12 research outputs found
The microscopic structure of water under extreme conditions
Liquid water is one of the key components of life on this planet. Moreover, its unique properties and anomalies make it highly relevant for several processes in physics, biology and chemistry. The fascinating characteristics and anomalies are by no means restricted to liquid water at ambient conditions. Thus, pressurised water at high temperatures, so-called hydrothermal water, is essential for heat and mass transfer processes in Earth’s upper mantle and exerts a significant influence on geochemical processes. For instance, hydrothermal water is involved in the formation of ore deposits due to its unique dissolving properties under hydrothermal conditions. However, the transport of metal often requires an additional dissolved salt which can form a metal-bearing complex and thus enables the transport. In this context, NaCl is one of the most abundant dissolved salts in natural hydrothermal fluids. Liquid water is also of major importance when exposed to high pressures and temperatures far below 100 °C. Under these conditions, it provides a habitat for marine life in the deep sea, for instance, or is used in industrial processes. Furthermore, by changing the applied pressure, structural changes of the water structure can be induced in a controlled manner, which offers a promising opportunity to test various proposed models for liquid water. These unique properties of water are directly related to the internal arrangement of the hydrogen bond network, whose exact structure is still subject to debate. Therefore, this thesis focuses on the investigation of the local microscopic structure of water and aqueous sodium chloride solution under extreme thermodynamic conditions. For this purpose, X-ray Raman scattering spectroscopy is primarily exploited which is a powerful tool for studying absorption edges under extreme conditions. The correlation of the oxygen K-edge spectrum of water with the local arrangement of the water molecules is utilized and combined with spectral calculations based on various structural models to resolve the changes in the water network over a wide range of temperatures and pressures. This way, the exact influence of the sodium chloride ions on the water structure at hydrothermal conditions is revealed, as well as the microscopic structural changes around the anomaly at 3 kbar
Temperature dependence of the hydrogen bond network in Trimethylamine N-oxide and guanidine hydrochloride - water solutions
We present an X-ray Compton scattering study on aqueous Trimethylamine
N-oxide (TMAO) and guanidine hydrochloride solutions (GdnHCl) as a function of
temperature. Independent from the concentration of the solvent, Compton
profiles almost resemble results for liquid water as a function of temperature.
However, The number of hydrogen bonds per water molecule extracted from the
Compton profiles suggests a decrease of hydrogen bonds with rising temperatures
for all studied samples, the differences between water and the solutions are
weak. Nevertheless, the data indicate a reduced bond weakening with rising TMAO
concentration up to 5M of 7.2% compared to 8 % for pure water. In contrast, the
addition of GdnHCl appears to behave differently for concentrations up to 3.1 M
with a weaker impact on the temperature response of the hydrogen bond
structure
Hydration in aqueous NaCl
Atomistic details about the hydration of ions in aqueous solutions are still debated due to the disordered and statistical nature of the hydration process. However, many processes from biology, physical chemistry to materials sciences rely on the complex interplay between solute and solvent. Oxygen K-edge X-ray excitation spectra provide a sensitive probe of the local atomic and electronic surrounding of the excited sites. We used ab initio molecular dynamics simulations together with extensive spectrum calculations to relate the features found in experimental oxygen K-edge spectra of a concentration series of aqueous NaCl with the induced structural changes upon solvation of the salt and distill the spectral fingerprints of the first hydration shells around the Na+- and Cl−-ions. By this combined experimental and theoretical approach, we find the strongest spectral changes to indeed result from the first hydration shells of both ions and relate the observed shift of spectral weight from the post- to the main-edge to the origin of the post-edge as a shape resonance. </p
Impact of Macromolecular Crowding and Compression on Protein–Protein Interactions and Liquid–Liquid Phase Separation Phenomena
We determined the intermolecular interaction potential, V(r), of dense lysozyme solutions, which governs the spatial distribution of the protein molecules and the location of its liquid–liquid phase separation (LLPS) region, in various crowding environments applying small-angle X-ray scattering in combination with liquid-state theory. We explored the effect of polyethylene glycol (PEG) on V(r) and the protein’s phase behavior over a wide range of temperatures and pressures, crossing from the dilute to the semidilute polymer regime, thereby mimicking all crowding scenarios encountered in the heterogeneous biological cell. V(r) and hence the protein–protein distances and the phase boundary of the LLPS region strongly depend on the polymer-to-protein size ratio and the polymer concentration. The strongest effect is observed for small-sized PEG molecules, leading to a marked decrease of the mean intermolecular spacing of the protein molecules with increasing crowder concentration. The effect levels off at intermolecular distances where the proteins’ second hydration shells start to penetrate each other. Strong repulsive forces like hydration-shell repulsion and/or soft enthalpic protein-PEG interactions must be operative at short distances which stabilize the protein against depletion-induced aggregation, also at pressures as high as encountered in the deep sea, where pressures up to the kbar-level are encountered
Hydration in aqueous NaCl
