EPR Evidence of Liquid Water in Ice: An Intrinsic Property of Water or a Self-Confinement Effect?

Thangswamy, Muthulakshmi; Maheshwari, P.; Dutta, Dhanadeep; Rane, Vinayak; Pujari, P. K.

doi:10.1021/acs.jpca.8b03605

Cited by 4 publications

(9 citation statements)

References 36 publications

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“…32 The freeze concentrated solution (FCS) threading the ice crystals creates a specific and hitherto not fully described medium whose behavior is of utmost importance in various fields, including geological, atmospheric, life, and pharmaceutical sciences. To date, FCSs have been examined via microscopy [33][34][35][36] and also characterized spectroscopically [37][38][39][40] and calorimetrically, [41][42][43] applying numerous systems at various temperatures within diverse fields. The FCS was found to behave distinctly from the impurities deposited from the gaseous phase.…”

Section: Introductionmentioning

confidence: 99%

Vitrification and increase of basicity in between ice Ih crystals in rapidly frozen dilute NaCl aqueous solutions

Imrichová

Veselý

Gasser

et al. 2019

The Journal of Chemical Physics

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The freezing of ionic aqueous solutions is common in both nature and human-conducted cryopreservation. The cooling rate and the dimensions constraining the solution are known to fundamentally influence the physicochemical characteristics of the sample, including the extent of vitrification, morphology, and distribution of ions. The presence of some salts in an aqueous solution often suppresses the ice crystallization, allowing bulk vitrification during relatively slow cooling. Such a process, however, does not occur in NaCl solutions, previously observed to vitrify only under hyperquenching and/or in sub-micrometric confinements. This work demonstrates that, at freezing rates of ≥100 K min −1 , crystallized ice I h expels the freeze-concentrated solution onto the surfaces of the crystals, forming lamellae and veins to produce glass, besides eutectic crystallization. The vitrification covers (6.8% ± 0.6%) and (17.9% ± 1.5%) of the total eutectic content in 0.06M and 3.4 mM solutions, respectively. The vitrified solution shows a glass-to-liquid transition succeeded by cold crystallization of NaCl ⋅ 2H 2 O during heating via differential scanning calorimetry. We establish that ice crystallization is accompanied by increased basicity in freeze-concentrated solutions, reflecting preferential incorporation of chloride anions over sodium cations into the ice. After the sample is heated above the glass transition temperature, the acidity gradually returns towards the original value. The morphology of the samples is visualized with an environmental scanning electron microscope. Generally, the method of vitrifying the freeze-concentrated solution in between the ice I h crystals via fast cooling can be considered a facile route towards information on vitrified solutions.

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Section: Introductionmentioning

confidence: 99%

Vitrification and increase of basicity in between ice Ih crystals in rapidly frozen dilute NaCl aqueous solutions

Imrichová

Veselý

Gasser

et al. 2019

The Journal of Chemical Physics

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“…For pristine ice, atomistic simulations indicate that the mobility of water molecules in such layers is significantly lower than in bulk supercooled liquid water at the same temperature, displaying subdiffusive behavior on time scales of ∼100 ns. , Similar behavior has also been observed at ice/clay nanocomposite interfaces . This enhanced sluggishness has been linked to the confined nature of these quasi-liquid regions, with the restraining presence of adjacent crystal grains restricting molecular motion. ,− However, whether or not this sluggishness is affected when sodium chloride is dissolved is an open question and it is directly related to, for instance, mass transport along the GB regions and mechanical deformation mechanisms based on grain sliding processes.…”

Section: Introductionmentioning

confidence: 95%

Effect of Sodium Chloride on Internal Quasi-Liquid Layers in Ice I_h

2021

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We consider the effect of sodium chloride on the properties of internal interfaces in ice I h . For this purpose, we employ molecular dynamics simulations to investigate the role of sodium and chloride ions in the properties of grain boundaries (GB), which are the interfacial regions separating adjacent crystal grains with different orientations. The results show that the presence of the ions significantly affects both the structural and dynamical characteristics of the disordered layers at the GB regions. Compared to pristine ice samples, in addition to reducing the degree of water structure, the ions enhance the mobility of the water molecules in the GB region. Even so, the briny GB regions display quasi-liquid behavior in that both the molecular and the ionic diffusivities are substantially lower than in the corresponding bulk liquid solutions at the same conditions of temperature, pressure, and salinity. Finally, the presence of sodium chloride in the GB regions is found to facilitate the GB sliding process, which is consistent with experimental insight.

