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122 results on '"Kimmel, Greg A."'

1. Isotope effects in supercooled H$_2$O and D$_2$O and a corresponding-states-like rescaling of the temperature and pressure

Author

Kimmel, Greg A.

Subjects
Physics - Chemical Physics, Condensed Matter - Other Condensed Matter, Condensed Matter - Soft Condensed Matter
Abstract

Water shows anomalous properties that are enhanced upon supercooling. The unusual behavior is observed in both H$_2$O and D$_2$O, however with different temperature dependences for the two isotopes. It is often noted that comparing the properties of the isotopes at two different temperatures (i.e., a temperature shift) approximately accounts for many of the observations with a temperature shift of 7.2 K in the temperature of maximum density being the most well-known example. However, the physical justification for such a shift is unclear. Motivated by recent work demonstrating a corresponding-states-like rescaling for water properties in three classical water models that all exhibit a liquid-liquid transition and critical point (B. Uralcan, et al., J. Chem. Phys. 150, 064503 (2019)), the applicability of this approach for reconciling the differences in temperature- and pressure-dependent thermodynamic properties of H$_2$O and D$_2$O is investigated here. Utilizing previously published data and equations-of-state for H$_2$O and D$_2$O, we show that the available data and models for these isotopes are consistent with such a low temperature correspondence. These observations provide support for the hypothesis that a liquid-liquid critical point, which is predicted to occur at low temperatures and high pressures, is the origin of many of water's anomalies.

Published
2024

3. Isotope effects in supercooled H2O and D2O and a corresponding-states-like rescaling of the temperature and pressure.

Author

Kimmel, Greg A.

Subjects
*THERMODYNAMICS, *ISOTOPES, *LOW temperatures, *POLYWATER, *CRITICAL point (Thermodynamics), *SUPERCOOLED liquids
Abstract

Water shows anomalous properties that are enhanced upon supercooling. The unusual behavior is observed in both H2O and D2O, however, with different temperature dependences for the two isotopes. It is often noted that comparing the properties of the isotopes at two different temperatures (i.e., a temperature shift) approximately accounts for many of the observations—with a temperature shift of 7.2 K in the temperature of maximum density being the most well-known example. However, the physical justification for such a shift is unclear. Motivated by recent work demonstrating a "corresponding-states-like" rescaling for water properties in three classical water models that all exhibit a liquid–liquid transition and critical point [Uralcan et al., J. Chem. Phys. 150, 064503 (2019)], the applicability of this approach for reconciling the differences in the temperature- and pressure-dependent thermodynamic properties of H2O and D2O is investigated here. Utilizing previously published data and equations-of-state for H2O and D2O, we show that the available data and models for these isotopes are consistent with such a low temperature correspondence. These observations provide support for the hypothesis that a liquid–liquid critical point, which is predicted to occur at low temperatures and high pressures, is the origin of many of water's anomalies. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Reversible structural transformations in supercooled water from 135 to 245 K

Author

Kringle, Loni, Thornley, Wyatt A., Kay, Bruce D., and Kimmel, Greg A.

Subjects
Physics - Chemical Physics
Abstract

Water has many anomalous properties compared to "simple" liquids, and these anomalies are typically enhanced in supercooled water. While numerous models have been proposed, including the liquid-liquid critical point, the singularity-free scenario, and the stability limit conjecture, a molecular-level understanding remains elusive.The main difficulty in determining which, if any, of these models is correct is the limited amount of data in the relevant temperature and pressure ranges. For water at ambient pressures, which is the focus of this work, data is largely missing from 160 - 232 K due to rapid crystallization. Whether rapid crystallization is just an experimental obstacle, or a fundamental problem signaling the inability of water to thermally equilibrate prior to crystallization is also a major unanswered question. Here, we investigate the structural transformations of transiently-heated, supercooled water with nanosecond time resolution using infrared vibrational spectroscopy. The experiments demonstrate three key results. First, water's structure relaxes from its initial configuration to a "steady-state" configuration prior to the onset of crystallization over a wide temperature range. Second, water's steady-state structure can be reproduced by a linear combination of two, temperature-independent structures that correspond to a "high-temperature liquid" and a "low-temperature liquid." Third, the observed structural changes are reversible over the full temperature range. Taken together, these results show that supercooled water can equilibrate prior to crystallization for temperatures from the homogeneous nucleation temperature down to the glass transition temperature. Second, the results provide support for the hypothesis that supercooled water can be described as a mixture of two, structurally-distinct, interconvertible liquids from 135 K to 245 K.

