1 / 30

Physical Chemistry 2 nd Edition

Chapter 25 Electronic Spectroscopy. Physical Chemistry 2 nd Edition. Thomas Engel, Philip Reid. Objectives. Understanding of electronic transitions. Outline. The Energy of Electronic Transitions Molecular Term Symbols

deana
Download Presentation

Physical Chemistry 2 nd Edition

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 25 Electronic Spectroscopy Physical Chemistry 2nd Edition Thomas Engel, Philip Reid

  2. Objectives • Understanding of electronic transitions

  3. Outline • The Energy of Electronic Transitions • Molecular Term Symbols • Transitions between Electronic States of Diatomic Molecules • The Vibrational Fine Structure of Electronic Transitions in Diatomic Molecules • UV-Visible Light Absorption in Polyatomic Molecules • Transitions among the Ground and Excited States • Singlet–Singlet Transitions: Absorption and Fluorescence

  4. Outline • Intersystem Crossing and Phosphorescence • Fluorescence Spectroscopy and Analytical Chemistry • Ultraviolet Photoelectron Spectroscopy • Single Molecule Spectroscopy • Fluorescent Resonance Energy Trasfer (Fret) • Linear and Circular Dichroism

  5. 25.1 The Energy of Electronic Transitions • Electronic excitations are responsible for giving color to the objects we observe. • UV-visible spectroscopy provides a very useful qualitative tool for identifying molecules and determine energy levels in molecules.

  6. 25.2 Molecular Term Symbols • In electronic excitations, molecular term describe the electronic states of molecules. • L and S (MLand MS) is chosen to be the z axis, and S are to specify individual states in diatomic molecules. where mli, mls = z components of orbital and spin angular momentum for the i th electron in its molecular orbital.

  7. Example 25.1 What is the molecular term symbol for the H2 molecule in its ground state? In its first two excited states?

  8. Example 25.1 In the ground state, the H2 molecule is described by the (1σg)2configuration. For both electrons, ml=0. Therefore, Λ=0, and we are dealing with a Σterm. Because of the Pauli principle, one electron has ms=+1/2 and the other has ms=-1/2. Therefore, MS=0 and it follows that S=0. It remains to be determined whether the MO has g or u symmetry. Each term in the antisymmetrized MO is of the form σg x σg. Recall that the products of two even or odd functions is even, and the product of an odd and an even function is odd.

  9. Example 25.1 Therefore, the product of two g (or two u) functions is a g function, and the ground state of the H2 molecule is 1Σg In the first excited state, the configuration is (1σg)(1σu), and because theelectrons are in separate MOs, this configuration leads to both singlet states and triplet states. Again, because ml=0 for both electrons, we are dealingwith a Σterm.

  10. Example 25.1 Because the two electrons are in different MOs, for each electron, giving msvalues of -1, 0 (twice), and +1. This is consistent with S=1 and S=0. Because the product of a u and a g function is a u function, both singlet and triplet states are u functions. Therefore, the first two excited states are described by the terms 3Σuand 1Σu. Using Hund’s first rule, we conclude that the triplet state is lower in energy than the singlet state.

  11. 25.3 Transitions Between Electronic States of Diatomic Molecules • Diatomic molecules have spacing between the various rotational-vibrational-electronic states which is large to allow individual states to be resolved. • Each of the molecular bound states of O2 has well-defined vibrational and rotational energy levels.

  12. 25.4 The Vibrational Fine Structure of Electronic Transitions in Diatomic Molecules • Vibrational and rotational quantum numbers can change during electronic excitation. • Born-Oppenheimer approximation can beused todetermine vibrational transition between electronic states. where R1,…,Rm depends on position of the nuclei r1,…rn depends on the position of electrons

  13. 25.4 The Vibrational Fine Structure of Electronic Transitions in Diatomic Molecules • Franck-Condon principle states that transitions between electronic states correspond to vertical lines on an energy versus inter-nuclear distance diagram. • Electronic transitions occur on a timescale that is very short compared to the vibrational period of a molecule

  14. 25.5 UV-Visible Light Absorption in Polyatomic Molecules • Rotational and vibrational transitions are possible if an electronic transition occurs in polyatomic molecules. • The concept of chromophores is useful for electronic spectroscopy of polyatomic molecules. • A chromophore is a chemical entity embedded within a molecule that absorbs radiation at the same wavelength in different molecules.

