Optimize¶
- optimize(name[, func, mode, dertype, molecule])[source]¶
Function to perform a geometry optimization.
Aliases : opt() Returns: (float) Total electronic energy of optimized structure in Hartrees. Psi variables: Note
Analytic gradients area available for all methods in the table below. Optimizations with other methods in the energy table proceed by finite differences.
name calls method scf Hartree–Fock (HF) or density functional theory (DFT) dcft density cumulant functional theory omp2 orbital-optimized second order Moller–Plesset perturbation theory mp2 2nd-order Moller-Plesset perturbation theory (MP2) df-mp2 MP2 with density fitting conv-mp2 conventional MP2 (non-density-fitting) ccsd coupled cluster singles and doubles (CCSD) ccsd(t) CCSD with perturbative triples eom-ccsd equation of motion (EOM) CCSD name calls method b3lyp B3LYP Hybrid-GGA Exchange-Correlation Functional b3lyp-chg B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Chai and Head-Gordon Dispersion Correction b3lyp-d B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Grimme’s -D2 Dispersion Correction b3lyp-d1 B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Grimme’s -D1 Dispersion Correction b3lyp-d3 B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction b3lyp-d3bj B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction b3_x Becke88 GGA Exchange (B3LYP weighting) b88_x Becke88 GGA Exchange b97-0 B97-0 Hybrid-GGA Exchange-Correlation Functional b97-1 B97-1 Hybrid-GGA Exchange-Correlation Functional b97-2 B97-2 Hybrid-GGA Exchange-Correlation Functional b97-d B97-D Pure-GGA Exchange-Correlation Functional w/ Grimme’s -D2 Dispersion Correction b97-d3 B97-D Pure-GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction b97-d3bj B97-D Pure-GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction blyp BLYP GGA Exchange-Correlation Functional blyp-d BLYP GGA Exchange-Correlation Functional w/ Grimme’s -D2 Dispersion Correction blyp-d1 B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Grimme’s -D1 Dispersion Correction blyp-d3 BLYP GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction blyp-d3bj BLYP GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction bp86 BP86 GGA Exchange-Correlation Functional bp86-d BP86 GGA Exchange-Correlation Functional w/ Grimme’s -D2 Dispersion Correction bp86-d1 B3LYP Hybrid-GGA Exchange-Correlation Functional w/ Grimme’s -D1 Dispersion Correction bp86-d3 BP86 GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction bp86-d3bj BP86 GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction ft97 FT97 GGA Exchange-Correlation Functional ft97b_x Filitov and Theil 1997 Exchange ft97_c FT97 Correlation (Involves Ei functions) hcth HCTH Pure-GGA Exchange-Correlation Functional hcth120 HCTH120 Pure-GGA Exchange-Correlation Functional hcth120-d3 HCTH120 Pure-GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction hcth120-d3bj HCTH120 Pure-GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction hcth147 HCTH147 Pure-GGA Exchange-Correlation Functional hcth407 HCTH407 Pure-GGA Exchange-Correlation Functional hf+d w/ Podeszwa and Szalewicz Dispersion Correction lyp_c LYP Correlation m05 Heavily Parameterized Hybrid Meta-GGA XC Functional m05-2x Heavily Parameterized Hybrid Meta-GGA XC Functional m05-2x-d3 Heavily Parameterized Hybrid Meta-GGA XC Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction m05-d3 Heavily Parameterized Hybrid Meta-GGA XC Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction p86_c P86 Correlation (PZ81 LSDA + P86 GGA) pbe PBE GGA Exchange-Correlation Functional pbe-d PBE GGA Exchange-Correlation Functional w/ Grimme’s -D2 Dispersion Correction pbe-d1 PBE GGA Exchange-Correlation Functional w/ Grimme’s -D1 Dispersion Correction pbe-d3 PBE GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction pbe-d3bj PBE GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction pbe0 PBE0 Hybrid GGA Exchange-Correlation Functional pbe0-d PBE0 Hybrid GGA Exchange-Correlation Functional w/ Grimme’s -D2 Dispersion Correction pbe0-d3 PBE0 Hybrid GGA Exchange-Correlation Functional w/ Grimme’s -D3 (zero-damping) Dispersion Correction pbe0-d3bj PBE0 Hybrid GGA Exchange-Correlation Functional w/ Grimme’s -D3 (BJ-damping) Dispersion Correction pbesol_x PBEsol GGA Exchange Hole (Parameter Free) pbe_c PBE Correlation pbe_x PBE GGA Exchange Hole (Parameter Free) pw91 PW91 GGA Exchange-Correlation Functional pw91_c PW91 Correlation pw91_x PW91 Parameterized GGA Exchange pw92_c pz81_c PZ81 Correlation rpbe_x RPBE GGA Exchange Hole (Parameter Free) sogga Second Order GGA Exchange-Correlation Functional sogga_x Second Order GGA Exchange Hole (Parameter Free) svwn SVWN3 (RPA) LSDA Functional s_x Slater LSDA Exchange vwn3rpa_c VWN3 (RPA) LSDA Correlation vwn3_c VWN3 LSDA Correlation vwn5rpa_c VWN5 (RPA) LSDA Correlation vwn5_c VWN5 LSDA Correlation dldf Dispersionless Hybrid Meta-GGA XC Functional dldf+d Dispersionless Hybrid Meta-GGA XC Functional w/ Podeszwa and Szalewicz Dispersion Correction dldf+d09 Dispersionless Hybrid Meta-GGA XC Functional w/ Podeszwa and Szalewicz Dispersion Correction wb88_x B88 Short-Range GGA Exchange (HJS Model) wb97 Parameterized LRC B97 GGA XC Functional wb97x Parameterized Hybrid LRC B97 GGA XC Functional wb97x-d Parameterized Hybrid LRC B97 GGA XC Functional with Dispersion w/ Chai and Head-Gordon Dispersion Correction wblyp BLYP SR-XC Functional (HJS Model) wpbe PBE SR-XC Functional (HJS Model) wpbe0 PBE0 SR-XC Functional (HJS Model) wpbe_x PBE Short-Range GGA Exchange (HJS Model) wpbesol PBEsol SR-XC Functional (HJS Model) wpbesol0 PBEsol0 SR-XC Functional (HJS Model) wpbesol_x PBEsol Short-Range GGA Exchange (HJS Model) wsvwn LSDA SR-XC Functional ws_x Slater Short-Range LSDA Exchange Warning
For the present, file intco.dat is lodged in the submission directory and defines the internal coordinates for an optimization. Thus, it is unsafe to run multiple optimizations from a single directory. Also, intco.dat can linger, so, unless you’ve deliberately constructed it, be sure to clear it out before starting a new optimization.
Warning
Optimizations where the molecule is specified in Z-matrix format with dummy atoms will result in the geometry being converted to a Cartesian representation.
Parameters: - name (string) –
'scf' || 'df-mp2' || 'ci5' || etc.
First argument, usually unlabeled. Indicates the computational method to be applied to the database. May be any valid argument to driver.energy().
- func (function) –
gradient 
|| energy || cbsIndicates the type of calculation to be performed on the molecule. The default dertype accesses``’gradient’`` or 'energy', while 'cbs' performs a multistage finite difference calculation. If a nested series of python functions is intended (see Function Intercalls), use keyword opt_func instead of func.
- mode (string) – 'continuous' || 'sow' || 'reap'
For a finite difference of energies optimization, indicates whether the calculations required to complete the optimization are to be run in one file ('continuous') or are to be farmed out in an embarrassingly parallel fashion ('sow'/'reap'). For the latter, run an initial job with 'sow' and follow instructions in its output file.
- dertype (dertype) –
'gradient' || 'energy'
Indicates whether analytic (if available) or finite difference optimization is to be performed.
- molecule (molecule) –
h2o || etc.
The target molecule, if not the last molecule defined.
Examples : >>> # [1] Analytic scf optimization >>> optimize('scf')
>>> # [2] Finite difference mp3 optimization >>> opt('mp3')
>>> # [3] Forced finite difference ccsd optimization >>> optimize('ccsd', dertype=1)
- name (string) –
For further discussion of geometry optimization, see Sec. Geometry Optimization.