Published
2019
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5. Boehmite and Gibbsite Nanoplates for the Synthesis of Advanced Alumina Products

Author

Zhang, Xin, Huestis, Patricia L, Pearce, Carolyn I, Hu, Jian Zhi, Page, Katharine, Anovitz, Lawrence M, Aleksandrov, Alexandr B, Prange, Micah P, Kerisit, Sebastien, Bowden, Mark E, Cui, Wenwen, Wang, Zheming, Jaegers, Nicholas R, Graham, Trent R, Dembowski, Mateusz, Wang, Hsiu-Wen, Liu, Jue, N’Diaye, Alpha T, Bleuel, Markus, Mildner, David FR, Orlando, Thomas M, Kimmel, Greg A, La Verne, Jay A, Clark, Sue B, and Rosso, Kevin M

Subjects
Engineering, Materials Engineering, Chemical Sciences, gibbsite, boehmite, aluminum oxides, nanoplates, material synthesis, thermal decomposition, neutron scattering, temperature-dependent Raman, Industrial biotechnology, Macromolecular and materials chemistry, Nanotechnology
Abstract

Boehmite (γ-AlOOH) and gibbsite (α-Al-(OH)3) are important archetype (oxy)hydroxides of aluminum in nature that also play diverse roles across a plethora of industrial applications. Developing the ability to understand and predict the properties and characteristics of these materials, on the basis of their natural growth or synthesis pathways, is an important fundamental science enterprise with wide-ranging impacts. The present study describes bulk and surface characteristics of these novel materials in comprehensive detail, using a collectively sophisticated set of experimental capabilities, including a range of conventional laboratory solids analyses and national user facility analyses such as synchrotron X-ray absorption and scattering spectroscopies as well as small-angle neutron scattering. Their thermal stability is investigated using in situ temperature-dependent Raman spectroscopy. These pure and effectively defect-free materials are ideal for synthesis of advanced alumina products.

Published
2018

6. Elucidating the water–anatase TiO2(101) interface structure using infrared signatures and molecular dynamics.

Author

O'Connor, Christopher R., Calegari Andrade, Marcos F., Selloni, Annabella, and Kimmel, Greg A.

Subjects
MOLECULAR dynamics, INTERFACE structures, HYDROGEN bonding, INFRARED spectroscopy, MONOMOLECULAR films, ATOMS
Abstract

The structure and dynamics of water on solid surfaces critically affect the chemistry of materials in ambient and aqueous environments. Here, we investigate the hydrogen bonding network of water adsorbed on the majority (101) surface of anatase TiO2, a widely used photocatalyst, using polarization- and azimuth-resolved infrared spectroscopy combined with neural network potential molecular dynamics simulations. Our results show that one monolayer of water saturates the undercoordinated titanium (Ti5c) sites, forming one-dimensional chains of molecule hydrogen bonded to surface undercoordinated bridging oxygen (O2c) atoms. As the coverage increases, water adsorption on O2c sites leads to significant restructuring of the water monolayer and the formation of a two-dimensional hydrogen bond network characterized by tightly bound pairs of water molecules on adjacent Ti5c and O2c sites. This structural motif likely persists at ambient conditions, influencing the reactions occurring there. The results reported here provide critical details of the structure of the water–anatase (101) interface that were previously hypothesized but unconfirmed experimentally. [ABSTRACT FROM AUTHOR]

Published
2023
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7. Structural relaxation of water during rapid cooling from ambient temperatures.

Author

Kringle, Loni, Kay, Bruce D., and Kimmel, Greg A.

