Vestnik of the Far East Branch of the Russian Academy of Sciences

Вестник Дальневосточного отделения Российской академии наук

0869-7698

The Russian Academy of Sciences

677452

10.31857/S0869769824060125

HRBLEV

Chemical sciences. Advanced inorganic materials

Химические науки. Перспективные неорганические материалы

Review Article

New glasses in the MNbOF₅-BaF₂-InF₃ (M–Mn, Cd, Zn) systems

Новые стекла в системах MNbOF₅-BaF₂-InF₃ (M–Mn, Cd, Zn)

Ignatieva

L. N.

Игнатьева

Л. Н.

Russian Federation

Doctor of Sciences in Chemistry, Chief Researcher

доктор химических наук, главный научный сотрудник

ignatieva@ich.dvo.ru

Savchenko

N. N.

Савченко

Н. Н.

Russian Federation

Researcher

научный сотрудник

savchenko@ich.dvo.ru

https://orcid.org/0000-0002-0494-9948

Marchenko

Yu. V.

Марченко

Ю. В.

Russian Federation

Candidate of Sciences in Chemistry, Senior Researcher

кандидат химических наук, старший научный сотрудник

gor_dvo@mail.ru

Mashchenko

V. А.

Мащенко

В. А.

Russian Federation

Researcher

научный сотрудник

mashchenko@ich.dvo.ru

Sarin

S. A.

Сарин

С. А.

Russian Federation

Researcher

научный сотрудник

sarin@ich.dvo.ru

Institute of Chemistry, FEB RASИнститут химии ДВО РАН

05122024

18720220032025

2024

Russian Academy of Sciences

Российская академия наук

https://journals.eco-vector.com/0869-7698/article/view/677452

The article summarizes the results of studying new glasses in the MnNbOF₅-BaF₂-InF₃, ZnNbOF₅-BaF₂-InF₃ and CdNbOF₅-BaF₂-InF₃ systems. The thermal characteristics of glasses were studied, the role of fluorindate and fluoroniobate components in glass formation and crystallization behavior was revealed. Glasses in the MNbOF₅-BaF₂-InF₃ systems can be considered three-component; their structure is formed by polyhedra of fluoroniobate (NbO₂F₄ and NbO₃F₃), InF₆ and polyhedra formed by MF_n. The possibility of obtaining glass ceramics has been demonstrated. For glasses in the CdNbOF₅-BaF₂-InF₃ and ZnNbOF₅-BaF₂-InF₃ systems, the photoluminescence was detected corresponding to emission levels of 542, 573 and 673, 751 nm, depending on the presence and concentration of indium trifluoride in the glass. Luminescent properties are shown only by glasses in which nanoparticles, 9–13 nm, were detected according to SAXS data.

В статье обобщены результаты исследования новых стекол в системах MnNbOF₅-BaF₂-InF₃, ZnNbOF₅-BaF₂-InF₃иCdNbOF₅-BaF₂-InF₃. Изучены термические характеристики стекол, выявлена роль фториндатных и фторниобатных компонентов в стеклообразовании и кристаллизационном поведении. Стекла в системах MNbOF₅-BaF₂-InF₃ (M = Mn, Zn, Cd) можно считать трехкомпонентными, их структуру формируют полиэдры NbO₂F₄ и NbO₃F₃, InF₆ и полиэдры, формируемые MF_n. Показана возможность получения стеклокерамик. Для стекол в системах CdNbOF₅-BaF₂-InF₃ и ZnNbOF₅-BaF₂-InF₃ зафиксирована фотолюминесценция, соответствующая уровням эмиссии 542, 573 и 673, 751 нм, зависящая от присутствия и концентрации в стекле трифторида индия. Люминесцентные свойства показывают только стекла, в которых по данным МУРР обнаружены наноразмерные включения, 9–13 нм.

glassesstructurecrystallizationluminescenceglass ceramics

стекластруктуракристаллизациялюминесценциястеклокерамика

Российский научный фонд

Russian Science Foundation

24-13-00133

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