Rotationally-Resolved Spectroscopy of the Bending Modes of Deuterated Water Dimer

1. Rotationally-Resolved Spectroscopy of the Bending Modes of Deuterated Water Dimer Jacob T. Stewart and Benjamin J. McCall Department of chemistry, University of Illinois

2. Why water clusters? • Water is ubiquitous on Earth and essential to life • Complicated molecular structure due to hydrogen bonding • Studying small water clusters aids in understanding interactions between water molecules

3. What do we know about water dimer? • (H2O)2 and (D2O)2 extensively studied in microwave and far-IR (rotations and intermolecular modes) • Data used to develop potential energy surfaces • Intramolecular stretches have been measured at high resolution • No rotationally-resolved spectra of bending modes far-IR probes intermolecular vibrations mid-IR probes intramolecular vibrations

4. Previous work on bending modes of water dimer • Gas phase spectra of (H2O)2 observed by cavity ringdown spectroscopy • No rotational resolution, difficult to determine band centers • Could not observe tunneling patterns Paul et al., J. Phys. Chem. A, 103, 2972 (1999).

5. Previous work on bending modes of water dimer • Spectra taken in the Saykally group of a He/D2O expansion • Possible hints of (D2O)2 features • Laser stopped working (damaged mirrors) Huneycutt, PhD thesis, University of California, Berkeley, 2003.

6. Tunneling in water dimer • Three large amplitude motions lead to tunneling between 8 equivalent minima • Splittings caused by tunneling can be observed experimentally Keutsch, F. N., & Saykally, R. J. PNAS, 98 (2001) 10533.

7. Tunneling in water dimer Top half are “2’s” Experimentally determined splittings are a measure of barriers on the potential energy surface Bottom half are “1’s” Keutsch, F. N., & Saykally, R. J. PNAS, 98 (2001) 10533. rigid dimer acceptor switching interchange bifurcation

8. Expected band structure • Either perpendicular (ΔKa = ±1) or parallel bands (ΔKa = 0) • Selection rules only allow 1s ↔ 1s or 2s ↔ 2s • Two sets of bands separated by acceptor switching tunneling • Each set composed of three bands

9. Producing and measuring clusters • Clusters were generated in a continuous supersonic slit expansion (150 µm × 1.6 cm) • Gas was bubbled through D2O at room temperature • Ar at ~250 torr • He at ~900 torr • Used cavity ringdown spectroscopy to obtain spectrum

10. Overview of the spectrum • Arexpansion • Most features also present in He • Studies with D2O/H2O mixtures confirm (D2O)2

11. Identifying (D2O)2 bands Ka = 1 ← 0 band of donor bend R(0) lines confirm assignment Actually three overlapping bands

12. Identifying (D2O)2 bands Ka = 2 ← 1 band of donor bend Lack of R(0) lines confirm assignment Actually three overlapping bands

13. Other component of acceptor switching splitting Ka = 1 ← 0 1’s 2’s 2.4 cm-1

14. Other component of acceptor switching splitting Ka = 2← 1 1’s 2’s 0.9 cm-1

15. Acceptor switching splitting in the excited state • Using previous estimates of Paul et al. for the ground state, we can calculate excited state splitting • For Ka= 1 in excited state, acceptor switching splitting is 19 GHz (17 GHz in ground state) • For Ka= 2 in excited state, acceptor switching splitting is 44 GHz (42 GHz in ground state) • Exciting donor bend has little to no effect on acceptor switching

16. Trying to assign interchange tunneling levels Exciting donor bend perturbs interchange tunneling

17. Band center • Band center can be calculated from assignment • After taking tunneling into account, band center is 1182.2 cm-1 • About 10 cm-1 lower than matrix studies • Close agreement with calculations on ab initio surface

18. Conclusions • Observed first rotationally resolved spectrum of donor bend of water dimer • Found excitation of donor bend has basically no effect on acceptor switching tunneling • Excitation of donor bend appears to perturb the interchange tunneling, making detailed fit difficult • Additional bands should be accessible with more widely tunable laser TJ12, 2015 McPherson, 4:40

19. Acknowledgments • McCall Group • Claire Gmachl • Richard Saykally Springborn Endowment http://bjm.scs.illinois.edu

21. Determining cluster size • Add H2O to sample and observe how lines decrease • Assume statistical ratio of D2O, H2O, and HOD • Cluster size can be determined by a linear relationship Cruzan et al., Science, 271 (1996), 59.

22. Determining cluster size • Our data from cluster of lines near 1195.5 cm-1 • Measured each concentration 10 times Slope = 3.9 ± 0.2 Consistent with dimer