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“…Recently, we observed a novel type of confinement in the electron paramagnetic resonance (EPR) studies of very dilute frozen aqueous solutions of a paramagnetic solute molecule, TEMPO, where the frozen solvent matrix itself acts as a confining medium for the unfrozen solution. 5 Importantly, no external porous medium is needed to confine the solution. The origin of self-confinement lies in an important aspect of the bulk BP diagram, which is that the size of the liquid domains (LDs) that coexist with the frozen solvent is predicted to depend on the initial concentration of the solute (Supporting Information, Figure S1).…”

Section: ■ Introductionmentioning

confidence: 99%

“…9 A home written program, using the programming language C, was used, details of which can be found elsewhere. 5 The computer program also allows for axially symmetric rotational diffusion along with isotropic rotational motion. Different rotational models were considered, such as Brownian, jump, and free diffusion.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Thus, confinement of solutions in foreign porous materials is of limited applicability here. Recently, we observed a novel type of confinement in the electron paramagnetic resonance (EPR) studies of very dilute frozen aqueous solutions of a paramagnetic solute molecule, TEMPO, where the frozen solvent matrix itself acts as a confining medium for the unfrozen solution . Importantly, no external porous medium is needed to confine the solution.…”

Section: Introductionmentioning

confidence: 99%

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Does a Binary Phase Diagram Exist for a Solvent Containing a Single Solute Molecule? Case of a Neutral Solute Molecule in Ethanol

et al. 2019

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Binary phase (BP) diagrams have been a cornerstone in both the industrial and the academic research. Traditionally, the twocomponent BP diagrams always consider a finite amount of solute in a finite solvent host. Here, we consider a special situation: a single solute molecule in a structurally different solvent host and pose the question "Can the traditional BP diagram account for the behavior of a single solute in a finite solvent host?" To date, this aspect remains unexplored because of both practical difficulties in probing such dilute solutions and conceptual difficulties in formulating a BP diagram for such a single solute molecule case. In this work, we have overcome the experimental barrier and produced such a system in ethanolic solutions of a neutral solute molecule by exploiting the ethanol's property of crystallization from a translationally rigid plastic crystalline state. We studied the freezing behavior of dilute solutions of nitroxyl spin probes, 2,2,6,6-tetramethylpiperidin-1-oxyl (TEMPO), 4-hydroxy-TEMPO, 4-oxo-TEMPO, and 4-amino-TEMPO, in ethanol by electron paramagnetic resonance (EPR) spectroscopy. Computer simulations based on Stochastic Liouville theory were used to analyze the EPR spectra. The EPR results reveal that liquid domains (LDs) containing a single solute molecule are formed in ethanol ice and are subjected to strong confinement because of its own frozen solvent phase. No evidence of crystallization of these LDs is observed at any temperature. The observed behavior cannot be rationalized by the bulk BP diagram but could be understood by a self-confined BP diagram, where the freezing point curve is not bounded at lower temperatures. Interestingly, the size of the LD was estimated to be 2.0 nm, which is similar to the lower limit for crystallizing water.

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EPR Evidence of Liquid Water in Ice: An Intrinsic Property of Water or a Self-Confinement Effect?

Cited by 4 publications

References 36 publications

Vitrification and increase of basicity in between ice Ih crystals in rapidly frozen dilute NaCl aqueous solutions

Vitrification and increase of basicity in between ice Ih crystals in rapidly frozen dilute NaCl aqueous solutions

Effect of Sodium Chloride on Internal Quasi-Liquid Layers in Ice I_h

Does a Binary Phase Diagram Exist for a Solvent Containing a Single Solute Molecule? Case of a Neutral Solute Molecule in Ethanol

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EPR Evidence of Liquid Water in Ice: An Intrinsic Property of Water or a Self-Confinement Effect?

Cited by 4 publications

References 36 publications

Vitrification and increase of basicity in between ice Ih crystals in rapidly frozen dilute NaCl aqueous solutions

Vitrification and increase of basicity in between ice Ih crystals in rapidly frozen dilute NaCl aqueous solutions

Effect of Sodium Chloride on Internal Quasi-Liquid Layers in Ice Ih

Does a Binary Phase Diagram Exist for a Solvent Containing a Single Solute Molecule? Case of a Neutral Solute Molecule in Ethanol

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Effect of Sodium Chloride on Internal Quasi-Liquid Layers in Ice I_h