S. Parthiban et Tj. Lee, Theoretical study of XONO2 (X=Br, OBr, O2Br): Implications for stratospheric bromine chemistry, J CHEM PHYS, 113(1), 2000, pp. 145-152
The equilibrium structure, dipole moment, harmonic vibrational frequencies,
and infrared intensities of XONO2 (X=Br, OBr, O2Br) are determined using d
ensity functional theory in conjunction with a TZ2P (triple zeta double pol
arized) basis set. The B3LYP functional was used since this has previously
been shown to perform well for similar bromine compounds. The equilibrium g
eometry and vibrational spectra of BrONO2 are shown to be in good agreement
with the experimental data and also with high-level coupled-cluster calcul
ations. The vibrational spectrum of O2BrONO2 has been compared with that of
the chlorine analog, O2ClONO2, for which some experimental data exist. The
bonding in OBrONO2 is shown to be more similar to that in BrONO2. Using la
rge atomic natural orbital basis sets, the singles and doubles coupled-clus
ter method that includes a perturbative correction for triple excitations,
denoted CCSD(T), was employed to compute energies for three isodesmic react
ions in order to determine heats of formation for OBrONO2 and O2BrONO2. Our
best estimates are 36.7 and 38.7 kcal/mol, respectively. Finally, the poss
ible formation of O2BrONO2 in the stratosphere by adduct formation and oxid
ation of OBrONO2 and the implications for stratospheric bromine chemistry a
re discussed. (C) 2000 American Institute of Physics. [S0021-9606(00)30125-
8].