Atomistic details about the hydration of ions in aqueous solutions are still debated due to the disordered and statistical nature of the hydration process. However, many processes from biology, physical chemistry to materials sciences rely on the complex interplay between solute and solvent. Oxygen K-edge X-ray excitation spectra provide a sensitive probe of the local atomic and electronic surrounding of the excited sites. We used ab initio molecular dynamics simulations together with extensive spectrum calculations to relate the features found in experimental oxygen K-edge spectra of a concentration series of aqueous NaCl with the induced structural changes upon solvation of the salt and distill the spectral fingerprints of the first hydration shells around the Na+- and Cl--ions. By this combined experimental and theoretical approach, we find the strongest spectral changes to indeed result from the first hydration shells of both ions and relate the observed shift of spectral weight from the post- to the main-edge to the origin of the post-edge as a shape resonance
Ion association in hydrothermal aqueous NaCl solutions: implications for the microscopic structure of supercritical water
Knowledge of the microscopic structure of fluids and changes thereof with pressure and temperature is important for the understanding of chemistry and geochemical processes. In this work we investigate the influence of sodium chloride on the hydrogen-bond network in aqueous solution up to supercritical conditions. A combination of in situ X-ray Raman scattering and ab initio molecular dynamics simulations is used to probe the oxygen K-edge of the alkali halide aqueous solution in order to obtain unique information about the oxygen's local coordination around the ions, e.g. solvation-shell structure and the influence of ion pairing. The measured spectra exhibit systematic temperature dependent changes, which are entirely reproduced by calculations on the basis of structural snapshots obtained via ab initio molecular dynamics simulations. Analysis of the simulated trajectories allowed us to extract detailed structural information. This combined analysis reveals a net destabilizing effect of the dissolved ions which is reduced with rising temperature. The observed increased formation of contact ion pairs and occurrence of larger polyatomic clusters at higher temperatures can be identified as a driving force behind the increasing structural similarity between the salt solution and pure water at elevated temperatures and pressures with drawback on the role of hydrogen bonding in the hot fluid. We discuss our findings in view of recent results on hot NaOH and HCl aqueous fluids and emphasize the importance of ion pairing in the interpretation of the microscopic structure of water
Structural and electron spin state changes in an x-ray heated iron carbonate system at the Earth's lower mantle pressures
The determination of the spin state of iron-bearing compounds at high pressure and temperature is crucial for our understanding of chemical and physical properties of the deep Earth. Studies on the relationship between the coordination of iron and its electronic spin structure in iron-bearing oxides, silicates, carbonates, iron alloys, and other minerals found in the Earth's mantle and core are scarce because of the technical challenges to simultaneously probe the sample at high pressures and temperatures. We used the unique properties of a pulsed and highly brilliant x-ray free electron laser (XFEL) beam at the High Energy Density (HED) instrument of the European XFEL to x-ray heat and probe samples contained in a diamond anvil cell. We heated and probed with the same x-ray pulse train and simultaneously measured x-ray emission and x-ray diffraction of an FeCO sample at a pressure of 51 GPa with up to melting temperatures. We collected spin state sensitive Fe Kβ fluorescence spectra and detected the sample's structural changes via diffraction, observing the inverse volume collapse across the spin transition. During x-ray heating, the carbonate transforms into orthorhombic FeCO and iron oxides. Incipient melting was also observed. This approach to collect information about the electronic state and structural changes from samples contained in a diamond anvil cell at melting temperatures and above will considerably improve our understanding of the structure and dynamics of planetary and exoplanetary interiors
Structural and electron spin state changes in an x-ray heated iron carbonate system at the Earth's lower mantle pressures
The determination of the spin state of iron-bearing compounds at high pressure and temperature is crucial for our understanding of chemical and physical properties of the deep Earth. Studies on the relationship between the coordination of iron and its electronic spin structure in iron-bearing oxides, silicates, carbonates, iron alloys, and other minerals found in the Earth's mantle and core are scarce because of the technical challenges to simultaneously probe the sample at high pressures and temperatures. We used the unique properties of a pulsed and highly brilliant x-ray free electron laser (XFEL) beam at the High Energy Density (HED) instrument of the European XFEL to x-ray heat and probe samples contained in a diamond anvil cell. We heated and probed with the same x-ray pulse train and simultaneously measured x-ray emission and x-ray diffraction of an FeCO3 sample at a pressure of 51 GPa with up to melting temperatures. We collected spin state sensitive Fe Kβ1,3
fluorescence spectra and detected the sample's structural changes via diffraction, observing the inverse volume collapse across the spin transition. During x-ray heating, the carbonate transforms into orthorhombic Fe4C3O12 and iron oxides. Incipient melting was also observed. This approach to collect information about the electronic state and structural changes from samples contained in a diamond anvil cell at melting temperatures and above will considerably improve our understanding of the structure and dynamics of planetary and exoplanetary interiors.ISSN:2643-156