Физико-химические аспекты переноса заряда в системе «субстрат — бактериальные клетки Gluconobacter oxydans — медиатор — электрод» в биотопливном элементе
Диссертация
В настоящее время основная часть потребностей в электроэнергии удовлетворяется путем использования невосполнимых природных ресурсов, что влечёт за собой возникновение серьезных экологических проблем. В связи с этим актуальным направлением при поиске и создании альтернативных источников электрической энергии является разработка биотопливных элементов (БТЭ). В основе функционирования этих устройств… Читать ещё >
Содержание
- СПИСОК СОКРАЩЕНИЙ
- ГЛАВА 1. ЛИТЕРАТУРНЫЙ ОБЗОР
- 1. 1. Устройство и принципы функционирования биотопливных элементов
- 1. 1. 1. Конструкция ячейки БТЭ
- 1. 1. 2. Электроды используемые в БТЭ
- 1. 1. 3. Мембраны, используемые в БТЭ
- 1. 1. 4. Схема работы ячейки и перенос заряда в БТЭ
- 1. 2. Биотопливные элементы, основанные на микроорганизмах
- 1. 3. Микробные медиаторные биотопливные элементы
- 1. 3. 1. Взаимодействие медиаторов с микроорганизмами
- 1. 3. 2. Краткая характеристика применяемых медиаторов
- 1. 4. Характеристики БТЭ и факторы, влияющие на работу элемнта
- 1. 5. Модели МБТЭ
- 1. 6. Особенности метаболизма и физиологии Gluconobacter oxydans
- 1. 6. 1. Особенности рода Gluconobacter
- 1. 6. 2. Метаболизм
- 1. 6. 3. Дыхательная цепь Gluconobacter oxydans
- 1. 6. 4. Мембраносвязанные дегидрогеназы Gluconobacter oxydans
- 1. 6. 5. Окисление Сахаров и этанола клетками Gluconobacter oxydans
- 1. 6. 6. Образование глюконата и кетоглюконатов
- 1. 6. 7. Применение Gluconobacter oxydans в биосенсорах
- 1. 6. 8. Биосенсоры на основе целых клеток Gluconobacter oxydans
- 1. 6. 9. Биосенсоры на основе дегидрогеназ
- 1. 1. Устройство и принципы функционирования биотопливных элементов
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