Syllabus
Molecular solids, singlet and triplet states, excitons. Energetic ionized states, polarons, Debye theory.
UV-VIS absorption and emission spectra. Polarization of fluorescence.
Photoconductivity. Transfer of excitation energy.
Time-resolved spectroscopy. Transfer of electrical charge.
Conductivity and supraconductivity. Scattering of light.
Photochromism and photochemistry. Principles of molecular electronics.
Molecular photonics. Experimental techniques briefly described through the course, Molecular solids, singlet and triplet states, excitons.
Energetic ionized states, polarons, Debye theory. UV-VIS absorption and emission spectra.
Polarization of fluorescence. Photoconductivity.
Transfer of excitation energy. Time-resolved spectroscopy.
Transfer of electrical charge. Conductivity and supraconductivity.
Scattering of light. Photochromism and photochemistry.
Principles of molecular electronics. Molecular photonics.
Experimental techniques briefly described through the course.
Annotation
Molecular solids, singlet and triplet states, excitons. Energetic ionized states, polarons, Debye theory.
UV-VIS absorption and emission spectra. Polarization of fluorescence.
Photoconductivity. Transfer of excitation energy.
Time-resolved spectroscopy. Transfer of electrical charge.
Conductivity and supraconductivity. Scattering of light.
Photochromism and photochemistry. Principles of molecular electronics.
Molecular photonics. Experimental techniques briefly described through the course, Molecular solids, singlet and triplet states, excitons.
Energetic ionized states, polarons, Debye theory. UV-VIS absorption and emission spectra.
Polarization of fluorescence. Photoconductivity.
Transfer of excitation energy. Time-resolved spectroscopy.
Transfer of electrical charge. Conductivity and supraconductivity.
Scattering of light. Photochromism and photochemistry.
Principles of molecular electronics. Molecular photonics.
Experimental techniques briefly described through the course,