8. Electronic Spectroscopy. Vibrational spectroscopy refers to changes in vibrational energy levels. Electronic spectroscopy refers to the photon energy absorbed or emitted by a molecule from electron transitions between different possible electronic states. On the diagram below, Draw arrows to illustrate the processes, and Label with the letters shown in bold. a) Franck-Condon principle for electronic excitation (F-C), from vibrational ground state v = 0. Collisional Relaxation in the excited states without photon emission (CR) b) Return to the ground state via Fluorescence (F) Intersystem Crossing (ISC) d) Return to the ground state via Phosphorescence (P) f) InfraRed absorbance of one quantum of vibrational energy from v = 0 in the ground state (IR) g) Raman scattering that allows transition from v = 0 to v = 1, in the ground state (RAMAN) h) On the x-axis, indicate the hond longthor
8. Electronic Spectroscopy. Vibrational spectroscopy refers to changes in vibrational energy levels. Electronic spectroscopy refers to the photon energy absorbed or emitted by a molecule from electron transitions between different possible electronic states. On the diagram below, Draw arrows to illustrate the processes, and Label with the letters shown in bold. a) Franck-Condon principle for electronic excitation (F-C), from vibrational ground state v = 0. Collisional Relaxation in the excited states without photon emission (CR) b) Return to the ground state via Fluorescence (F) Intersystem Crossing (ISC) d) Return to the ground state via Phosphorescence (P) f) InfraRed absorbance of one quantum of vibrational energy from v = 0 in the ground state (IR) g) Raman scattering that allows transition from v = 0 to v = 1, in the ground state (RAMAN) h) On the x-axis, indicate the hond longthor
8. Electronic Spectroscopy. Vibrational spectroscopy refers to changes in vibrational energy levels. Electronic spectroscopy refers to the photon energy absorbed or emitted by a molecule from electron transitions between different possible electronic states. On the diagram below, Draw arrows to illustrate the processes, and Label with the letters shown in bold. a) Franck-Condon principle for electronic excitation (F-C), from vibrational ground state v = 0. Collisional Relaxation in the excited states without photon emission (CR) b) Return to the ground state via Fluorescence (F) Intersystem Crossing (ISC) d) Return to the ground state via Phosphorescence (P) f) InfraRed absorbance of one quantum of vibrational energy from v = 0 in the ground state (IR) g) Raman scattering that allows transition from v = 0 to v = 1, in the ground state (RAMAN) h) On the x-axis, indicate the hond longthor
answer EACH PART very clearly please dont make it confusing, this is chem 2600, physical chemistry course!!!! please draw it seperately clearly!!
fast answer .
Transcribed Image Text:8. Electronic Spectroscopy. Vibrational spectroscopy refers to changes in vibrational energy levels. Electronic
spectroscopy refers to the photon energy absorbed or emitted by a molecule from electron transitions between
different possible electronic states.
On the diagram below, Draw arrows to illustrate the processes, and Label with the letters shown in bold.
a) Franck-Condon principle for electronic excitation (F-C), from vibrational ground state v = 0.
b) Collisional Relaxation in the excited states without photon emission (CR)
c)
Return to the ground state via Fluorescence (F)
Intersystem Crossing (ISC)
Return to the ground state via Phosphorescence (P)
Infra Red absorbance of one quantum of vibrational energy from v = 0 in the ground state (IR)
Raman scattering that allows transition from v = 0 to v = 1, in the ground state (RAMAN)
On the x-axis, indicate the bond lengths re and ro for the ground electronic state only.
Draw an arrow to show the magnitude of the Zero Point Energy (ZPE)
Briefly state why ZPE exists.
d)
e)
f)
g)
h)
i)
j)
Ground Electronic state
Singlet state
Triplet state
Branch of chemistry that studies how atoms, molecules, and materials interact with each other. Physical chemistry focuses on the behavior of matter, such as solids, liquids, and gases, as they interact with other matter. The study of physical chemistry is crucial to thermodynamics, quantum mechanics, and photochemistry.
Expert Solution
This question has been solved!
Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, chemistry and related others by exploring similar questions and additional content below.
