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Published May 7, 2024 | Published
Journal Article Open

Sum rule comparison of narrowband and broadband sum frequency generation spectra and comparison with theory

  • 1. ROR icon California Institute of Technology

Abstract

Earlier sum frequency generation (SFG) experiments involve one infrared and one visible laser, and a measurement of the intensity of the response, yielding data on the surface sensitive properties of the sample. Recently, both the real and imaginary components of the susceptibility were measured in two different sets of experiments. In one set, a broadband infrared laser was used, permitting observations at very short times, while in another set the infrared laser was narrowband, permitting higher spectral resolution. The differences in the spectrum obtained by the two will be most evident in studying narrow absorption bands, e.g., the band due to dangling OH bonds at a water interface. The direct comparisons in the integrated amplitude (sum rule) of the imaginary part of the dangling OH bond region differ by a factor of 3. Due to variations in experimental setup and data processing, corrections were made for the quartz reference, Fresnel factors, and the incident visible laser wavelength. After the corrections, the agreement differs now by the factors of 1.1 within broadband and narrowband groups and the two groups now differ by a factor of 1.5. The 1.5 factor may arise from the extra heating of the more powerful broadband laser system on the water surface. The convolution from the narrowband SFG spectrum to the broadband SFG spectrum is also investigated and it does not affect the sum rule. Theory and narrowband experiments are compared using the sum rule and agree to a factor of 1.3 with no adjustable parameters.

Copyright and License

© 2024 the Author(s). Published by PNAS. This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).

Acknowledgement

We gratefully acknowledge helpful discussions with Professors Y. R. Shen, Chuanshan Tian, T. Tahara, and Dr. Hui Wang. This work was supported by research grants in Tianjin University of Technology and Education Nos. XJKC031432 and XJKC031532, the Tianjin Municipal Education Commission through Grant No. 2017KJ117, the open fund of the state key laboratory of molecular reaction dynamics in DICP, CAS, and at Caltech by the Office of Naval Research and the James W. Glanville Foundation. The computations presented here were conducted on the Caltech High Performance Cluster, partially supported by a grant from the Gordon and Betty Moore Foundation.

Contributions

K.N. and R.A.M. designed research; K.N., H.-f.W., and R.A.M. performed research; K.N., H.-f.W., and R.A.M. analyzed data; and K.N., H.-f.W., and R.A.M. wrote the paper.

Code Availability

The DL_POLY2.0 program was used to calculate the trajectories. All other data are included in the manuscript and/or SI Appendix.

Conflict of Interest

The authors declare no competing interest.

Files

niu-et-al-2024-sum-rule-comparison-of-narrowband-and-broadband-sum-frequency-generation-spectra-and-comparison-with.pdf

Additional details

Created:
May 3, 2024
Modified:
May 13, 2024