Disentangling the molecular polarizability and first hyperpolarizability of methanol-air interfaces

Liquid-air interfaces have extensive implications in different areas of interest because the dynamical processes at the interface can be different from those in bulk. Thus, its characterization, understanding, and control may be pivotal in advancing discoveries. However, characterizing the interface...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2024-03, Vol.26 (11), p.8658-8669
Main Authors: Ramos, Tárcius N, Champagne, Benoît
Format: Article
Language:English
Subjects:
Anisotropy
Interfaces
Methanol
Molecular dynamics
Quantum chemistry
Second harmonic generation
Tensors
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Summary:Liquid-air interfaces have extensive implications in different areas of interest because the dynamical processes at the interface can be different from those in bulk. Thus, its characterization, understanding, and control may be pivotal in advancing discoveries. However, characterizing the interface requires special and selective tools to avoid signals from the bulk region. This surface specificity and versatility is achieved by using the second harmonic generation (SHG) responses. This study adopts multiscale simulation methods to evaluate the surface SHG responses of methanol-air interfaces with submonolayer resolution tackled by sequentially using classical molecular dynamics simulations under different temperatures and then employing quantum chemistry methods to compute the molecular first hyperpolarizabilities ( β ). This approach ensures the configurational diversity required to evaluate the average β values. The main achievements are (i) a quasi-absence of surface sensitivity of the mean polarizability 〈 α 〉 with values about 2% larger than those obtained in bulk, (ii) conversely, smooth variations on the polarizability anisotropy Δ α are observed up to the fourth molecular layer at around 20 Å from the interface, and (iii) narrow interfacial effects on the SHG responses, β (−2 ω ; ω , ω ), which are limited to the first molecular layer (∼3.0 Å) and characterized by a high contrast in the β ZZZ (−2 ω ; ω , ω ) tensor component between the first and the subsequent layers. Similar trends are obtained at different temperatures or when increasing the number of methanol molecules treated at the quantum chemistry level, indicating the robustness of the approach for describing the dipolar molecular responses of air-liquid interfaces. Modeling the interfacial selective first hyperpolarizability at methanol-air interfaces was successfully achieved using the sequential molecular dynamics and quantum chemistry approach.
ISSN:1463-9076
1463-9084
DOI:10.1039/d4cp00043a