В.Г. Шадров – к.ф.-м.н., вед. науч. сотрудник, 

ГНПО «НПЦ НАН Беларуси по материаловедению»

А.Э. Дмитриева – мл. науч. сотрудник, 

ГНПО «НПЦ НАН Беларуси по материаловедению»

А.В. Болтушкин – к.ф.-м.н., вед. науч. сотрудник, 

ГНПО «НПЦ НАН Беларуси по материаловедению»

E-mail: nemtsevich@ifttp.bas-net.by

Постановка проблемы. Технология энергоассистируемой магнитной записи, в основе которой лежит кратковременное уменьшение коэрцитивной силы записывающей среды ниже поля записи за счет локального нагрева (термоассистированная магнитная запись) или прецессии вектора намагниченности под действием микроволнового излучения (микроволновая ассистированная запись), предполагает возможность значительного уменьшения среднего термостабильного размера зерна и увеличения поверхностной плотности магнитной записи существенно выше 1 Тб/дюйм2.

Цель. Провести анализ основных параметров магнитных сред и магнитных головок чтения-записи для энергоассистируемой магнитной записи, используемым материалам, а также альтернативным магнитным материалам и концепциям сред записи.

Результаты. Проанализированы основные параметры магнитных сред и магнитных головок термоассистируемой и микроволновой ассистируемой записи, используемые магнитные материалы, а также альтернативные материалы и концепции сред энергоассистируемой магнитной записи.

Практическая значимость. Рассмотренные технологии позволяют увеличить поверхностную плотность записи до 5 Тб/дюйм2 на основе энергоассистируемой записи, а при использовании комбинации HAMR или MAMR и (бит)структурированных технологий – до 10 Тб/дюйм2 и выше.

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