Liquid Alloys Research Articles

Nanoalloys Composed of Platinum Group Metals and p‐Block Elements for Innovative Catalysis

Alloy nanoparticles based on platinum group metals (PGMs) have been intensively investigated in various fields, especially in catalysis. Recently, the scope of alloying has expanded to include not only d‐block transition metals but also p‐block elements, which have a wide range of properties that are very different from those of d‐block transition metals. By alloying PGMs with p‐block elements, the electronic structure and surface properties of the catalysts can be tuned, enhancing their catalytic performance. The focus of this review is on PGM–p‐block element nanoalloys, their synthesis methods, characterization techniques, and catalytic properties. In addition to typical binary crystalline alloys, such as solid‐solution and intermetallic alloys, this review also highlights the potential of multielement, amorphous, or liquid alloys, which have recently garnered much attention. The review aims to provide valuable perspectives for the development of PGM‐based sustainable and innovative catalysis, while also addressing the current challenges and future directions in this field.

Accelerating phase field simulations through a hybrid adaptive Fourier neural operator with U-net backbone

Prolonged contact between a corrosive liquid and metal alloys can cause progressive dealloying. For one such process as liquid-metal dealloying (LMD), phase field models have been developed to understand the mechanisms leading to complex morphologies. However, the LMD governing equations in these models often involve coupled non-linear partial differential equations (PDE), which are challenging to solve numerically. In particular, numerical stiffness in the PDEs requires an extremely refined time step size (on the order of 10−12s or smaller). This computational bottleneck is especially problematic when running LMD simulation until a late time horizon is required. This motivates the development of surrogate models capable of leaping forward in time, by skipping several consecutive time steps at-once. In this paper, we propose a U-shaped adaptive Fourier neural operator (U-AFNO), a machine learning (ML) based model inspired by recent advances in neural operator learning. U-AFNO employs U-Nets for extracting and reconstructing local features within the physical fields, and passes the latent space through a vision transformer (ViT) implemented in the Fourier space (AFNO). We use U-AFNOs to learn the dynamics of mapping the field at a current time step into a later time step. We also identify global quantities of interest (QoI) describing the corrosion process (e.g., the deformation of the liquid-metal interface, lost metal, etc.) and show that our proposed U-AFNO model is able to accurately predict the field dynamics, in spite of the chaotic nature of LMD. Most notably, our model reproduces the key microstructure statistics and QoIs with a level of accuracy on par with the high-fidelity numerical solver, while achieving a significant 11, 200 × speed-up on a high-resolution grid when comparing the computational expense per time step. Finally, we also investigate the opportunity of using hybrid simulations, in which we alternate forward leaps in time using the U-AFNO with high-fidelity time stepping. We demonstrate that while advantageous for some surrogate model design choices, our proposed U-AFNO model in fully auto-regressive settings consistently outperforms hybrid schemes.

Understanding the local structure and thermophysical behavior of Mg-La liquid alloys via machine learning potential

Understanding the local structure and thermophysical behavior of Mg-La liquid alloys via machine learning potential

Theoretical Study of the Stability of CdSn Liquid Alloy at Different Temperatures

The quasi-lattice theory (QLT) is utilized for the prediction of the temperature and concentration dependence of the thermodynamic properties of the molten CdSn alloys. At first, the analytical expressions are employed to reckon the excess Gibbs free energy of mixing, Gibbs free energy of mixing, activity, enthalpy of mixing and entropy of mixing as well as concentration fluctuations, short range-order parameter and excess stability function ofCdSn melts at 773 K. For this, the model parameters i.e. size ratio and order energy parameter are assessed using the experimental data of the free energy of mixing for CdSnmelts at 773 K. The theoretical values of the thermodynamic functions are in well harmony with the interrelated experimental values. The theoretical values of the structure function like concentration fluctuations are in unison with the experimental values for molten CdSn system at 773 K. Again, the optimization procedure is applied to explore the excess Gibbs free energy of mixing, activity, concentration fluctuations, short-range order parameter and excess stability function at different temperatures for CdSnmelts. The present study discloses that the stability as well as the segregating nature of CdSnmelts decrease with the elevation of the temperature from 773 K to 1123 K. Further, the temperature dependency of the excess stability function reveals that there is a probability of transition from segregating character to the ordering character of CdSn melts near 1162 K. Keywords: Gibbs free energy of mixing; entropy of mixing; concentration fluctuations; short-range order parameter; excess stability function

Cluster structure of nickel and its alloys with chromium in the liquid state

Modern ideas about the structure of liquid metals and alloys are considered. The main emphasis is placed on the cluster model and its structural parameters. The effect of chromium concentration in nickel-chromium melts on the change in the parameters of the cluster structure is shown. The calculation results are compared with the previously obtained experimental X-ray diffraction data and the results of studying the temperature dependences of the physical properties of nickel and its alloys with chromium in the liquid state. Attention is drawn to the fact that at a temperature close to 1900ºС the cluster radius becomes less than 10 Ǻ and these are the critical temperatures characteristic of binary and multicomponent nickel melts, upon reaching which structural changes occur in the melts and the metallic liquid becomes more equilibrium. and microhomogeneous.