  15. 25.5 UV-Visible Light Absorption in Polyatomic Molecules • The intensity of absorption for (a) an atom, (b) a diatomic molecule, and (c) a polyatomic molecule.

  16. 25.5 UV-Visible Light Absorption in Polyatomic Molecules • The energy difference between the initial and final states determines the frequency of the spectral line. • The energy increases in the sequence nπ*, π π*, and σσ*.

  17. 25.6 Transitions among the Ground and Excited States • There are possible transitions among the ground and excited electronic states.

  18. 25.6 Transitions among the Ground and Excited States The 2 types of transitions are: • Radiative transitions - photon is absorbed/emitted • Nonradiative transitions - energy transferred between molecule to the surroundings

  19. 25.7 Singlet–Singlet Transitions: Absorption and Fluorescence • Beer’s law is used to quantify what is meant by strong and weak absorption. where I0 = incident light intensity at frequency of interest It = intensity of transmitted lightc = concentrationl = path lengthε = strength of the transition (molar extinction coefficient)

  20. 25.7 Singlet–Singlet Transitions: Absorption and Fluorescence • Integral absorption coefficient is a measure ofthe probability that an incident photon will be absorbed in a specific electronic transition.

  21. 25.8 Intersystem Crossing and Phosphorescence • Probability of intersystem crossing transitions is enhanced by two factors: similar molecular geometry in the excited singlet and triplet states. • Fluorescence spectroscopy is good for detecting chemical species if wavelength of the emission lies in the visible-UV where there is little noise near room temperature.

  22. 25.9 Fluorescence Spectroscopy and Analytical Chemistry • The goal of the human genome is to determine the four bases, A, C, T, and G, in DNA that encode all the genetic information. • Laser-induced fluorescence spectroscopy consist of3 parts: • DNA cut into small pieces, replicate many copies, and put into A, C, T and G mixture to modified the bases. • Lengths of the partial replicas measured using capillary electrophoresis

  23. 25.9 Fluorescence Spectroscopy and Analytical Chemistry • Measure the time for each of thepartial replicas spent in capillary, to determines lengthand terminating base.

  24. 25.10 Ultraviolet Photoelectron Spectroscopy • Spectroscopy gives information on the energy difference between initial and final states, but not transition energy level. • UV photoelectron spectroscopyis to identify the orbital energy level from which an electronictransition originates.

  25. 25.10 Ultraviolet Photoelectron Spectroscopy • The kinetic energy of ejected electronis the total energy required to form the positive ion via photoionization, by where Ef= energy of the cation

  26. 25.10 Ultraviolet Photoelectron Spectroscopy • Koopmans’ theorem states the 3 assumptions for Ef equal to εorbital : • Nuclear positions are unchanged in the transition (Born-Oppenheimerapproximation). • Orbitals for the atom and ion are the same (frozen orbital approximation). • Total electron correlation energy in the molecule and ion are the same.

  27. 25.11 Single Molecule Spectroscopy • The “true” absorption band for an individual molecule is observed only if the number of molecules in the volume being sampled is very small • Conformation of a biomolecule is the arrangement of its constituent atoms in space • Primary structure is determined by the backbone of the molecule • Tertiary structure refers to the overall shape of the molecule

  28. 25.11 Single Molecule Spectroscopy

  29. 25.12 Fluroscent Resonance Energy Transfer (FRET) • FRET is a form of single molecule spectroscopy that has proved to be very useful in studying biochemical systems • Resonance energy transfer is where the emission spectrum of the donor overlaps the absorption spectrum of the acceptor • Theodor Förster states that

  30. 25.13 Linear and Circular Dichroism • Transition dipole moment is defined by • The arrows in successive images indicate the direction of the electric field vector as a function of time or distance • In linear dichroism spectroscopy, the variation of the absorbance with the orientation of plane-polarized light is measured

More Related