Calculations on the rate of the ion–molecule reaction between NH+3 and H2

AH was stud& m a selected-ion dnft tube as a funcfion of gas density and temperature from 2U to 298 K A pressure dependence of the second-order rate coefficient was observed which indicates Hal Lhe reactlon rate is Increased when the intermedlate complexes colhde with a third body. It IS concluded t

Ion-molecule reaction pathways between H-SiNH; and NH3 have been examined by ab initio quantum chemical techniques using polarized split-valence basis sets and including the effects of electron cowelation and zero-point energy corrections. The proton transfer (PT), hydrogen abstraction (HA), electro

Using 2 + 1 multipho ton ionization, NH; is prepared in sclcctcd levels of the "2 bending mode (v = O-7) and the NH:(u) + Da reaction is studied as a function of the center-of-mass collision energy (l-10 eV). The exchange channel (NH2D\*+ HD or H + D) is enhanced by ion vibrational ehcitation wherex

The rate constant for the reaction NHa + OH + NH= + Hz0 was determined by the comparison of the calculated induo tion period data with experiments by the shock tube technique in the range 1360-1840 K, for NHs-Ha-02-\_Ar mixtures\_ The rate constants can be represented by the expression k = 1012-4g'o

A ciasGcaI trajectory analysis has been performed on the ion-molecule reaction Cc+ Hz +CH++ H. The results of the calculation are compared with the results of molecular beam experiments\_