Ion effect on the dynamics of water hydrogen bonding network: A theoretical and computational spectroscopy point of view

Molecular Insights into Anion-Specific Freezing Point Depression in Lithium Salt Solutions

The depression of freezing points in electrolyte aqueous solutions, a well-known colligative property, is traditionally attributed to entropy increases arising from ion-induced disruption of the hydrogen-bonding networks. However, the microscopic mechanisms governing this phenomenon remain poorly understood, particularly at concentrated salt concentrations where ion-specific effects emerge. In this study, we combined Raman spectroscopy, molecular dynamics (MD) simulations, and density functional theory (DFT) calculations to investigate the hydrogen-bonding structures of water in lithium salt solutions containing typical anions. MD simulations reveal that diffusion barriers of water are influenced by the anion identity, while DFT calculations indicate that anions with lower surface electrostatic potentials weaken the disruption of the hydrogen-bonding network caused by the cation. By systematically evaluating five lithium salts─LiClO4, LiNO3, LiBF4, LiCl, and LiTFSI─we show that freezing point depression in lithium salt solutions arises from a complex interplay of anion-water, cation-anion, and cation-water interactions. Notably, the freezing point trends deviate from the Hofmeister series, suggesting the critical role of ion-pairing and aggregate formation in determining solution behavior. Our results further indicate that rather than the intrinsic structure─disrupting ability of Hofmeister anions, the mobility of water molecules within the ions' hydration shells is a primary determinant of freezing behavior, challenging the conventional view and revealing the critical influence of local water dynamics on solid/liquid transitions. These findings provide molecular-level insights into the ion-specific effects governing freezing point depression in electrolyte solutions, with implications for lithium-ion battery electrolytes and other concentrated ionic systems.

Comparative Bindings of Glycosaminoglycans with CXCL8 Monomer and Dimer: Insights from Conformational Dynamics and Kinetics of Hydrogen Bonds

GAGs bind to both the monomeric and dimeric forms of CXCL8, helping to form a concentration gradient of the chemokine that facilitates the recruitment of neutrophils to an injury site and supports other biological functions. In this study, atomistic molecular dynamics simulations were conducted to investigate the binding behavior of two hexameric GAGs sulfated at two different positions, chondroitin sulfate (CS) and heparan sulfate (HS), with the monomer (SIL8) and dimer (DIL8) forms of the CXCL8 protein. The results support that the conformational diversity of CS and HS appeared to be more when binding with monomer SIL8 than dimer DIL8. CS gained more configurational entropy from glycosidic linkage flexibility when bound to SIL8 than DIL8, with a higher energy barrier, whereas HS exhibited a lower energy barrier for configurational entropy when bound to SIL8 and DIL8. The monomer SIL8 exhibited more favorable and preferential binding with GAGs compared to DIL8. Formation of hydrogen bonds with the basic amino acids of SIL8 and GAG was more rigid and required higher activation energy to break than the other identified hydrogen bondings. Water molecules involved in hydrogen bonding with GAGs, excluding those with basic amino acids of DIL8, showed longer lifetimes and slower relaxation compared to SIL8. This suggests that water-mediated interactions also favor binding of DIL8 with GAGs. Despite having more basic amino acids, DIL8 did not display stronger binding than SIL8, indicating the significant role of basic residues in stabilizing the GAG-protein interactions in the monomers. The reason could be that the greater number of nonbasic amino acids in dimeric CXCL8 stabilizes the complex by forming water-mediated hydrogen bonds, reducing the conformational preferences for binding with GAGs. In contrast, the monomeric form of CXCL8 exhibits a higher conformational preference for protein-GAG interactions.

Effects of Hydrogen Bond Networks on Viscosity in Aqueous Solutions

In aqueous solutions, the impact of ions on hydrogen bond networks plays a crucial role in transport properties. We used molecular dynamics simulations to explain how ions affect viscosity through structural changes. We developed a quantitative model to describe the effect of ions on viscosity. The model comprises two parts: the addition of ions alters hydrogen bond networks, and changes in hydrogen bond networks exponentially lead to changes in viscosity. The influence of ions on hydrogen bond networks involves the following mechanisms: first, ions can disrupt the tetrahedral structures within the first solvation shell into three-coordinated structures through substitution; second, structural changes within the first shells affect the global hydrogen bond network through electrostatic forces and the hindrance of ionic volumes. By analyzing the mechanisms of how hydrogen bond networks determine viscosity through the decomposition of viscosity, we found that the proportion of potential viscosity in aqueous solutions primarily increases due to the enhancement of non-hydrogen bonding interactions, and the proportion of hydrogen bonding viscosity decreases accordingly. Our results demonstrate that hydrogen bond networks are crucial for describing the changes in transport phenomena affected by external factors.