Subjects
POLYWATER, WATER temperature, REFRACTIVE index, COOLING, HIGH temperatures, ICE
Abstract

Experiments investigating the properties of deeply supercooled liquid water are needed to develop a comprehensive understanding of water's anomalous properties. One approach involves transiently heating nanoscale water films into the supercooled region for several nanoseconds at a time and then interrogating the water films after they have quenched to cryogenic temperatures. To relate the results obtained with this approach to other experiments and simulations on supercooled water, it is important to understand how closely the quenched structure tracks the (metastable) equilibrium structure of water as a function of the transient heating temperature. A key step involves quantifying the extent to which water that is transiently heated to ambient temperatures [hyperquenched water (HQW)] subsequently relaxes toward the structure of low-density amorphous (LDA) ice as it cools. We analyzed the infrared reflection–absorption spectra of LDA, HQW, and crystalline ice films to determine their complex indices of refraction. With this information, we estimate that HQW retains ∼50%–60% of a structural motif characteristic of water at high temperatures with the balance comprised of a low-temperature motif. This result, along with results from x-ray diffraction experiments on water and amorphous ices, allows one to quantify the fraction of the high-temperature motif at approximately zero pressure as a function of temperature from 150 to 350 K. [ABSTRACT FROM AUTHOR]

Published
2023
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10. Isotope effects on the structural transformation and relaxation of deeply supercooled water.

Author

Kringle, Loni, Thornley, Wyatt A., Kay, Bruce D., and Kimmel, Greg A.

Subjects
SUPERCOOLED liquids, METASTABLE states, PULSED lasers, ISOTOPES, ISOTOPOLOGUES, PULSED laser deposition, CRYSTALLIZATION
Abstract

We have examined the structure of supercooled liquid D2O as a function of temperature between 185 and 255 K using pulsed laser heating to rapidly heat and cool the sample on a nanosecond timescale. The liquid structure can be represented as a linear combination of two structural motifs, with a transition between them described by a logistic function centered at 218 K with a width of 10 K. The relaxation to a metastable state, which occurred prior to crystallization, exhibited nonexponential kinetics with a rate that was dependent on the initial structural configuration. When the temperature is scaled by the temperature of maximum density, which is an isostructural point of the isotopologues, the structural transition and the non-equilibrium relaxation kinetics of D2O agree remarkably well with those for H2O. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Origin of hydroxyl pair formation on reduced anatase TiO2(101)

Author

Adamsen, Kræn C., primary, Petrik, Nikolay G., additional, Dononelli, Wilke, additional, Kimmel, Greg A., additional, Xu, Tao, additional, Li, Zheshen, additional, Lammich, Lutz, additional, Hammer, Bjørk, additional, Lauritsen, Jeppe V., additional, and Wendt, Stefan, additional

Published
2023
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16. Crystallization kinetics of amorphous acetonitrile nanoscale films.

Author

Smith, R. Scott, Tylinski, M., Kimmel, Greg A., and Kay, Bruce D.

Subjects
CRYSTALLIZATION kinetics, ACETONITRILE, AVRAMI equation, MOLECULAR beams, MONOMOLECULAR films, CRYSTALLIZATION, DISCONTINUOUS precipitation
Abstract

We measure the isothermal crystallization kinetics of amorphous acetonitrile films using molecular beam dosing and reflection adsorption infrared spectroscopy techniques. Experiments on a graphene covered Pt(111) substrate revealed that the crystallization rate slows dramatically during long time periods and that the overall kinetics cannot be described by a simple application of the Avrami equation. The crystallization kinetics also have a thickness dependence with the thinner films crystallizing much slower than the thicker ones. Additional experiments showed that decane layers at both the substrate and vacuum interfaces can also affect the crystallization rates. A comparison of the crystallization rates for CH3CN and CD3CN films showed only an isotope effect of ∼1.09. When amorphous films were deposited on a crystalline film, the crystalline layer did not act as a template for the formation of a crystalline growth front. These overall results suggest that the crystallization kinetics are complicated, indicating the possibility of multiple nucleation and growth mechanisms. [ABSTRACT FROM AUTHOR]

Published
2021
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18. Insights into Acetic Acid Binding and Ketene Formation on Anatase TiO2(101).

