The influence of low-temperature argon matrix on embedded water clusters. A DFT theoretical study

Vasylieva, A.; Doroshenko, I.; Stepanian, S.; Adamowicz, L.

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Author

Vasylieva, A.
Doroshenko, I.
Stepanian, S.
Adamowicz, L.

Affiliation

Department of Chemistry and Biochemistry, University of Arizona

Issue Date

2021

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Publisher

American Institute of Physics Inc.

Citation

Vasylieva, A., Doroshenko, I., Stepanian, S., & Adamowicz, L. (2021). The influence of low-temperature argon matrix on embedded water clusters. A DFT theoretical study. Low Temperature Physics, 47(3), 242-249.

Journal

Low Temperature Physics

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This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.

Abstract

Computer simulations of an argon fcc crystal fragment with embedded water clusters of different sizes are performed using the quantum mechanical DFT/M06-2X method. The effect of the argon matrix on the structural, energy, and spectral parameters of individual water clusters are investigated. The formation energies of (H2O)n@Arm complexes, as well as deformation energies of water clusters and of the argon crystal involved in the embedment, are computed for n = 1-7. Matrix shifts of the IR vibrational frequencies of water clusters isolated in argon matrices are predicted based on the results of the calculations. The predictions indicate a possibility of the formation of small stable water complexes in low-temperature argon matrices. © 2021 Author(s).

Note

12 month embargo; published online: 25 March 2021

ISSN

1063-777X

DOI

10.1063/10.0003525

Version

Final published version

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UA Faculty Publications