1. Vibrational predissociation spectroscopy of the CO2 reduction intermediate HCO2¯
Helen K. Gerardi1, Andrew F. DeBlase1, Xiaoge Su2, Kenneth D. Jordan2, Anne B. McCoy3, and
Mark A. Johnson1
1Sterling Chemistry Laboratory, Yale University, P.O. Box , New Haven, CT 06520,
2Department of Chemistry, University of Pittsburgh, Pittsburgh, PA 15260,
3Department of Chemistry, The Ohio State University, Columbus, OH 43210
66th International Symposium on Molecular Spectroscopy
The Ohio State University
6/23/2011

2. Conversion of CO2 to Fuels
Products
catalyst
CO2
Introduction | Section 1 | Section 2 | Section 3 | Section 4

3. Reduction of CO2 Yields HCO2¯ Intermediate
Reaction Intermediate h
ZnO2/H2
CO2
Introduction | Section 1 | Section 2 | Section 3 | Section 4
Yoshida and coworkers, J. Chem. Soc., Faraday Trans., 1998
Reaction Intermediate
Innocent et. al, J Appl Electrochem, 2009

4. Brief History of Vibrational Spectra of HCO2¯
Forney, Jacox, Thompson, J. Chem. Phys, 2003
Kidd and Mantsch, Journal of Molecular Spectroscopy, 1981
Na+HCO2¯
HCO2¯
COa
COs
CH
OCOb
Introduction | Section 1 | Section 2 | Section 3 | Section 4
3600
4000
3200
2800
2400
1200
800
400
2000
1600
Wavenumbers (cm-1)
Why is CH so responsive to environment?

5. Experimental Method: Vibrational Predissociation Spectroscopy
Supersonic Expansion
Ar / HCOOH hν
Reflectron Detector
Introduction | Section 1 | Section 2 | Section 3 | Section 4
Mass
Gate
Ion Optics
Reflectron (secondary mass separation)
1 keV Electron Gun

6. Gas-phase Structure of Isolated Formate Ion
HCO2¯ MP2/aug-cc-pVTZ
Calc. Intensity
ωCH
ωCOs
ωCOa
Introduction | Section 1 | Section 2 | Section 3 | Section 4
250 cm-1
HCO2¯
νCOa
Ar Prediss. Yield
νCH
νCOs
800
1000
1200
1400
1600
1800
2000
2200
2400
2600
2800
3000
3200
Photon Energy (cm-1)

7. Gas-phase Structure of Isolated Formate Ion
HCO2¯ MP2/aug-cc-pVTZ
ωCOa
Calc. Intensity
ωCH
~250 cm-1
ωCOs
νCOa
νCOs + νCOa
2νCHb
νCOs
νCH
HCO2¯
Ar Prediss. Yield
Introduction | Section 1 | Section 2 | Section 3 | Summary
DCO2¯ MP2/aug-cc-pVTZ
DCO2¯
Ar Prediss. Yield
Photon Energy (cm-1)
800
1000
1200
1400
1600
1800
2000
2200
2400
2600
2800
3000
3200
ωCD
ωCOs
ωCOa
Calc. Intensity
Photon Energy (cm-1)
800
1000
1200
1400
1600
1800
2000
2200
2400
2600
2800
3000
3200
2νCHb
2νOOP
νCOs + νCOa
νCD
νCOa
νCOs
Botschwina and coworkers, PCCP, 2004

8. Origin of Weaker Features in Formate IR Spectra
νCOa
νCOs
HCO2¯
Fermi
Fermi
Introduction | Section 1 | Section 2 | Section 3 | Summary
Ar Prediss. Yield
DCO2¯
Photon Energy (cm-1)
800
1000
1200
1400
1600
1800
2000
2200
2400
2600
2800
3000
3200

9. Why so low?...Origin of low-frequency C-H stretch
45000
40000 O C H
35000 C O H¯
30000
25000
V(rCH) (cm-1)
Introduction | Section 1 | Section 2 | Section 3 | Summary
20000
15000
θOCO fixed = 130°
θOCO fixed = 180°
10000
5000
RMP2
-5000
0.5
1.0
1.5
2.0
2.5
3.0
3.5
rCH (Å)
*PES scans (RMP2 aug-cc-pVTZ) from Anne B. McCoy– The Ohio State University

10. Dissociation Dynamics
θOCO () 80
100
120
140
160
180
200
rCH (Å)
1.0
1.5
2.0
2.5
3.0
10,000 cm-1
20,000 cm-1
30,000 cm-1
40,000 cm-1
50,000 cm-1
60,000 cm-1 H
+CO 2
HCO
Introduction | Section 1 | Section 2 | Section 3 | Summary
*2D plot from RMP2 calculations by Anne B. McCoy

11. Electrostatic Potentials Depict Charge Migration
rCH
2.5 Å
rCH
1.9 Å
2 Å
1.8 Å
rCH
Introduction | Section 1 | Section 2 | Section 3 | Summary
1.7 Å
1.5 Å
1.6 Å
1 Å

12. Response of C-H stretch frequency with solvationD
HCO2¯·HCOOH
2632
Na+HCO2¯
2553
HCO2¯·H2O
Introduction | Section 1 | Section 2 | Section 3 | Summary
Predissociation Yield
2465
HCO2¯·Ar2
Photon Energy (cm-1)
1200
1400
1600
1800
2000
2200
2400
2600
2800
3000
2449
HCO2¯·Ar

13. Response of C-H stretch frequency with solvation
50000
40000
Na+HCO2¯
30000
V(rCH) (cm-1)
HCO2¯· H2O
Introduction | Section 1 | Section 2 | Section 3 | Summary
20000
relaxed
10000
0.5
1.0
1.5
2.0
2.5
3.0
3.5
rCH (Å)
*PES scans (RMP2 aug-cc-pVTZ) from Anne B. McCoy– The Ohio State University

14. Summary
The vibrational spectrum of isolated HCO2¯ is reported for the first time with both experimental transition energies and intensities
Weaker features are described through Fermi resonances between both CH/D bends (out-of-plane and in-plane) and the CH/D stretch as well as a combination band involving the symmetric and asymmetric CO stretches
The unexpectedly low frequency of the CH stretch in the formate ion is due to preferential dissociation to lower energy asymptote – production of neutral CO2 and hydride (H¯) for isolated formate.
The solvent response of the CH stretching frequency toward higher energy is linked to charge retention on the CO2 component for longer C-H distances.

15. Acknowledgments rCH z Mark A. Johnson Anne B. McCoy Kenneth D. Jordan
Andrew DeBlase
Christopher Leavitt
Rachael Relph
Etienne Garand
Kristin Breen
Mike Kamrath
Arron Wolk
Gary Weddle
I’d like to thank my advisor Mark Johnson and the entire Johnson lab. In particular, Andrew DeBlase who worked closely on this project with me. I also want to thank our theoretical collaborators Anne McCoy and Ken Jordan. And a big thanks of course to the organizations that funded this research.
Anne B. McCoy
Kenneth D. Jordan
Department of Energy
National Science Foundation