Author

O'Connor, Christopher R., Ma, Runze, Collinge, Gregory, Lee, Mal-Soon, Kimmel, Greg A., and Dohnálek, Zdenek

Subjects
ACETIC acid, CARBOXYLIC acids, SCANNING tunneling microscopy, ACETATES, TITANIUM dioxide, DENSITY functional theory, ULTRAHIGH vacuum
Abstract

Understanding the adsorption and reactivity of carboxylic acids on oxide surfaces is of great interest in catalysis for biomass upgrading via ketonization, a carbon–carbon coupling reaction. Herein, we investigate the adsorption and reaction of acetic acid on anatase TiO2(101) using scanning tunneling microscopy, infrared spectroscopy, temperature programmed reaction, and density functional theory calculations. We demonstrate the adsorption of acetic acid can form two intermediates: (1) dissociated, bidentate acetate with an associated bridging hydroxyl, and (2) molecular, monodentate acetic acid. The coexistence of ordered phases with increasing monolayer (ML) saturation coverages consisting of (1) pure acetate (0.5 ML), (2) mixed acetate/acetic acid (0.67 ML), (3) mixed acetate/acetic acid (1.0 ML) and (4) pure acetic acid demonstrates similar energetics for both acetate and acetic acid species. Under ultra-high vacuum conditions, the presence of both monodentate acetic acid and bidentate acetate was observed below room temperature, while solely bidentate acetate was observed up to 575 K. The deprotonation of acetic acid produces water at 280 K, while the thermal decomposition of bidentate acetate produces ketene and acetic acid at 645 K. This model study provides detailed insight into the stability and reactivity of carboxylic acid surface-bound intermediates, which could participate during ketonization reactions for biomass upgrading. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Origin of hydroxyl pair formation on reduced anatase TiO2(101).

Author

Adamsen, Kræn C., Petrik, Nikolay G., Dononelli, Wilke, Kimmel, Greg A., Xu, Tao, Li, Zheshen, Lammich, Lutz, Hammer, Bjørk, Lauritsen, Jeppe V., and Wendt, Stefan

Abstract

The interaction of water with metal oxide surfaces is of key importance to several research fields and applications. Because of its ability to photo-catalyze water splitting, reducible anatase TiO2 (a-TiO2) is of particular interest. Here, we combine experiments and theory to study the dissociation of water on bulk-reduced a-TiO2(101). Following large water exposures at room temperature, point-like protrusions appear on the a-TiO2(101) surface, as shown by scanning tunneling microscopy (STM). These protrusions originate from hydroxyl pairs, consisting of terminal and bridging OH groups, OHt/OHb, as revealed by infrared reflection absorption spectroscopy (IRRAS) and valence band experiments. Utilizing density functional theory (DFT) calculations, we offer a comprehensive model of the water/a-TiO2(101) interaction. This model also explains why the hydroxyl pairs are thermally stable up to ∼480 K. [ABSTRACT FROM AUTHOR]

Published
2023
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22. Crystallization growth rates and front propagation in amorphous solid water films.

Author

Smith, R. Scott, Yuan, Chunqing, Petrik, Nikolay G., Kimmel, Greg A., and Kay, Bruce D.

Subjects
THIN films, AMORPHOUS substances, GROWTH rate, INFRARED absorption, INFRARED spectroscopy
Abstract

The growth rate of crystalline ice (CI) in amorphous solid water (ASW) films was investigated using reflection absorption infrared spectroscopy. Two different experiments were set up to measure rates of the crystallization front propagation from the underlying crystalline template upward and from the vacuum interface downward. In one set of experiments, layers of ASW (5% D2O in H2O) were grown on a CI template and capped with a decane layer. In isothermal experiments from 140 to 150 K, crystallization was observed from the onset (no induction time) and the extent of crystallization increased linearly with time. In a second set of experiments, uncapped ASW films without a CI template were studied. The films were created by placing a 100 ML isotopic layer (5% D2O in H2O) at various positions in a 1000 ML ASW (H2O) film. The CI growth rates obtained from the two configurations (capped films with a CI template and uncapped films without a CI template) are in quantitative agreement. The results support the idea that for ASW films in a vacuum, a crystalline layer forms at the surface that then acts as a CI template for a growth front that moves downward into the film. [ABSTRACT FROM AUTHOR]

