Серия «Металлургия»

Рассмотрены методы синтеза наноматериалов с применением поверхностно-активных веществ. Приведен краткий анализ и классификация ПАВ. Одним из методов является синтез нанопористых трехмерно упорядоченных оксидных, халькогенидных или металлических наноматериалов в структуре лиотропных жидких кристаллов, формирующихся в высококонцентрированных водных растворах ПАВ. Отмечена пионерская работа 1992 г. по созданию первого мезопористого силикатного материала, послужившая инициатором широкой волны исследований в этой области. Другим методом является использование обратных мицелл ПАВ в углеводородных средах, что позволяет проводить реакции в объеме микрокапель растворов реагирующих компонентов и тем самым уменьшать размер образующихся наночастиц. Для целенаправленного использования ПАВ необходимо знание двойных и тройных диаграмм состояния вода – ПАВ и вода – масло – ПАВ, которые строятся согласно классическим представлениям физической химии о равновесии в двух- и многокомпонентных системах. В обзоре приведены наиболее подробно охарактеризованные двойные и тройные диаграммы состояния, имеющие значение для матричного синтеза. Обсуждены методы исследования диаграмм состояния. Затронуты также близко родственные системы на основе блок-сополимеров, ряд которых также может быть рассмотрен как высокомолекулярные ПАВ. Отдельно рассмотрены оксидные и оксигидроксидные наноматериалы, включающие соединения Si, Al, Ti, Zr, Hf, Nb, Ta, Mn, W, Sn, Ce и смешанных материалов, с матрицей из SiO2, на которую нанесено некоторое количество оксида другого металла: Al, V, Cr, Fe, Zr, Mo, Ni, либо металлические частицы катализаторов: Ag, Pt или Pd, полученные с применением ПАВ в процессе осаждения неорганической фазы. Приведены примеры наиболее упорядоченных мезопористых наноматериалов, образующих трехмерно периодические структуры с открытой пористостью. Предложены пути дальнейшего развития метода матричного синтеза наноматериалов с использованием ПАВ.

поверхностно-активные вещества; наноматериалы; матричный синтез

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