Low Temperature Physics: 33, 569 (2007); https://doi.org/10.1063/1.2755176 (4 pages)
Физика Низких Температур: Том 33, Выпуск 6-7 (Июнь 2007), c. 747-751    ( к оглавлению , назад )

Neon in carbon nanopores: wetting, growth mechanisms and cluster structures

N.V. Krainyukova

B. Verkin Institute for Low Temperature Physics and Engineering of the National Academy of Sciences of Ukraine 47 Lenin Ave., Kharkov 61103, Ukraine
E-mail: ninakrai@yahoo.com
krainyukova@ilt.kharkov.ua

Received October 20, 2006

Аннотация

Low-temperature high-energy (50 keV) electron diffraction study of size-dependent structures and growth mechanisms of neon samples in multiporous «amorphous» carbon films is presented. Electron diffractograms were analyzed on the basis of the assumption that there exists the cluster size distribution in deposits formed in substrate and multi-shell structures such as icosahedra, decahedra, fcc and hcp were probed for different sizes up to approximately 3·104 atoms. The analysis was based on the comparison of precise experimental and calculated diffracted intensities with the help of the R (reliability) — factor minimization procedure. Highly reproducible discrete distribution functions of sizes and structures were found. The time-dependent evolution of diffractograms at earlier stages of growth was revealed. Initially distinct diffraction peaks gradually «disappeared» although the total electron beam absorption evidenced that deposited neon was preserved in the porous substrate. We ascribed this effect to diffusion-like gas penetration from larger to smaller pores which resulted in a highly dispersed or even disordered substance. Evidently, clusters initially grown during deposition were later soaked by a sponge-like substrate due to capillary forces.

PACS: 61.14.–x Electron diffraction and scattering;
PACS: 61.46.–w Nanoscale materials;
PACS: 67.70.+n Films (including physical adsorption);
PACS: 81.05.Rm Porous materials; granular materials;
PACS: 81.05.Uw Carbon, diamond, graphite.

Ключевые слова: carbon nanopores, electron diffraction.