Please use this identifier to cite or link to this item: http://dspace.iitrpr.ac.in:8080/xmlui/handle/123456789/4131
Title: Investigation of Water Evaporation Process at Air/Water Interface using Hofmeister Ions
Authors: Rana, B.
Fairhurst, D.J.
Jena, K.C.
Keywords: VIS
visible
IR
infrared
HWHM
half width at half maxima
SFG
sum frequency generation
Issue Date: 27-Oct-2022
Abstract: Evaporation is an interfacial phenomenon in which a water molecule breaks the intermolecular hydrogen (H−) bonds and enters the vapor phase. However, a detailed demonstration of the role of interfacial water structure in the evaporation process is still lacking. Here, we purposefully perturb the H-bonding environment at the air/ water interface by introducing kosmotropic (HPO4 −2 , SO4 −2 , and CO3 −2 ) and chaotropic ions (NO3 − and I −) to determine their influence on the evaporation process. Using time-resolved interferometry on aqueous salt droplets, we found that kosmotropes reduce evaporation, whereas chaotropes accelerate the evaporation process, following the Hofmeister series: HPO4 −2 < SO4 −2 < CO3 −2 < Cl− < NO3 − < I −. To extract deeper molecular-level insights into the observed Hofmeister trend in the evaporation rates, we investigated the air/water interface in the presence of ions using surface-specific sum frequency generation (SFG) vibrational spectroscopy. The SFG vibrational spectra reveal the significant impact of ions on the strength of the H-bonding environment and the orientation of free OH oscillators from ∼36.2 to 48.4° at the air/water interface, where both the effects follow the Hofmeister series. It is established that the slow evaporating water molecules experience a strong H-bonding environment with free OH oscillators tilted away from the surface normal in the presence of kosmotropes. In contrast, the fast evaporating water molecules experience a weak H-bonding environment with free OH oscillators tilted toward the surface normal in the presence of chaotropes at the air/water interface. Our experimental outcomes showcase the complex bonding environment of interfacial water molecules and their decisive role in the evaporation process.
URI: http://localhost:8080/xmlui/handle/123456789/4131
Appears in Collections:Year-2022

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