Chemistry 5325/5326. Angelo R. Rossi Department of Chemistry The University of Connecticut. January 17-24, 2012

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Symmetry and Group Theory for Computational Chemistry Applications Chemistry 5325/5326 Angelo R. Rossi Department of Chemistry The University of Connecticut angelo.rossi@uconn.edu January 17-24, 2012

Infrared Spectra A Fundamental Transition consists of a transition from a molecule in a vibrational ground state (initial vibrational state wave function, ψ i ) to a vibrationally excited state (final vibrational state wave function, ψ f ) where the molecule absorbs one quantum of energy in one vibrational mode. A vibrational transition in the infrared occurs when the molecular dipole moment (µ) interacts with incident radiation which occurs with a probability which is proportional to the transition moment: ψ i µψ f dτ A transition is said to be forbidden in the infrared if the value of this integral is zero because the probability of that transition is zero and no absorption will be observed. The integral will be zero unless the direct product of ψ i µψ f contains the totally symmetric representation which has the character +1 for all symmetry operations for the molecule under consideration. The vector µ can be split into three components, µ x, µ y, and µ z along the Cartesian coordinate axes, and only one of the three integrals needs to be non-zero: ψ i µ x ψ f dτ µ y µ z 2

Infrared Spectra The vibrational ground state wave function, ψ i belongs to the totally symmetric representation. The symmetry properties of the components of the dipole moment (µ x,µ y,µ z ) are the same as those of the translation vectors along the same axes: T x,t y,t z. The symmetry of the vibrationally excited state wave function, ψ f are the same as the symmetry which describes the vibrational mode. Therefore, it is necessary to form direct products of the totally symmetric representation of ground state vibrational wave function (ψ i ), the irreducible representations of each of the translation vectors (T T x,t y,t z ), and the irreducible representation of the excited vibration under consideration. 3

Infrared Spectra Consider the vibrations of the tetrahedal molecule, ruthenium tetroxide (T d symmetry), where there are vibrations of A 1, E, and T 2, and deduce the infrared activity of each of them. 1. ψ i has A 1 symmetry. 2. The character table for T d shows thatt T x,t y,t z together have T 2 symmetry. The direct products are then A 1 vibration: A 1 T 2 A 1 = T 2 E vibration: A 1 T 2 E = T 2 E = T 1 + T 2 T 2 vibration: A 1 T 2 T 2 = T 2 T 2 = A 1 + E + T 1 + T 2 Thus, the T 2 vibrations are infrared active because the direct products produce an A 1 representation, but the E and T 2 vibrations will not appear in the infrared spectrum. An important result of the above analysis is that if an excited vibrational mode has the same symmetry as the translation vectors, T x,t y,t z, for that point group, then the totally symmetric irreducible representation is present and a transition from the vibrational ground state to that excited vibrational mode will be infrared active. 4

Raman Spectra The probability of a vibrational transition occurring in Raman scattering is proportional to: ψ i αψ f dτ where α is the polarizability of the molecule. The Raman effect depends on a molecular dipole induced by the electromagnetic field of the incident rasiation and is proportional to the polarizability of the molecule which is a measure of the ease with which the molecular electron distribution can be distorted. α is a tensor, i.e. a 3 x 3 array of components α x 2 α xy α xz α yx α y 2 α yz α zx α zy α z 2 so there will be six distinct components ψ i α x 2 α y 2 α z 2 ψ α xy f dτ α yz α zx where one non-zero integral is needed to have an allowed Raman transition. 5

Raman Spectra For the ruthenium tetroxide molecule with T d symmetry, the components of polarizability have the following symmetries: A 1 x 2 + y 2 + z 2 E 2z 2 x 2 y 2, x 2 y 2 T 2 xy,yz,zx The vibrations are A 1, E, and T 2, and it is possible to deduce the infrared actavity of each of them. The direct products are then A 1 A 1 E A 1 = A 1, E, T 2 ; A 1 vibration is possible. T 2 A 1 A 1 A 1 E T 2 E = E,(A 1 + A 2 + E),(T 1 + T 2 ); E vibrations are possible. A 1 E T 2 T 2 = T 2,(T 1 + T 2 ),(A 1 + E + T 1 + T 2 ); T 2 vibrations are possible. Thus, all of the vibrations in the RuO 4 molecule are Raman active. A summary of the infrared and Raman activity is given as A 1 : x 2 + y 2 + z 2 Raman Only E: 2z 2 x 2 y 2, x 2 y 2 Raman Only T 2 : (T T x,t y,t z ),(xy,yz,zx) Infrared and Raman Active 6

The Infrared Spectrum of Pd(NH 3 ) 2 Cl 2 One can determine which isomer (cis or trans) is present in a sample from the IR sprectrum by determining the contribution to the spectrum of the Pd-Cl stretching modes for both the cis and trans complexes. The trans isomer exhibits a single Pd-Cl stretching vibration (ν Pd-Cl ) acround 350 cm 1, while the cis isomer exhibits two stretching modes. M-X Vibrations IR Raman trans isomer, D 2h B 2u A u cis isomer, C 2v A 1, B 2 A 1, B 2 Active M-X Stretching Modes for ML 2 X 2 Complexes IR Spectrum of cis and trans Pd(NH 3 ) 2 Cl 2 from Kazauo Nakamoto, Infrared and Raman Spectra of Inorganic and Coordination Compounds, 5 th Edition (1997), Part B, p. 10, Fig. III-5, John Wiley & Sons, New York 7

The Infrared Spectrum of trans Pd(NH 3 ) 2 Cl 2 Determine the contribution of the Pd-Cl stretching modes in the trans complex. D 2h E C 2 (z) C 2 (y) C 2 (x) i σ(xy) σ(xz) σ(yz) P d Cl 2 0 0 2 0 2 2 0 Pd Cl = A g +B 3u IR active modes have the same symmetry as translational vectors (Γ(IR) = B 1u,B 2u.B 3u ) while Raman modes have the same symmetry as binary functions (Γ(Raman) = A g,b 1g,B 2g,B 3g ). Trans Pd(NH 3 ) 2 Cl 2 has a center of symmetry, and the rule of mutual exclusion indicates that no vibrational modes will be present in both the Raman and IR spectra. Thus, there should be one polarized active Raman mode and one active infrared mode Pd Cl = A g(polarized)+b 3u (IR) 8

The Infrared Spectrum of cis Pd(NH 3 ) 2 Cl 2 Determine the contributions to Pd-Cl stretching modes for the cis Pd(NH 3 ) 2 Cl 2 complex. C 2v E C 2 σ(xz) σ (yz) Pd Cl 2 0 0 2 Pd Cl = A 1 +B 2 IR active modes have the same symmetry as translational vectors (Γ(IR) = A 1,B 1.B 2 ) while Raman modes have the same symmetry as binary functions (Γ(Raman) = A 1,A 2,B 1,B 2 ). Two infrared active modes and two Raman active modes, one of which will be polarized are expected. Both modes will be present in both the IR and Raman spectra: Pd Cl = A 1(IR, polarized)+b 2 (IR, depolarized) Summary 1. For the higher symmetry trans Pd(NH 3 ) 2 Cl 2 complex, a single mode Pd-Cl stretching vibration is expected in the IR spectrum, while two Pd-Cl stretching modes are expected in the IR spectrum for the lower symmetry cis Pd(NH 3 ) 2 Cl 2 complex 2. The next step will be to construct and optimize the cis and trans Pd(NH 3 ) 2 Cl 2 complexes, obtain the vibrational modes, and compare the results with the experimental spectrum. 9

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