Physik-Department, TUM | LV 0000003665 im SS 2022

Basisdaten

LV-Art

Übung

Umfang

2 SWS

betreuende Organisation

Chemische Physik fern des Gleichgewichts

Dozent(inn)en

Werner Schindler

Termine

13 Termine in Gruppen

Gruppe 1 iCalendar

	Datum und Zeit	Raum und Anmerkung
	Di, 26.04.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 03.05.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 10.05.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 17.05.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 24.05.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 31.05.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 14.06.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 21.06.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 28.06.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 05.07.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 12.07.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 19.07.2022, 11:30–13:00	James-Franck-Str. 1
	Di, 26.07.2022, 11:30–13:00	James-Franck-Str. 1

Zuordnung zu Modulen

PH2197: Photochemische Energieumwandlung und künstliche Photosynthese / Photochemical Energy Conversion Artificial Photosynthesis
Dieses Modul ist in den folgenden Katalogen enthalten:
- Spezifischer Spezialfachkatalog Physik der kondensierten Materie
- Spezifischer Spezialfachkatalog Applied and Engineering Physics
- Komplementärer Spezialfachkatalog Kern-, Teilchen- und Astrophysik
- Komplementärer Spezialfachkatalog Biophysik

weitere Informationen

Lehrveranstaltungen sind neben Prüfungen Bausteine von Modulen. Beachten Sie daher, dass Sie Informationen zu den Lehrinhalten und insbesondere zu Prüfungs- und Studienleistungen in der Regel nur auf Modulebene erhalten können (siehe Abschnitt "Zuordnung zu Modulen" oben).

ergänzende Hinweise	Photochemical Energy Conversion and Artificial PhotosynthesisFor the transition to a renewable energy based energy supply, the greatest challenge is the energy storage to compensate for the daily and yearly variability of wind and solar energy. Owing to their high energy density and temporally unlimited storage capacity, fuels, such as hydrogen, methane or liquid hydrocarbons, present the ideal storage medium.In the lecture we will discuss in-depth state of the art routes to store solar energy directly in form of chemical energy. These routes involve absorption of solar light (mainly by a semiconductor), and accumulation of the minority charge carriers at the semiconductor surface followed by charge transfer of an electron or hole to a chemical species, such as water or carbon dioxide. Artificial pathways to solar fuels will be compared to natural photosynthesis. The lecture will provide foundations of the various areas being necessary to understand the production of fuels from sunlight: semiconductor physics, semiconductor surfaces, the solid-liquid interface, electron transfer theories, experimental techniques, state of the art of water splitting and carbon dioxide reduction.
Links	E-Learning-Kurs (z. B. Moodle) TUMonline-Eintrag TUMonline-Anmeldeverfahren

ergänzende Hinweise

Photochemical Energy Conversion and Artificial PhotosynthesisFor the transition to a renewable energy based energy supply, the greatest challenge is the energy storage to compensate for the daily and yearly variability of wind and solar energy. Owing to their high energy density and temporally unlimited storage capacity, fuels, such as hydrogen, methane or liquid hydrocarbons, present the ideal storage medium.In the lecture we will discuss in-depth state of the art routes to store solar energy directly in form of chemical energy. These routes involve absorption of solar light (mainly by a semiconductor), and accumulation of the minority charge carriers at the semiconductor surface followed by charge transfer of an electron or hole to a chemical species, such as water or carbon dioxide. Artificial pathways to solar fuels will be compared to natural photosynthesis. The lecture will provide foundations of the various areas being necessary to understand the production of fuels from sunlight: semiconductor physics, semiconductor surfaces, the solid-liquid interface, electron transfer theories, experimental techniques, state of the art of water splitting and carbon dioxide reduction.

Links

E-Learning-Kurs (z. B. Moodle)
TUMonline-Eintrag
TUMonline-Anmeldeverfahren

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Semester	Titel	Dozent(en)	Termine
SS 2024	Exercise to Photochemical Energy Conversion and Artificial Photosynthesis	Schindler, W. Mitwirkende: Feil, M.	Di, 11:30–13:00, PH 3734
SS 2023	Exercise to Photochemical Energy Conversion and Artificial Photosynthesis	Schindler, W.	Di, 11:30–13:00, PH 3734
SS 2021	Exercise to Photochemical Energy Conversion and Artificial Photosynthesis	Schindler, W.	Termine in Gruppen
SS 2020	Exercise to Photochemical Energy Conversion and Artificial Photosynthesis	Schindler, W.	Di, 11:30–13:00, virtuell
SS 2019	Exercise to Photochemical Energy Conversion and Artificial Photosynthesis	Schindler, W.	Di, 11:30–13:00, PH 3734
WS 2017/8	Exercise to Photochemical Energy Conversion and Artificial Photosynthesis	Schindler, W.	Termine in Gruppen

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Übung zu Photochemische Energieumwandlung und künstliche Photosynthese
Exercise to Photochemical Energy Conversion and Artificial Photosynthesis

Lehrveranstaltung 0000003665 im SS 2022

Basisdaten

Zuordnung zu Modulen

weitere Informationen

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Übung zu Photochemische Energieumwandlung und künstliche PhotosyntheseExercise to Photochemical Energy Conversion and Artificial Photosynthesis

Lehrveranstaltung 0000003665 im SS 2022

Basisdaten

Zuordnung zu Modulen

weitere Informationen

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Übung zu Photochemische Energieumwandlung und künstliche Photosynthese
Exercise to Photochemical Energy Conversion and Artificial Photosynthesis