# Pressure effects on the relaxation of an excited nitromethane molecule in an argon bath

## Abstract

Classical molecular dynamics simulations were performed to study the relaxation of nitromethane in an Ar bath (of 1000 atoms) at 300 K and pressures 10, 50, 75, 100, 125, 150, 300, and 400 atm. The molecule was instantaneously excited by statistically distributing 50 kcal/mol among the internal degrees of freedom. At each pressure, 1000 trajectories were integrated for 1000 ps, except for 10 atm, for which the integration time was 5000 ps. The computed ensemble-averaged rotational energy decay is ∼100 times faster than the vibrational energy decay. Both rotational and vibrational decay curves can be satisfactorily fit with the Lendvay-Schatz function, which involves two parameters: one for the initial rate and one for the curvature of the decay curve. The decay curves for all pressures exhibit positive curvature implying the rate slows as the molecule loses energy. The initial rotational relaxation rate is directly proportional to density over the interval of simulated densities, but the initial vibrational relaxation rate decreases with increasing density relative to the extrapolation of the limiting low-pressure proportionality to density. The initial vibrational relaxation rate and curvature are fit as functions of density. For the initial vibrational relaxation rate, the functional form of the fit arisesmore »

- Authors:

- Department of Chemistry, University of Missouri-Columbia, Columbia, Missouri 65211-7600 (United States)
- Argonne National Laboratory, Chemical Sciences and Engineering Division, Argonne, Illinois 60439 (United States)

- Publication Date:

- OSTI Identifier:
- 22415455

- Resource Type:
- Journal Article

- Resource Relation:
- Journal Name: Journal of Chemical Physics; Journal Volume: 142; Journal Issue: 1; Other Information: (c) 2015 AIP Publishing LLC; Country of input: International Atomic Energy Agency (IAEA)

- Country of Publication:
- United States

- Language:
- English

- Subject:
- 37 INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY; ARGON; ATOMS; COMPUTERIZED SIMULATION; CROSS SECTIONS; DEGREES OF FREEDOM; DENSITY; DIAGRAMS; EXTRAPOLATION; MOLECULAR DYNAMICS METHOD; MOLECULES; NITROMETHANE; PRESSURE DEPENDENCE; RELAXATION; TRAJECTORIES

### Citation Formats

```
Rivera-Rivera, Luis A., Sewell, Thomas D., Thompson, Donald L., and Wagner, Albert F.
```*Pressure effects on the relaxation of an excited nitromethane molecule in an argon bath*. United States: N. p., 2015.
Web. doi:10.1063/1.4904314.

```
Rivera-Rivera, Luis A., Sewell, Thomas D., Thompson, Donald L., & Wagner, Albert F.
```*Pressure effects on the relaxation of an excited nitromethane molecule in an argon bath*. United States. doi:10.1063/1.4904314.

```
Rivera-Rivera, Luis A., Sewell, Thomas D., Thompson, Donald L., and Wagner, Albert F. Wed .
"Pressure effects on the relaxation of an excited nitromethane molecule in an argon bath". United States.
doi:10.1063/1.4904314.
```

```
@article{osti_22415455,
```

title = {Pressure effects on the relaxation of an excited nitromethane molecule in an argon bath},

author = {Rivera-Rivera, Luis A. and Sewell, Thomas D. and Thompson, Donald L. and Wagner, Albert F.},

abstractNote = {Classical molecular dynamics simulations were performed to study the relaxation of nitromethane in an Ar bath (of 1000 atoms) at 300 K and pressures 10, 50, 75, 100, 125, 150, 300, and 400 atm. The molecule was instantaneously excited by statistically distributing 50 kcal/mol among the internal degrees of freedom. At each pressure, 1000 trajectories were integrated for 1000 ps, except for 10 atm, for which the integration time was 5000 ps. The computed ensemble-averaged rotational energy decay is ∼100 times faster than the vibrational energy decay. Both rotational and vibrational decay curves can be satisfactorily fit with the Lendvay-Schatz function, which involves two parameters: one for the initial rate and one for the curvature of the decay curve. The decay curves for all pressures exhibit positive curvature implying the rate slows as the molecule loses energy. The initial rotational relaxation rate is directly proportional to density over the interval of simulated densities, but the initial vibrational relaxation rate decreases with increasing density relative to the extrapolation of the limiting low-pressure proportionality to density. The initial vibrational relaxation rate and curvature are fit as functions of density. For the initial vibrational relaxation rate, the functional form of the fit arises from a combinatorial model for the frequency of nitromethane “simultaneously” colliding with multiple Ar atoms. Roll-off of the initial rate from its low-density extrapolation occurs because the cross section for collision events with L Ar atoms increases with L more slowly than L times the cross section for collision events with one Ar atom. The resulting density-dependent functions of the initial rate and curvature represent, reasonably well, all the vibrational decay curves except at the lowest density for which the functions overestimate the rate of decay. The decay over all gas phase densities is predicted by extrapolating the fits to condensed-phase densities.},

doi = {10.1063/1.4904314},

journal = {Journal of Chemical Physics},

number = 1,

volume = 142,

place = {United States},

year = {Wed Jan 07 00:00:00 EST 2015},

month = {Wed Jan 07 00:00:00 EST 2015}

}