9.5.1 Introduction‣ 9.5 Application of Pressure ‣ Chapter 9 Exploring Potential Energy Surfaces: Searches for Critical Points and Molecular Dynamics ‣ Q-Chem 6.1 User’s Manual

Q-Chem features a number of methods to apply pressure to a chemical system during a geometry optimization or an AIMD simulation. ¹¹⁶⁸ Stauch T.
Int. J. Quantum Chem.
(2021), 121, pp. e26208. Link The following methods are implemented:

Hydrostatic Compression Force Field (HCFF) ¹¹⁶⁵ Stauch T., Chakraborty R., Head-Gordon M. ChemPhysChem (2019), 20, pp. 2742. Link	Section 9.5.2
eXtended Hydrostatic Compression Force Field (X-HCFF) ¹¹⁶⁷ Stauch T. J. Chem. Phys. (2020), 153, pp. 134503. Link	Section 9.5.3
Gaussians On Surface Tesserae Simulate HYdrostatic Pressure (GOSTSHYP) ¹⁰⁸⁷ Scheurer M. et al. J. Chem. Theory Comput. (2021), 17, pp. 583. Link	Section 9.5.4

To invoke one of these methods, set DISTORT = TRUE in the $rem section. By setting the $rem variable scf_final_print = 1, the energy contribution due to pressure is printed in the output.

DISTORT

DISTORT
       Specifies whether to apply pressure or external force to a chemical system
TYPE:
       LOGICAL
DEFAULT:
       False
OPTIONS:
       False Do not use pressure or force True Use pressure or force
RECOMMENDATION:
       Set to true to apply pressure or force.

The parameters of the jobs are set via options specified in the $distort input section. The format of the $distort section is analogous to the $rem section:

$distort
  <Keyword>  <parameter/option>
$end

Note: The following job control variables belong only in the $distort section. Do not place them in the $rem section.

Model
       Specifies which model is used to distort the molecule.
INPUT SECTION: $distort
TYPE:
       STRING
DEFAULT:
       None
OPTIONS:
       HCFF Hydrostatic Compression Force Field ¹¹⁶⁵ Stauch T., Chakraborty R., Head-Gordon M.
ChemPhysChem
(2019), 20, pp. 2742. Link XHCFF eXtended Hydrostatic Compression Force Field ¹¹⁶⁷ Stauch T.
J. Chem. Phys.
(2020), 153, pp. 134503. Link GOSTSHYP Gaussians On Surface Tesserae Simulate HYdrostatic Pressure ¹⁰⁸⁷ Scheurer M. et al.
J. Chem. Theory Comput.
(2021), 17, pp. 583. Link EFEI External Force is Explicitly Included (Section 9.6)
RECOMMENDATION:
       Please refer to the following subsections for recommendations on which model to use.

Pressure
       Specifies the pressure (in MPa) used to compress the molecule.
INPUT SECTION: $distort
TYPE:
       DOUBLE
DEFAULT:
       None
OPTIONS:
       User defined
RECOMMENDATION:
       None

NPoints_Heavy
       Specifies the number of tessellation points per non-hydrogen atom.
INPUT SECTION: $distort
TYPE:
       INTEGER
DEFAULT:
       110
OPTIONS:
       User defined
RECOMMENDATION:
       Use the default.

NPoints_Hydrogen
       Specifies the number of tessellation points per hydrogen atom.
INPUT SECTION: $distort
TYPE:
       INTEGER
DEFAULT:
       110
OPTIONS:
       User defined
RECOMMENDATION:
       Use the default.

Scaling
       Specifies the scaling factor of the atomic van der Waals radii used in the tessellation of the molecular surface, which is used in the pressure models.
INPUT SECTION: $distort
TYPE:
       DOUBLE
DEFAULT:
       1.2
OPTIONS:
       User defined
RECOMMENDATION:
       Increase when modeling a chemical complex to make sure that the complex is placed inside a single cavity. ¹⁰⁸⁷ Scheurer M. et al.
J. Chem. Theory Comput.
(2021), 17, pp. 583. Link A value of 1.0 was suggested to be used in the X-HCFF model. ¹¹⁶⁷ Stauch T.
J. Chem. Phys.
(2020), 153, pp. 134503. Link

Screener
       Enables/disables Integral screening for gostshyp calculations.
INPUT SECTION: $distort
TYPE:
       BOOL
DEFAULT:
       True
OPTIONS:
       True Enable integral screening for gostshyp False Disable integral screening for gostshyp
RECOMMENDATION:
       Use default. Disabling integral screening will lead to much higher memory usage and severe performance drops.

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9.5.1 Introduction