Published
2019
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23. Homogeneous ice nucleation rates and crystallization kinetics in transiently-heated, supercooled water films from 188 K to 230 K.

Author

Kimmel, Greg A., Xu, Yuntao, Brumberg, Alexandra, Petrik, Nikolay G., Smith, R. Scott, and Kay, Bruce D.

Subjects
*CRYSTALLIZATION kinetics, *HOMOGENEOUS nucleation, *CRYSTALLIZATION, *RATE of nucleation, *HEAT pulses, *DISCONTINUOUS precipitation
Abstract

The crystallization kinetics of transiently heated, nanoscale water films were investigated for 188 K < Tpulse < 230 K, where Tpulse is the maximum temperature obtained during a heat pulse. The water films, which had thicknesses ranging from approximately 15–30 nm, were adsorbed on a Pt(111) single crystal and heated with ∼10 ns laser pulses, which produced heating and cooling rates of ∼109–1010 K/s in the adsorbed water films. Because the ice growth rates have been measured independently, the ice nucleation rates could be determined by modeling the observed crystallization kinetics. The experiments show that the nucleation rate goes through a maximum at T = 216 K ± 4 K, and the rate at the maximum is 1029±1 m−3 s−1. The maximum nucleation rate reported here for flat, thin water films is consistent with recent measurements of the nucleation rate in nanometer-sized water drops at comparable temperatures. However, the nucleation rate drops rapidly at lower temperatures, which is different from the nearly temperature-independent rates observed for the nanometer-sized drops. At T ∼ 189 K, the nucleation rate for the current experiments is a factor of ∼104−5 smaller than the rate at the maximum. The nucleation rate also decreases for Tpulse > 220 K, but the transiently heated water films are not very sensitive to the smaller nucleation rates at higher temperatures. The crystallization kinetics are consistent with a "classical" nucleation and growth mechanism indicating that there is an energetic barrier for deeply supercooled water to convert to ice. [ABSTRACT FROM AUTHOR]

Published
2019
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25. Communication: Proton exchange in low temperature co-mixed amorphous H2O and D2O films: The effect of the underlying Pt(111) and graphene substrates.

Author

Smith, R. Scott, Petrik, Nikolay G., Kimmel, Greg A., and Kay, Bruce D.

Subjects
EXCHANGE reactions, AMORPHOUS substances, HYDROGEN ions, PROTONS, GRAPHENE, SUBSTRATES (Materials science)
Abstract

Isotopic exchange reactions in mixed D2O and H2O amorphous solid water (ASW) films were investigated using reflection absorption infrared spectroscopy. Nanoscale films composed of 5% D2O in H2O were deposited on Pt(111) and graphene covered Pt(111) substrates. At 130 K, we find that the reaction is strongly dependent on the substrate with the H/D exchange being significantly more rapid on the Pt(111) surface than on graphene. At 140 K, the films eventually crystallize with the final products on the two substrates being primarily HOD molecule on Pt(111) and a mixture of HOD and unreacted D2O on graphene. We demonstrate by pre-dosing H2 and O2 on Pt(111) that the observed differences in reactivity on the two substrates are likely due to the formation of hydrogen ions at the Pt(111) surface that are not formed on graphene. Once formed the mobile protons move through the ASW overlayer to initiate the H/D exchange reaction. [ABSTRACT FROM AUTHOR]

Published
2018
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32. Binding of Formic Acid on Anatase TiO2(101)

