Title | Toward the first study of chemical reaction dynamics of Mu with vibrational-state-selected reactants in the gas phase: The Mu + H-2*(v=1) reaction by stimulated Raman pumping |
Publication Type | Journal Article |
Year of Publication | 2009 |
Authors | Bakule, P, Sukhorukov, O, Matsuda, Y, Pratt, F, Gumplinger, P, Momose, T, Torikai, E, Fleming, DG |
Journal | Physica B-Condensed Matter |
Volume | 404 |
Pagination | 1013-1016 |
Date Published | Apr |
Type of Article | Proceedings Paper |
ISBN Number | 0921-4526 |
Keywords | DYNAMICS, HYDROGEN, Laser setups, muonium, reaction, Stimulated Raman pumping |
Abstract | Stimulated Raman pumping (SRP) is used to produce H-2 in its first vibrational state, in order to measure, for the first time, the Mu + H-2*(v = 1) -> MuH + H reaction rate at room temperature, as a prototypical example of new directions in gas-phase muonium chemistry, utilizing the pulsed muon beam and a new dedicated laser system at the RIKEN/RAL Laboratory. Reported here is a preliminary result but the final results are expected to provide definitive new tests of reaction rate theory on the highly accurate H-3 potential energy surface. The major difficulty in this experiment, compared to the standard SRP process, is to ensure a homogeneous excitation over a volume of several cm(3) and of sufficient intensity to ensure a measurable Mu relaxation rate. The techniques used to accomplish this are described. The experiment utilizes the 2nd harmonic output of a Nd:YAG laser (532 nm) with pulse energies up to 500 mJ at a repetition rate of 25 Hz. Different optical setups have been constructed and tested in order to optimize the number of laser-pumped H-2 molecules and their overlap with the stopping profile of the muon beam in the reaction cell (total volume similar to 100 x 40 x 4 mm(3)). The first result of this experiment gives a measured relaxation rate due to laser excitation of lambda* = 0.085 +/- 0.051 mu s(-1), consistent with theory but limited by both low statistics and particularly a high background relaxation rate. (c) 2009 Elsevier B.V. All rights reserved. |
URL | <Go to ISI>://000265469800122 |