Abstract
Nanodiamond material (∼5 nm diameter diamond particles) has the potential to be used in the design of the next generation of cold neutron sources (CNS). It is hoped that using a blanket layer of this material surrounding the CNS moderator vessel will reflect very cold neutrons back into the moderator, thus reducing radiation leakage through the vessel wall. In this work nanodiamonds produced by two different techniques have been studied, namely those prepared by the detonation method and by the laser ablation of a carbon-hydrocarbon mixture. The analysis of experimental data from USANS, SANS and SAXS measurements suggests that large scale structure such as clustering or aggregation of nanodiamond particles may be determining the scattering. The scattering function S (Q, ω) obtained at 20 K from TOF inelastic neutron scattering measurements shows no low energy states. The generalised density of states (GDOS) of heated and unheated samples at 300 K is consistent with the proposition that thermal treatment eliminates hydrogen in the form of water adsorbed on the nanoparticle surface. Hydrogen bonded to carbon is difficult to remove by thermal treatment.
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