2024-03-28T23:25:02Zhttp://digital.csic.es/dspace-oai/requestoai:digital.csic.es:10261/172652021-05-24T11:57:34Zcom_10261_78com_10261_3col_10261_331
DIGITAL.CSIC
author
Hémono, Nicolas
author
Rocherullé, Jean
author
Floch, Marie le
author
Muñoz, Francisco
2009-09-29T08:48:10Z
2009-09-29T08:48:10Z
2007
Journal of Non-Crystalline Solids 354 (2008) 1822–1827
http://hdl.handle.net/10261/17265
10.1016/j.jnoncrysol.2007.10.014
SnO-containing oxynitride phosphate glasses have been obtained by ammonolysis and their structure studied by nuclear magnetic
resonance. The nitrided glasses are characterized by tetrahedral units P(O,N)4 in which nitrogen atoms have substituted both bridging
and non-bridging oxygen atoms. The N/O substitution in the anionic network induces important changes in the glass properties such as
an increase in the glass transition temperature and a decrease in the coefficient of thermal expansion. 31P MAS NMR shows that PO4,
PO3N and PO2N2 units coexist within the vitreous network and their relative proportions are a function of the nitrogen content as well as
of the base glass composition. The influence of the different modifiers on the nitridation process is explained through a comparative study
of the LiNaSnPON and LiNaPbPON systems. Unlike lead in oxynitride glasses, tin affects the nitridation mechanism by limiting the
nitrogen/oxygen substitution in the anionic network, so that the substitution model is assumed to be closer to the one taking place in
alkali phosphate glasses LiNaPON.
eng
closedAccess
Oxynitride glasses
Nuclear magnetic (and quadrupole) resonance
Phosphates
Stannates
Synthesis and characterization of SnO-containing phosphorous oxynitride glasses
artículo
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