TY - JOUR
T1 - Reaction of phenoxy radical with nitric oxide
AU - Yu, T.
AU - Mebel, A. M.
AU - Lin, Ming-Chang
PY - 1995/1/1
Y1 - 1995/1/1
N2 - The associationof C6H5O with NO was studied with the cavity‐ring‐down method by directly monitoring the decay of C6H5O in the presence of varying, excess amounts of NO. The biomolecular rate constant determined in the temperature range 297‐373 K can be effectively rate constant determined in the temperature range 297–373 K can be effectively represented by k1 = 10 − 12 · 12 ± 0.24 e (194±185)/r cm3 molecule−1 with a negative activation energy of 0.8 kcal mol−1 (1 kcal = 4.184 kJ). In order to understand better the mechanism of the reaction, ab initio molecular orbital calculations were also carried out at the MP4(SDQ)/6‐31G* level of theory using the HF optimized geometries. The molecular structues and energetics of five C6H5N1O2 isomers were calculated. Among them, the most likely and stable association product, phenyl nitrite (C4H5ONO), was found to be 17 kal mol−1 below the reactants, C6H5O + NO. Combining the measured rate constant and the calculated equilibrium constant for the association reaction, C6H5O + NO = C6H5ONO the rate constant for the unimolecular decomposition of C6H5ONO was obtained as k−1 = 4.6 × 1015E−8580/T s−1. The relatively large frequency factor suggests that a loose transition state was involved in the reaction, akin to those of its alkyl analogs (RONO, R CH3, C2H5, etc.).
AB - The associationof C6H5O with NO was studied with the cavity‐ring‐down method by directly monitoring the decay of C6H5O in the presence of varying, excess amounts of NO. The biomolecular rate constant determined in the temperature range 297‐373 K can be effectively rate constant determined in the temperature range 297–373 K can be effectively represented by k1 = 10 − 12 · 12 ± 0.24 e (194±185)/r cm3 molecule−1 with a negative activation energy of 0.8 kcal mol−1 (1 kcal = 4.184 kJ). In order to understand better the mechanism of the reaction, ab initio molecular orbital calculations were also carried out at the MP4(SDQ)/6‐31G* level of theory using the HF optimized geometries. The molecular structues and energetics of five C6H5N1O2 isomers were calculated. Among them, the most likely and stable association product, phenyl nitrite (C4H5ONO), was found to be 17 kal mol−1 below the reactants, C6H5O + NO. Combining the measured rate constant and the calculated equilibrium constant for the association reaction, C6H5O + NO = C6H5ONO the rate constant for the unimolecular decomposition of C6H5ONO was obtained as k−1 = 4.6 × 1015E−8580/T s−1. The relatively large frequency factor suggests that a loose transition state was involved in the reaction, akin to those of its alkyl analogs (RONO, R CH3, C2H5, etc.).
UR - http://www.scopus.com/inward/record.url?scp=84985482951&partnerID=8YFLogxK
U2 - 10.1002/poc.610080110
DO - 10.1002/poc.610080110
M3 - Article
AN - SCOPUS:84985482951
SN - 0894-3230
VL - 8
SP - 47
EP - 53
JO - Journal of Physical Organic Chemistry
JF - Journal of Physical Organic Chemistry
IS - 1
ER -