Author

Wang, Yang, primary, Wen, Bo, additional, Dahal, Arjun, additional, Kimmel, Greg A., additional, Rousseau, Roger, additional, Selloni, Annabella, additional, Petrik, Nikolay G., additional, and Dohnálek, Zdenek, additional

Published
2020
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33. Methane Hydrate Formation on Clay Mineral Surfaces: Thermodynamic Stability and Heterogeneous Nucleation Mechanisms

Author

Teich-McGoldrick, Stephanie, primary, Hart, David Blaine, additional, Gordon, Margaret Ellen, additional, Meserole, Stephen P., additional, Rodriguez, Mark A., additional, Thurmer, Konrad, additional, Cygan, Randall Timothy, additional, Yuan, Chunqing, additional, Kimmel, Greg A., additional, Kay, Bruce D., additional, and Smith, R. Scott, additional

Published
2015
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34. A nanosecond pulsed laser heating system for studying liquid and supercooled liquid films in ultrahigh vacuum.

Author

Yuntao Xu, Dibble, Collin J., Petrik, Nikolay G., Smith, R. Scott, Joly, Alan G., Tonkyn, Russell G., Kay, Bruce D., and Kimmel, Greg A.

Subjects
SUPERCOOLED liquids, LIQUID films, ULTRAHIGH vacuum, PULSED lasers, LASER heating
Abstract

A pulsed laser heating system has been developed that enables investigations of the dynamics and kinetics of nanoscale liquid films and liquid/solid interfaces on the nanosecond time scale in ultrahigh vacuum (UHV). Details of the design, implementation, and characterization of a nanosecond pulsed laser system for transiently heating nanoscale films are described. Nanosecond pulses from a Nd:YAG laser are used to rapidly heat thin films of adsorbed water or other volatile materials on a clean, well-characterized Pt(111) crystal in UHV. Heating rates of ~1010 K/s for temperature increases of ~100-200 K are obtained. Subsequent rapid cooling (~5 × 109 K/s) quenches the film, permitting insitu, post-heating analysis using a variety of surface science techniques. Lateral variations in the laser pulse energy are ~±2.7% leading to a temperature uncertainty of ~±4.4 K for a temperature jump of 200 K. Initial experiments with the apparatus demonstrate that crystalline ice films initially held at 90 K can be rapidly transformed into liquid water films with T > 273 K. No discernable recrystallization occurs during the rapid cooling back to cryogenic temperatures. In contrast, amorphous solid water films heated below the melting point rapidly crystallize. The nanosecond pulsed laser heating system can prepare nanoscale liquid and supercooled liquid films that persist for nanoseconds per heat pulse in an UHV environment, enabling experimental studies of a wide range of phenomena in liquids and at liquid/solid interfaces. [ABSTRACT FROM AUTHOR]

Published
2016
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48. Electron-stimulated reactions in nanoscale water films adsorbed on α-Al2O3(0001).

Author

Petrik, Nikolay G. and Kimmel, Greg A.

Abstract

The radiation-induced decomposition and desorption of nanoscale amorphous solid water (D2O) films adsorbed on an α-Al2O3(0001) surface was studied at low temperature in ultrahigh vacuum using temperature programmed desorption (TPD) and electron stimulated desorption (ESD) with a mono-energetic, low energy electron source. ESD yields of molecular products (D2, O2 and D2O) and the total sputtering yield increased with increasing D2O coverage up to ∼15 water monolayers (i.e.∼15 × 1015 cm−2) to a coverage-independent level for thicker water films. Experiments with isotopically-layered water films (D2O and H2O) demonstrated that the highest water decomposition yields occurred at the interfaces of the nanoscale water films with the alumina substrate and vacuum. However, the increased reactivity of the water/alumina interface is relatively small compared to the enhancements in the non-thermal reactions previously observed at the water/Pt(111) and water/TiO2(110) interfaces. We propose that the relatively low activity of Al2O3(0001) for the radiation-induced production of molecular hydrogen is associated with lower reactivity of this surface with hydrogen atoms, which are likely precursors for the formation of molecular hydrogen. [ABSTRACT FROM AUTHOR]

Published
2018
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