2002
Szczygielska, A.; Burian, A.; Dore, J. C.; Duber, S.; Hannon, A.
Paracrystalline nature of saccharose and anthracene-based carbons studied by wide-angle scattering Proceedings
vol. 5136, 2002, ISSN: 0277786X.
@proceedings{2-s2.0-1342311391,
title = {Paracrystalline nature of saccharose and anthracene-based carbons studied by wide-angle scattering},
author = { A. Szczygielska and A. Burian and J.C. Dore and S. Duber and A. Hannon},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-1342311391&partnerID=40&md5=970300bddc87548828bea4499323942b},
issn = {0277786X},
year = {2002},
date = {2002-01-01},
journal = {Proceedings of SPIE - The International Society for Optical Engineering},
volume = {5136},
pages = {288-294},
abstract = {A series of porous carbon materials, produced by pyrolysis of saccharose and anthracene and heat treated at 1000°C, 1800°C and 2600°C has been studied by wide-angle neutron scattering. The neutron data were collected at Rutheford Appleton Laboratory (RAL). The data were recorded in the scattering vector range from 0 to 60 Å-1 which enabled them to be converted to a real-space representation via the Fourier transform. The structure of these carbons has been described in terms of a model based on disordered, graphite-like layers with very weak interlayer correlations. At higher temperatures the anthracene-based carbon transforms into graphite while the carbon produced from saccharose remains disordered. The graphitization process has been studied in detail by careful analysis of the diffraction data in real and reciprocal space.},
keywords = {},
pubstate = {published},
tppubtype = {proceedings}
}
A series of porous carbon materials, produced by pyrolysis of saccharose and anthracene and heat treated at 1000°C, 1800°C and 2600°C has been studied by wide-angle neutron scattering. The neutron data were collected at Rutheford Appleton Laboratory (RAL). The data were recorded in the scattering vector range from 0 to 60 Å-1 which enabled them to be converted to a real-space representation via the Fourier transform. The structure of these carbons has been described in terms of a model based on disordered, graphite-like layers with very weak interlayer correlations. At higher temperatures the anthracene-based carbon transforms into graphite while the carbon produced from saccharose remains disordered. The graphitization process has been studied in detail by careful analysis of the diffraction data in real and reciprocal space.