OSU_05.ppt

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Structures and Spin States of Transition-Metal
Cation Complexes with Aromatic Ligands
Free Electron Laser IRMPD Spectra
Robert C. Dunbar
Case Western Reserve University
Structures and Spin States of Transition-Metal
Cation Complexes with Aromatic Ligands
Free Electron Laser IRMPD Spectra
Robert C. Dunbar
Case Western Reserve University
Coauthors:
David T. Moore, Jos Oomens
FOM Institute for Plasma Physics
John R. Eyler
Univ. of Florida
Gerard Meijer, Gert von Helden
Fritz Haber Institute
Structures and Spin States of Transition-Metal
Cation Complexes with Aromatic Ligands
 Spectroscopy of metal ion complexes
 Cr+ ligand binding sites
 Cr+ spin states (effect of coordination)
 Transition metals with acetophenone
 Rearrangement product ion structure
Infrared Spectroscopy of Molecular Ions
Low densities of ionic molecules due to Coulombic repulsion:
Direct absorption spectroscopy difficult at best
Action spectroscopy, such as IR photodissociation
Infrared multiple photon photodissociation = IRMPD
 Free Electron Laser
High power
Excellent tunability
 Ion storage devices
Trap ions, irradiate for seconds
Free electron laser
•
•Relativistic electron beam in periodic B field
• Wavelength determined by electron energy and B field
• High intensity pulsed output
FELIX – Free Electron Laser for Infrared eXperiments
Tuning range : 40 – 2000 cm-1
Macropulse energy : 100 mJ
Bandwidth : Transform limited
Fourier Transform Ion Cyclotron
Resonance Mass Spectrometer
4.7 T supercon magnet
~10 ppm homogeneity
Open ended ICR cell
Ion sources: EI, ESI, laser vaporization
Laser ablation metal ion source
Vapor phase complex formation
Generate complexes
Mass selective isolation
Irradiate with FELIX
Record MS
Plot fragment yield vs. IR wavelength
Moore, Oomens, van der Meer, von Helden, Meijer, Valle,
Marshall & Eyler, Chem. Phys. Chem. 5, 740 (2004)
Density Functional Calculations of Complexes
Structure, Spin and Spectrum predictions
Choice of functional and basis set
Comparison of different spin states
Empirical scaling of vibrational frequencies
BSSE
Vibrational zero point energies and thermal energies
Binding Site:

Cr+(Aniline)
Choice of Ring (R) or nitrogen (N) binding
sites

Cr+(Acetophenone)
Choice of Ring (R) or carbonyl oxygen (O)
binding sites
Cr+aniline: Ring Bound
B3LYP: N-bound (DE = 7.2 kJ/mol)
MP1PW91: ring-bound (DE = 7.0 kJ/mol)
Oomens, Moore, von Helden, Meijer & Dunbar, JACS 126, 724 (2004)
Cr+(acetophenone)2: Side-chain Bound
Spin State
Cr+ is d5
 High-spin sextet in weak ligand field
 Low-spin doublet in strong ligand field
Cr+(Aniline) High spin
Cr+(Aniline)2 Low spin
Cr+(aniline)2: High or Low Spin ?
(S=5/2)
M+/Acetophenone Binding Modes
Exo
Endo (Chelating)
O-Binding modes
Spectroscopically similar
R Binding
Characteristic spectrum
Spectra of M+(Acet)2
Cr
 Cr and Ni very similar
Fe
 Co distinctly different
 Fe poorly resolved,
not fully interpreted
Co
Ni
400
600
800
1000
1200
cm
-1
1400
1600
1800
2000
Spectra of M+(Acet)2
Cr
O bound
Fe
O bound and
R bound
Side-chain stretch
C=O stretch
Co
Ring umbrella
O bound and
R bound
Ni
O bound
400
600
800
1000
1200
cm
-1
1400
1600
1800
2000
Fits to Calculations
Cr
OO bound
Fe
OR bound
Co
OR bound
Ni
OO bound
400
600
800
1000
1200
cm
-1
1400
1600
1800
2000
Summary: Transition metals with Acetophenone

Ni similar to Cr:
All ligands O bound

Co shows extra peaks:
R bound and O bound ligands.
Good fit to O/R complex (but mixtures possible)
Special affinity of Co+ for benzene ring

Fe spectrum not as good:
Clearly both O bound and R bound ligands
Various possibilities
Characterizing a Rearrangement

Co+ active in bond activation chemistry

Look at the product of the reaction
Co+ + Acet  Co+C7H8 + CO
Spectrum of Co+C7H8 Product Ion
0.40
+
+
Co C7H8 from Co + Acetophenone
0.35
0.30
Co+(Toluene) Calculation
m/z 59 yield
0.25
0.20
0.15
FELIX Spectrum
0.10
0.05
0.00
-0.05
600
800
1000
1200
cm-1
1400
1600
1800
Rearrangement Product

The product ion spectrum fits the expected
Co+(Toluene) spectrum

Other possible product structures don’t fit

Reflects Co+ insertion into a C-C bond,
rearrangement and coupling to form toluene, and
expulsion of CO.
Conclusions
 FEL based IRMPD spectroscopy of trapped ionic species
 Application to transition metal complexes gives valuable new insights
 Structural characterization for ligands with competing binding sites
ring versus side-chain binding gives clear IR fingerprint
 Spin state determination from vibrational spectrum is possible
ring-bound Cr+ bis-complexes are low spin
 Spectra can characterize products of complex rearrangement reactions
Possible Conformations
Spin state: mono vs bis complex
Cr+Anisole mono and bis complexes are ring bound.
Cr+(Anisole)1
high spin
Cr+(Anisole)2
low spin