# WATER-TOLUENE (ΔG_toluene - ΔG_water) TRANSFER FREE ENERGY PREDICTIONS # # This file will be automatically parsed. It must contain the following four elements: # predictions, name of method, software listing, and method description. # These elements must be provided in the order shown with their respective headers. # # Any line that begins with a # is considered a comment and will be ignored when parsing. # # # PREDICTION SECTION # # It is mandatory to submit water to octanol (ΔG_octanol - ΔG_water) transfer free energy (TFE) predictions for all 22 molecules. # Incomplete submissions will not be accepted. # The energy units must be in kcal/mol. # Please report the general molecule `ID tag` in the form of `SAMPL9-XX` (e.g. SAMPL9-1, SAMPL9-2, etc). # Please report TFE standard error of the mean (SEM) and TFE model uncertainty. # # The data in each prediction line should be structured as follows: # ID tag, TFE, TFE SEM, TFE model uncertainty # # If you use a microstate other than the challenge provided microstate, please note SMILES strings of microstates you used in your submission, such as in the methods section. # # The list of predictions must begin with the 'Predictions:' keyword as illustrated here. Predictions: SAMPL9-1,4.23,0.01,0.01 SAMPL9-2,4.20,0.01,0.01 SAMPL9-3,6.64,0.01,0.01 SAMPL9-4,8.36,0.01,0.01 SAMPL9-5,6.52,0.01,0.01 SAMPL9-6,-3.86,0.01,0.01 SAMPL9-7,4.23,0.01,0.01 SAMPL9-8,1.06,0.01,0.01 SAMPL9-9,6.84,0.01,0.01 SAMPL9-10,2.20,0.01,0.01 SAMPL9-11,1.21,0.01,0.01 SAMPL9-12,-1.27,0.01,0.01 SAMPL9-13,1.40,0.01,0.01 SAMPL9-14,1.88,0.01,0.01 SAMPL9-15,2.51,0.01,0.01 SAMPL9-16,7.58,0.01,0.01 # # # # Please list your name, using only UTF-8 characters as described above. The "Participant name:" entry is required. Participant name: Prajay Patel # # # Please list your organization/affiliation, using only UTF-8 characters as described above. Participant organization: University of Dallas # # # NAME SECTION # # Please provide an informal but informative name of the method used. # The name must not exceed 40 characters. # The 'Name:' keyword is required as shown here. Name: DLPNO-CCSD(T)/def2-SVP # # # COMPUTE TIME SECTION # # Please provide the average compute time across all of the molecules. # For physical methods, report the GPU and/or CPU compute time in hours. # For empirical methods, report the query time in hours. # Create a new line for each processor type. # The 'Compute time:' keyword is required as shown here. Compute time: CPU compute time - 182 # # COMPUTING AND HARDWARE SECTION # # Please provide details of the computing resources that were used to train models and make predictions. # Please specify compute time for training models and querying separately for empirical prediction methods. # Provide a detailed description of the hardware used to run the simulations. # The 'Computing and hardware:' keyword is required as shown here. Computing and hardware: Dell Precision 5820 Tower Workstation, OS: Windows 11 Pro, RAM: 64.0 GB, CPU: Intel(R) Xeon(R) W-2275 CPU @ 3.30GHz 3.31 GHz, 14 cores # SOFTWARE SECTION # # List all major software packages used and their versions. # Create a new line for each software. # The 'Software:' keyword is required. Software: ORCA 5.0.1 # METHOD CATEGORY SECTION # # State which method category your prediction method is better described as: # `Physical (MM)`, `Physical (QM)`, `Empirical`, or `Mixed`. # Pick only one category label. # The `Category:` keyword is required. Category: Physical (QM) # METHOD DESCRIPTION SECTION # # Methodology and computational details. # Level of details should be roughly equivalent to that used in a publication. # Please include the values of key parameters with units. # Please explain how statistical uncertainties were estimated. # # If you have evaluated additional microstates, please report their SMILES strings and populations of all the microstates in this section. # If you used a microstate other than the challenge provided microstate (`SMXX_micro000`), please list your chosen `Molecule ID` (in the form of `SMXX_extra001`) along with the SMILES string in your methods description. # # Use as many lines of text as you need. # All text following the 'Method:' keyword will be regarded as part of your free text methods description. Method: Structures were optimized at B3LYP/def2-SVP level of theory using 3D structure generated from provided SMILES strings. The structures were optimized in both solvents with the SMD implicit solvation model. The structures were verified to be local minina with no imaginary frequencies. Thermal free energy corrections at 298.15 K were obtained with harmonic frequencies scaled by 1.0044 to account for anharmonicity. DLPNO-CCSD(T)/def2-SVP calculations were performed on the optimized structures. The RIJCOSX approximation and the corresponding auxiliary basis sets (def2/J, def2-SVP/C) were used under TightPNO convergence thresholds. A vertical solvation model was used to compute the logP based on the difference in the solvation free energies of the molecules in toluene and water. Both the standard error of the mean and the model were reported to 0.01 based on submission criteria. In the method for the submission, true error would be 0 since only one QM calculation was completed per challenge molecule. # # # All submissions must either be ranked or non-ranked. # Only one ranked submission per participant is allowed. # Multiple ranked submissions from the same participant will not be judged. # Non-ranked submissions are accepted so we can verify that they were made before the deadline. # The "Ranked:" keyword is required, and expects a Boolean value (True/False) Ranked: False