Structure and dynamics of water in nanoscopic spheres and tubes

Loop, Tibert H. van der; Ottosson, Niklas; Lotze, Stephan; Kentzinger, Emmanuel; Vad, Thomas; Sager, W.F.C.; Bakker, Huib J.; Woutersen, Sander

doi:10.1063/1.4898380

Cited by 15 publications

(14 citation statements)

References 63 publications

(110 reference statements)

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“…It may be noted that the DRS and transient-IR experiments both probe water reorientation dynamics, but the observed relaxation behavior is generally different, because DRS probes the (first-order) orientational correlation function of the total electric-dipole moment of all the water molecules, whereas transient IR probes the (second-order) orientational correlation function of spatially well separated OH (or OD) groups (the spatial separation being due to the isotopic dilution) 46 . Rotation of a hydrogen-bond donating water molecule around the hydrogen-bonded OH group does not change the direction of the OH vector (and hence does not contribute to the OH-stretch anisotropy decay), but does rotate the electric-dipole moment (and hence does contribute to the dielectric relaxation); as a consequence, a fraction of solvating water molecules can cause a residual offset in the anisotropy, and an overall slowdown of the dielectric relaxation 47,48 . An additional difference between the two experiments is that DRS probes the collective motion of all the water molecules, and hence is more sensitive to collective water dynamics 47,48 .…”

Section: Resultsmentioning

confidence: 99%

On the origin of the extremely different solubilities of polyethers in water

et al. 2019

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The solubilities of polyethers are surprisingly counter-intuitive. The best-known example is the difference between polyethylene glycol ([–CH 2 –CH 2 –O–] n ) which is infinitely soluble, and polyoxymethylene ([–CH 2 –O–] n ) which is completely insoluble in water, exactly the opposite of what one expects from the C/O ratios of these molecules. Similar anomalies exist for oligomeric and cyclic polyethers. To solve this apparent mystery, we use femtosecond vibrational and GHz dielectric spectroscopy with complementary ab initio calculations and molecular dynamics simulations. We find that the dynamics of water molecules solvating polyethers is fundamentally different depending on their C/O composition. The ab initio calculations and simulations show that this is not because of steric effects (as is commonly believed), but because the partial charge on the O atoms depends on the number of C atoms by which they are separated. Our results thus show that inductive effects can have a major impact on aqueous solubilities.

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Section: Resultsmentioning

confidence: 99%

On the origin of the extremely different solubilities of polyethers in water

et al. 2019

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“…Additional spectra of the cells and cytosol mimics in 100% H 2 O were recorded for background subtraction. Polarization-resolved infrared pump-probe experiments were done using a setup described previously 74 . Pump-beam scattering by the samples was eliminated by delaying every second pump pulse by half an optical cycle using a photo-elastic modulator and averaging the signals at these two pump-probe delays 82 .…”

Section: Methodsmentioning

confidence: 99%

Picosecond orientational dynamics of water in living cells

et al. 2017

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Cells are extremely crowded, and a central question in biology is how this affects the intracellular water. Here, we use ultrafast vibrational spectroscopy and dielectric-relaxation spectroscopy to observe the random orientational motion of water molecules inside living cells of three prototypical organisms: Escherichia coli, Saccharomyces cerevisiae (yeast), and spores of Bacillus subtilis. In all three organisms, most of the intracellular water exhibits the same random orientational motion as neat water (characteristic time constants ~9 and ~2 ps for the first-order and second-order orientational correlation functions), whereas a smaller fraction exhibits slower orientational dynamics. The fraction of slow intracellular water varies between organisms, ranging from ~20% in E. coli to ~45% in B. subtilis spores. Comparison with the water dynamics observed in solutions mimicking the chemical composition of (parts of) the cytosol shows that the slow water is bound mostly to proteins, and to a lesser extent to other biomolecules and ions.

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“…2, а и 2, b, наблю-даемые различия спектральных зависимостей следует связать с разными силами осцилляторов дейтерирован-ной воды внутри нанометровых пор Нафиона в данном спектральном диапазоне. Таким образом, в эксперимен-тах по ИК фурье-спектрометрии можно изучать эффект " конфайнмента" (confinement), который в данном случае проявляется именно в различии спектров пропускания воды с указанным содержанием дейтерия внутри нано-метровых пор Нафиона и в кювете с размером 90 µm (различные проявления эффекта конфайнмента для воды описаны, например, в работах [43,44]). …”

Section: обсуждение результатовunclassified