In the present study we report neutron spectroscopic measurements on polycrystalline lithium imide, namely, incoherent inelastic neutron scattering at 20 K, and neutron Compton scattering from 10 K up to room temperature. From the former technique the H-projected density of phonon states up to 100 meV is derived, while the latter works out the spherically averaged single-particle (i.e., H, Li, and N) momentum distributions and, from this, the mean kinetic energies. Only for H at the lowest investigated temperature, non-Gaussian components of its momentum distribution are detected. However, these components do not seem directly connected to the system anharmonicity, being fully compatible with the simple N-H bond anisotropy. Neutron data are also complemented by ab initio lattice dynamics simulations, both harmonic and, at room temperature, carried out in the framework of the so-called quantum colored noise thermostat method. The single-particle mean kinetic energies in lithium imide as a function of temperature show a quite peculiar behavior at the moment not reproduced by ab initio lattice dynamics methods, at least as far as H and Li are concerned. As matter of fact, neither their low temperature values nor their temperature trends can be precisely explained in terms of standard phonon calculations. © 2012 American Institute of Physics.
CITATION STYLE
Pietropaolo, A., Colognesi, D., Catti, M., Nale, A. C., Adams, M. A., Ramirez-Cuesta, A. J., & Mayers, J. (2012). Proton vibrational dynamics in lithium imide investigated through incoherent inelastic and Compton neutron scattering. Journal of Chemical Physics, 137(20). https://doi.org/10.1063/1.4767566
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