Effect of protonation on the formation of nanocomposition structure in crystals

Abstract

The results on nanocomposition modifying in solutions and melts of salts and acids, as well as structural changes associated with the formation of nanocomposition (NC) structure of materials are presented. The associated protonation is a necessary condition for proton separation of primary structure of nanopolymers (PSN) in NC structure model. The shape and size of PSN in simple substances and compounds and their variation in phase transition have been determined with the use of modified formula of cinematic diffraction theory applied to minimal scattering volumes. A conclusion has been made that high content of interblock protons causes mechanical-chemical splitting in crystals.

Original language	English
Title of host publication	Proceedings of the 6th International Forum on Strategic Technology, IFOST 2011
Pages	218-221
Number of pages	4
Volume	1
DOIs	https://doi.org/10.1109/IFOST.2011.6021007
Publication status	Published - 6 Oct 2011
Event	6th International Forum on Strategic Technology, IFOST 2011 - Harbin, China Duration: 22 Aug 2011 → 24 Aug 2011

Conference

Conference	6th International Forum on Strategic Technology, IFOST 2011
Country	China
City	Harbin
Period	22.8.11 → 24.8.11

Keywords

nanoalloying
nanocomposition structure (NC)
primary structure of nanopolymers (PSN)
proton
protonation

ASJC Scopus subject areas

Management of Technology and Innovation
Strategy and Management

Access to Document

10.1109/IFOST.2011.6021007

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Borodin, Y. (2011). Effect of protonation on the formation of nanocomposition structure in crystals. In Proceedings of the 6th International Forum on Strategic Technology, IFOST 2011 (Vol. 1, pp. 218-221). [6021007] https://doi.org/10.1109/IFOST.2011.6021007

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abstract = "The results on nanocomposition modifying in solutions and melts of salts and acids, as well as structural changes associated with the formation of nanocomposition (NC) structure of materials are presented. The associated protonation is a necessary condition for proton separation of primary structure of nanopolymers (PSN) in NC structure model. The shape and size of PSN in simple substances and compounds and their variation in phase transition have been determined with the use of modified formula of cinematic diffraction theory applied to minimal scattering volumes. A conclusion has been made that high content of interblock protons causes mechanical-chemical splitting in crystals.",

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