Микроструктурированные световоды для генерации перестраиваемых по частоте сверхкоротких лазерных импульсов и элементов волоконно-оптических сенсоров
Современные волоконно-оптические технологии позволяют создавать не только генераторы и преобразователи лазерного излучения, но и средства его доставки до исследуемого объекта, а также волоконно-оптические сенсоры. При этом волоконнооптические сенсоры, основанные на МС волноводах представляют собой новое поколение сенсоров с лучшей чувствительностью и более широким кругом приложений. В ряде задач… Читать ещё >
Содержание
- Глава 1. Микроструктурированные волокна как волоконно-оптические компоненты для нелинейно-оптического преобразования частоты и оптического зондирования
- 1. 1. Микроструктурированные волокна и их классификация
- 1. 2. Основные свойства микроструктурированных волокон со сплошной сердцевиной
- 1. 3. Основные свойства и области применений полых микроструктурированных (фотонно-кристаллических) волокон
- 1. 4. Генерация суперконтинуума в микроструктурированных волокнах
- 1. 5. Солитонный механизм спеткрально-временных преобразований сверхкоротких импульсов в микрострукутруированных волокнах
- 1. 6. Элементы волоконно-оптических сенсоров с использованием микрострукутруированных волноводов
- Глава 2. Экспериментальная техника и методика измерений
- 2. 1. Наносекундный лазерный комплекс для исследования четырехволновых нелинейно-оптических процессов в микроструктурированных волокнах
- 2. 2. Методика измерения спектра пропускания полых фотонно-кристаллических волокон
- 2. 3. Фемтосекундный лазерный генератор на кристалле Сг4+: форстерита
- 2. 4. Многофункциональный лазерный комплекс на основе кристалла Ti: Sapphire
- Глава 3. Четырехволновые нелинейно-оптические взаимодействия и спектроскопические методики на их основе в микроструктурированных волноводах с использованием наносекундных лазерных импульсов
- 3. 1. Когерентное антистоксово рассеяние света в полых ФК волокнах, разделение вкладов в составную нелинейность
- 3. 2. Четырехволновые взаимодействия как способ измерения линейных размеров структуры микроструктурированных волокон
- 3. 3. Четырехволновые параметрические преобразования наносекундных лазерных импульсов и спектроскопия нелинейных свойств субмикронных волноводных каналов
- 3. 4. Оптимизация четырехволновых взаимодействий в высоконелинейных волноводных каналах микроструктурированных волокон для получения широкополосного излучения от наносекундных лазерных импульсов
Глава 4. Волоконно-оптические компоненты на основе микроструктурированных волокон для реализации эффективного источника перестраиваемых сверхкоротких лазерных импульсов и волоконно-оптических сенсоров.
§ 4.1 Формирование перестраиваемых по частоте мегаваттных фемтосекундных импульсов ИК-диапазона на основе генерации многосолитонного суперконтинуума в микроструктурированном световоде.
§ 4.2 Компрессия лазерных импульсов с использованием широкополосного излучения, получаемых из полностью твердотельных фотонно-кристаллических волокон с большой площадью моды.
§ 4.3 Генерация мощных солитонов в микроструктурированных волокнах с увеличенной сердцевиной
§ 4.4 Контроль фазового профиля и интерференция сдвинутых по частоте солитонов в микроструктурированных волокнах.
§ 4.5 Спектральная самокомпрессия сдвинутых по частоте солитонов в МС волокнах.
§ 4.6 Волоконно-оптический сенсор на основе МС волокна для регистрации линейной люминесценции кремниевых наночастиц.
§ 4.7 Волноводный сенсор для регистрации двухфотонной люминесценции. 116
Заключение.
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