Abstract
We review the recent development of chiral sum frequency generation (SFG) spectroscopy and its applications to study chiral vibrational structures at interfaces. This review summarizes observations of chiral SFG signals from various molecular systems and describes the molecular origins of chiral SFG response. It focuses on the chiral vibrational structures of proteins and presents the chiral SFG spectra of proteins at interfaces in the C-H stretch, amide I, and N-H stretch regions. In particular, a combination of chiral amide I and N-H stretches of the peptide backbone provides highly characteristic vibrational signatures, unique to various secondary structures, which demonstrate the capacity of chiral SFG spectroscopy to distinguish protein secondary structures at interfaces. On the basis of these recent developments, we further discuss the advantages of chiral SFG spectroscopy and its potential application in various fields of science and technology. We conclude that chiral SFG spectroscopy can be a new approach to probe chiral vibrational structures of protein at interfaces, providing structural and dynamic information to study in situ and in real time protein structures and dynamics at interfaces.
Highlights
Chirality plays an important role in modern chemistry, biology, and medicine
We conclude that chiral sum frequency generation (SFG) spectroscopy can be a new approach to probe chiral vibrational structures of protein at interfaces, providing structural and dynamic information to study in situ and in real time protein structures and dynamics at interfaces
We summarize the recent development of chiral sum frequency generation (SFG) spectroscopy and its applications to study chiral vibrational structures at interfaces
Summary
Chirality plays an important role in modern chemistry, biology, and medicine. Molecules in biological systems, such as sugars, nucleic acids, and amino acids have inherent chiral centers. Representative nonlinear chiroptical techniques include SHG linear dichroism (SHG-LD) [21,26,27] and SHG circular dichroism (SHG-CD) [27,28,29], nonlinear optical activity (NOA) [30,31], and chiral sum frequency generation (chiral SFG) [32,33,34,35] These studies have revealed that many biomolecules exhibit nonlinear chiroptical activity, leading to various applications in structural analysis [35,36,37,38], material sciences [39,40], and imaging [41,42,43]. The amide I and N-H stretch spectra of peptide backbone show highly characteristic vibrational signatures unique to specific secondary structures These results reveal the capacity of chiral SFG for characterizing protein secondary structures at interfaces. These developments support that chiral SFG spectroscopy can be used to distinguish between secondary structures at interfaces, similar to the use of CD spectroscopy for characterizing protein secondary structures in bulk solution
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