Abstract

Collisional relaxation of internally excited high-mass (>1 kDa) ions has been simulated under typical quadrupole ion trap storage conditions. Two models have been employed that are expected to bracket the range of cooling rates that prevail for such ions present in ∼1 mTorr of room temperature helium. A diffuse scattering model that assumes that the helium target atom thermally equilibrates with the high-mass ion upon collision is expected to yield a maximum cooling rate. A random walk algorithm using the exponential model for inefficient colliders and a relatively small average energy down-step size provides an estimate for the lowest cooling rates that might be expected. The two models give cooling rates that differ by about a factor of three and fall within the range of 200–2000 s −1 for the ions and energies considered in the simulations. Unimolecular dissociation rates have also been determined for the same model ions. Random walk simulations employing collisional cooling and dissociation clearly show how a rapid input of internal energy, as with the absorption of an ultraviolet photon, can either result in dissociation of a large fraction of the ions or can lead to an insignificant degree of dissociation, depending largely on the unimolecular dissociation rate of the ion.

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