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Photoelectron Spectroscopy

Photoelectron Spectroscopy. Lecture 8 – probability of photoionization Cross-sections Gelius model Asymmetry parameters. Ionization is still a transition between states. Initial State: Neutral (or anion)

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Photoelectron Spectroscopy

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  1. Photoelectron Spectroscopy • Lecture 8 – probability of photoionization • Cross-sections • Gelius model • Asymmetry parameters

  2. Ionization is still a transition between states • Initial State: Neutral (or anion) • Final State: Atom/Molecule/Anion after an electron is removed, plus the ejected electron • M → M+ + e- init = M final = M+ + e- • Transition Probability = ∫ init m final d • For direct photoionization, transition probability is always > 0 • Photoionization probability is typically described in terms of a cross-section (much more on this later)

  3. Photoionization Cross-section • The probability per unit area, per unit time that a photon of a given energy can be absorbed by an atom to excite the photoelectrons. • Fictitious area representing the fraction of incoming photons that will be absorbed in the photoionization process. • Unit: barn (10-24 cm2) or megabarn (10-18 cm2) # photons absorbed per unit time cross-section incident photon flux

  4. Partial Photoionization Cross-sections • If more than one orbital level is excited, then the cross-section becomes the summation of partial photoionization cross-sections (PPCS) • PPCSs are a function of the photoelectron’s kinetic energies, and therefore are a function of the incident photon energies. • When PPCS is measured at a specific angle, it is called a differential cross-section, dσ/d, which is related to σnl by an asymmetry parameter, (h) • This specific equation is for a randomly-oriented ensemble of atoms in an unpolarized field.

  5. Calculated atomic orbital ionization cross-sections J.J. Yeh and I. Lindau, At. Data Nucl. Data Tables 1985, 21, 1.

  6. So far we’ve only talked about atoms; what about molecules? Gelius model: cross-section behavior of molecular orbitals is dependent on the atomic orbital character from which the MO is comprised. (Gelius and Siegbahn, Faraday Discuss. Chem. Soc., 1972, 257.)

  7. Variable photon synchrotron studies: Green has collected data on ferrocene at 25 different photon energies from 20-120 eV. Branching Ratios: Ratio of band intensities as a function of photon energy. “Photoionization Cross-Sections: A Guide to Electronic Structure”, J. C. Green and P. Decleva, Coord. Chem. Rev. 2005, 249, 209-228.

  8. Fe Electronic Structure of Ferrocene What is the point group? Looking down the Cp-Fe-Cp vector: Cp’s can lie in two extreme conformations: staggered eclipsed D5h D5d d orbitals transform as: a1’, e1’, e2’ d orbitals transform as: a1g, e1g, e2g We’re going to use these labels

  9. Metallocene Ligand  Group Orbitals a " 2 (Cp)22- (D5d) Cp- (D5h) e " e2g 2 e2u e " 1 e1g e1u a1g a2u

  10. (Cp)22- (Cp)2M M2+ Cp- e1u a2u 4p e2g* (a2u+e1u) e2u a1g e " 4s 2 e2u e2g a1g e1g*  3d e2g e1g (a1g+e1g +e2g) a1g e " 1 e1u e1u e1g a2u a " a2u 2 a1g a1g

  11. Asymmetry Parameters  = 90° $ =2  = 54.73° $ =1 $ =0 $ =-1  = 180°  = 0°

  12. CS2- photoelectron images(Abel inverted) 800 nm 400 nm Photoelectron Imaging

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