization, self consistent polarization, smooth particle mesh Ewald (SPME), periodic boundary conditions and SHAKE constraints * Mixed quantum-classical: - Mixed quantum-mechanics and molecular-mechanics (QM/MM) minimizations and molecular dynamics simulations - Quantum molecular dynamics simulation by using any of the quantum mechanical methods capable of returning gradients.
This package provides nwchem built with MPICH. It is expected to run nwchem successfully over multiple nodes. If you need to compute large molecules using cluster computation, then this package might be a better choice than nwchem-openmpi.
其他與 nwchem-mpich 有關的套件
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- dep: libblas3
- Basic Linear Algebra Reference implementations, shared library
- 或者 libblas.so.3
- 本虛擬套件由這些套件填實: libatlas3-base, libblas3, libblis4-openmp, libblis4-pthread, libblis4-serial, libopenblas0-openmp, libopenblas0-pthread, libopenblas0-serial
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- dep: libc6 (>= 2.38)
- GNU C 函式庫:共用函式庫
同時作為一個虛擬套件由這些套件填實: libc6-udeb
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- dep: libgcc-s1 (>= 4.0)
- GCC 支援函式庫
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- dep: libgfortran5 (>= 10)
- Runtime library for GNU Fortran applications
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- dep: liblapack3
- Library of linear algebra routines 3 - shared version
- 或者 liblapack.so.3
- 本虛擬套件由這些套件填實: libatlas3-base, liblapack3, libopenblas0-openmp, libopenblas0-pthread, libopenblas0-serial
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- dep: libmpich12 (>= 4.2)
- Shared libraries for MPICH
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- dep: libpython3.12t64 (>= 3.12.7)
- Shared Python runtime library (version 3.12)
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- dep: libscalapack-mpich2.2 (>= 2.2.1)
- Scalable Linear Algebra Package - Shared libs for MPICH
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- dep: mpich
- Implementation of the MPI Message Passing Interface standard
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- dep: nwchem-data (= 7.2.3-6)
- High-performance computational chemistry software (data files)