This package will help you perform a multiple minumum Monte Carlo conformer search as described in Chang et al., 1989. It is built to be used with an ASE calculator and ASE optimization tools but user-defined optimization strategies can be employed as well.
This package can be installed with pip
pip install multiple-minimum-monte-carloTo run a search, you need to initialize Conformer, Calculation, and ConformerEnsemble objects. Conformer objects require either an input xyz or SMILES string. The default Calculation object is ASEOptimization which requires an ASE optimization routine (like FIRE) and an ASE calculator (the example below uses the aimnet calculator which will need to be installed separately from this package). ConformerEnsemble objects require a Conformer and Calculation object.
from ase.optimize.fire import FIRE
from ase.io import write
from aimnet.calculators import AIMNet2ASE
from multiple_minimum_monte_carlo.conformer import Conformer
from multiple_minimum_monte_carlo.calculation import ASEOptimization
from multiple_minimum_monte_carlo.conformer_ensemble import ConformerEnsemble
smiles = "CC(=O)Oc1ccccc1C(=O)O"
conformer = Conformer(smiles=smiles)
optimizer = ASEOptimization(calc=AIMNet2ASE(), optimizer=FIRE)
conformer_ensemble = ConformerEnsemble(conformer=conformer, calc=optimizer)To run the search, call run_monte_carlo with the ConformerEnsemble object
conformer_ensemble.run_monte_carlo()final_ensemble will be a list of coordinate arrays that arranged by their energy (lowest energy first). To read out the minimum energy compound, do this
from ase.io import write
conformer.atoms.set_positions(conformer_ensemble.final_ensemble[0])
write("lowest_energy_conformer.xyz", conformer.atoms, format="xyz")To perform batched calculations (which will perform multiple Monte Carlo steps at once and optimize all of the sampled conformers simultaneously), we will need to use a batched optimizer. In the example below, we will use the torchsim batched calculator with the uma-s-1 MLIP (which both need to be installed separately from this package)
from multiple_minimum_monte_carlo.batch_calculation import TorchSimCalculation
from torch_sim.models.fairchem import FairChemModel
from torch_sim.optimizers import Optimizer
model = FairChemModel(model=None, model_name="uma-s-1",task_name="omol", cpu=True)
calc = TorchSimCalculation(model=model, optimizer=Optimizer.fire, max_cycles=500)
conformer_ensemble = ConformerEnsemble(conformer=conformer, calc=calc)As opposed to batched calculations, you can also do calculations in parallel with a Calculation object by setting parallel=True in the ConformerEnsemble object. However, this requires that the multiprocessing start method "fork" is used which may be incompatible with certain workflows.
When you only include an input xyz structure, this code uses rdkit to construct the SMILES string. However, occassionally this will fail (i.e. when the structure is more ambiguous like a transition state). In this case, including the SMILES string will fix this issue, but the SMILES string needs to be mapped to the structure. The easiest way to do this is to use an atom-mapped SMILES string (the hydrogens also need to be mapped!) and set mapped=True in your Conformer object
To define a Calculation object, a class will need three function: init, run, and energy. init initializes the class with whatever information is necessary. run performs an optimization. It takes an ase.Atoms object and a list of atoms to constrain and returns an np array of cartesian coordinates (in angstroms) and a float with the energy of the conformation (in kcal/mol). energy calculates the energy of a conformer. It takes an ase.Atoms object and returns a float the with energy (in kcal/mol)