Beyond the Electric Dipole Approximation: Electric and Magnetic Multipole Contributions Reveal Biaxial Water Structure from SFG Spectra at the Air-Water Interface

Abstract: The interpretation of sum-frequency generation (SFG) spectra has been severely limited by the absence of quantitative theoretical predictions for multipole contributions. The previously unknown magnetic dipole and electric quadrupole contributions are determined by the bulk media but appear in all experimental SFG spectra, obscuring the connection between measured spectra and interfacial structure. We present the simulation-based framework that predicts the full set of multipole contributions to the SFG spectrum. This framework also yields depth-resolved spectra, enabling the precise localization of spectroscopic features. Applied to the air-water interface, our approach achieves quantitative agreement with experimental spectra for different polarization combinations in both the bending and stretching regions. Multipole contributions are crucial for correctly interpreting SFG spectra: in the bending band, the electric dipole contribution is of an intensity similar to the magnetic dipole contribution, and both are dominated by the electric quadrupole contribution. In the OH-stretch region, the electric quadrupole contribution is found to be responsible for the mysterious shoulder at 3600 cm$^{-1}$. Crucially, subtracting the multipole contributions isolates the second-order electric dipole susceptibility, which is a quantitative probe for interfacial orientational anisotropy. This electric-dipole susceptibility reveals a pronounced biaxial ordering of water at the air-water interface. By resolving a fundamental limitation of the interpretation of SFG spectroscopy, our framework allows for the detailed extraction of interfacial water ordering from SFG spectra.