Terahertz spectroscopy of thick and diluted water solutions

While bright terahertz sources are used to perform nonlinear experiments, they can be advantageous for high-precision linear measurements of opaque samples. By placing the sample away from the focus, nonlinearities can be suppressed, and sizeable amounts of transmitted radiation detected. Here, this approach is demonstrated for a 0.5 mm thick layer of liquid water in a static sample holder. Variations of the index of refraction as small as (7 ± 2) · 10-4 were detected at 0.58 THz for an aqueous salt solution containing ten millimoles of sodium chloride. To my knowledge, this precision is unprecedented in time-domain spectroscopy studies of diluted aqueous systems or other optically thick and opaque materials.

Liposomes and Lipid Droplets Display a Reversal of Charge-Induced Hydration Asymmetry

The unique properties of water are critical for life. Water molecules have been reported to hydrate cations and anions asymmetrically in bulk water, being a key element in the balance of biochemical interactions. We show here that this behavior extends to charged lipid nanoscale interfaces. Charge hydration asymmetry was investigated by using nonlinear light scattering methods on lipid nanodroplets and liposomes. Nanodroplets covered with negatively charged lipids induce strong water ordering, while droplets covered with positively charged lipids induce negligible water ordering. Surprisingly, this charge-induced hydration asymmetry is reversed around liposomes. This opposite behavior in charge hydration asymmetry is caused by a delicate balance of electrostatic and hydrogen-bonding interactions. These findings highlight the importance of not only the charge state but also the specific distribution of neutral and charged lipids in cellular membranes.

Water does not dance as ions sing: A new approach in elucidation of ion-invariant water fluctuations

Aqueous solutions of salts composed from monovalent ions are explored using temperature-dependent FT-IR spectroscopy in transmission. Water combination band, being extremely sensitive to the network of hydrogen bonds due to the contribution of water librations (ρ_LH₂O), is analyzed in uni- and multivariate fashion. Univariate analysis of the combination band maximum (ν_max) reveals that perturbation of water hydrogen bond network by ions is primary driven by electrostatic interactions between water and ions. Using multivariate curve resolution with alternating least squares and evolving factor analysis this band is separated into two components that represent low- and high-density water. The observed asymmetry in their behavior is interpreted in terms of fluctuations of a hydrogen bond network of two water components. The significance of the found phenomenon is unambiguously confirmed by performing analogous analysis in the spectral range that contains partial signature of water linear bending (δHOH) and is free from ρ_LH₂O, in which the asymmetry is absent. Additionally, we show that this phenomenon, namely ion-invariant behavior of water fluctuations, persists even in the regime of high ionic strengths. Although ions indeed participate in shaping of water hydrogen bond network, this straightforward approach shows that its temperature-dependent fluctuations are ion-independent.

Molecular Mechanism of Water Reorientation Dynamics in Dimethyl Sulfoxide Aqueous Mixtures

Nonmonotonic composition dependence is often observed for numerous properties in the aqueous mixtures of small amphiphilic molecules. The molecular picture underlying this structure-activity relationship, however, remains largely elusive. We herein studied water reorientation dynamics in the aqueous mixture of dimethyl sulfoxide (DMSO), which has a significant nonmonotonic composition dependence, using molecular dynamic simulation and an extended molecular jump model. The analysis indicates that this nonideal behavior is driven by the collective frame diffusion component of water reorientation, which decelerates in the water-rich regime because of the strengthened hydrogen bonds and accelerates in the water-poor regime as the hydrogen bonding network is broken into smaller aggregates. The current work therefore connects the microheterogeneity in the solvation structure of DMSO-water with its nonmonotonic hydration dynamics and sheds new light on how microsegregation leads to the multiscale hydration nonideality in general.

Trimethylamine N-oxide (TMAO) resists the compression of water structure by magnesium perchlorate: terrestrial kosmotrope vs. Martian chaotrope

Neutron diffraction and computational modelling provide insight into water structure.

Ion-Specific Effects on Hydrogen Bond Network at a Submicropore Confined Liquid-Vacuum Interface: An in Situ Liquid ToF-SIMS Study

The hydrogen bond (HB), one of the essential properties of water, tends to link water molecules to form dynamic water clusters. Extrinsic ions could change the size distribution of water clusters by influencing HBs. But the mechanism, especially the influence range of ions on HBs, is still in dispute due to limitation of analytical methods. Herein, we use in situ liquid ToF-SIMS analysis combined with density functional theory calculation to study the influence of different halide anions on HBs at a submicropore confined liquid-vacuum interface. Our experimental results demonstrated that anions show synchronous local and long-range effects on HBs. Specifically, the larger the anion is, the greater degree the long-range HB network and the local hydration number of anions are influenced. More importantly, we found that the long-range effect on the HB network is influenced by nuclear quantum effects, whereas the local effect on water molecules in the first hydration shell is not.