Редкоземельные металлы и соединения на их основе востребованы в разработке и производстве функциональных материалов, таких как оптическая керамика, постоянные магниты, люминофоры, катализаторы, стекла, сплавы и др. Уникальные физические и химические свойства данных материалов во многом зависят от элементного состава (панорамного и целевого), который нужно контролировать на всех стадиях производства, от исходных соединений до промежуточных и конечных продуктов. Метод масс-спектрометрии с различными источниками ионизации (индуктивно связанная плазма, вакуумный искровой разряд, тлеющий разряд, лазерный источник, источник вторичных ионов) и системами ввода образца (распыление растворов, лазерный пробоотбор, электротермическое испарение) является одним из перспективных и востребованных при определении целевых элементов в материалах сложного состава с высокой чувствительностью. Есть ряд других преимуществ, которые обеспечивает данный метод, а именно: селективность сигнала определяемых элементов, возможность проведения многоэлементного анализа, точность результатов анализа. Однако материалы сложного состава, в том числе содержащие редкоземельные металлы в качестве основных элементов, требуют изучения влияния условий анализа и других факторов для получения достоверных результатов и разработки методик. В данной статье проведен обзор публикаций, содержащих методические решения и подходы для преодоления ограничений метода масс-спектрометрии с различными источниками ионизации применительно к анализу редкоземельных металлов и функциональных материалов на их основе. Обзор включает в себя российские и зарубежные публикации с 2014 по 2023 года.

Ключевые слова: масс-спектрометрия, редкоземельные металлы, анализ, функциональные материалы, обзор

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