Analysis of Different Commercial Solid Fluxes Used During the Rotary Degassing Melt Treatment of Casting Aluminum Alloys

AbstractThis work aimed to get a better understanding of the behavior and melt cleaning efficiency of different commercial solid fluxes used in the foundry industry for the treatment of liquid aluminum alloys. This was realized by combining industrial melt treatment experiments with the application of characterization techniques that can provide information about the phase composition and thermal stability of different fluxes. Rotary degassing treatments coupled with flux addition using 5 different commercial fluxes were conducted on batches of EN AC-46000 alloy (AlSi9Cu3(Fe)) melt. The melt quality was assessed by the Qualiflash technique and Bifilm-Index (BI) analysis of reduced pressure test (RPT) samples. The phase composition and thermal behavior of the fluxes were investigated by X-ray diffraction (XRD) and differential thermal analysis (DTA), respectively. Among the 5 fluxes, two had a rather similar phase composition with the main constituents being NaCl, KCl, CaF2, MgF2, Na2CO3·NaHCO·3H2O, Na2SO4, and K2SiF6. These two fluxes, which contain a relatively high amount of fluoride components (about 11mol pct), and had a melting temperature below 600 °C, proved to be the most efficient in improving the melt quality. The Quality Temperature Index (QTI) values and normalized Bifilm-Index (NBI) results of the RPT samples generally showed a similar tendency, but there was only a loose relationship between the two parameters. Discrepancies between the results of different melt quality evaluation techniques can be traced back to their sensitivity to melt quality changes.

Thermophysical properties of undercooled Zr–Fe–Nb alloys investigated by electrostatic levitation and molecular dynamics calculation

The density, surface tension, and viscosity of liquid Zr76.0−xFe24.0Nbx (x = 6.6, 10.0, 15.0) alloys were measured by using the electrostatic levitation technique. The maximum undercooling achieved for these alloys was 151, 91, and 119 K, respectively. To evaluate the thermophysical properties in a wider temperature range, molecular dynamics simulations were performed by using the embedded atom method potential. Both measured and simulated results indicate that the liquid density increases linearly with decreasing temperature and also gradually rises with increasing Nb content. Additionally, the simulated and experimental results for surface tension and viscosity were analyzed. In all three alloys, surface tension increases linearly with decreasing temperature. The relationship between viscosity and temperature follows an Arrhenius-type equation, with both surface tension and viscosity increasing as the Nb content increases. The calculated results of density, surface tension, and viscosity are in good agreement with the experimental results. Furthermore, the specific heat, emissivity, and diffusion coefficient of liquid alloys were calculated. The specific heat for liquid Zr76.0−xFe24.0Nbx (x = 6.6, 10.0, 15.0) alloys is (36.47 ± 1.68), (35.20 ± 2.28), and (41.04 ± 3.73) J mol−1 K−1, respectively. Emissivity decreases linearly with temperature. The diffusion coefficient decreases, while the diffusion activation energy increases with a higher Nb content.

Synergic effects of time dependence and thermodynamic driving on metastable phase separation of liquid Fe50Cu50 alloy

Synergic effects of time dependence and thermodynamic driving on metastable phase separation of liquid Fe50Cu50 alloy

Phase-Field Approach to Formation of Aluminum Oxyhydroxide Nanofibrils on a Liquid Aluminum Alloy Surface in Water-Containing Atmospheres

Formation of peculiar nanofibril structures on the surface of liquid aluminum alloys as a result of chemical reaction of aluminum with water vapors was well studied experimentally for various alloy components starting from mercury. However, the mechanism of nanofibril formation remains unclear to date, and the lack of an appropriate theoretical model does not allow evaluation of the structure parameters depending on the process conditions. We assume that the interface layer between the liquid metal phase and the atmosphere, containing the water vapor, develops certain inhomogeneities respect to the content of hydroxyl groups. That provides areas of suppressed and enhanced diffusion of the aluminum from the liquid phase toward the atmosphere contact. Phase-field modeling, taking into account their elastic interaction, demonstrates formation of the array of nano-islands, enriched with hydroxyl groups, which can be precursors for formation and growth of nanofibrils with elements of pre-boehmite structure.

Thermodynamics of lead-free Sn-Au-Sb liquid alloys: a theoretical approach

The activities of the constituent metals in binary liquid solder alloys, namely Sb-Sn at 905 K, Au-Sn at 823 K, and Au-Sb at 913 K, and the activities of Sn in the ternary liquid solder alloys Sn-Au-Sb at 873 K for three cross-sections, i.e. for three different ratios of gold to antimony ( x Au : x Sb ) = 2: 1, 1: 1, and 1: 2, have been computed using the molecular interaction volume model (MIVM). The predicted values and the associated experimental data were analyzed. In addition, the excess Gibbs free energy of mixing ( G M xs ) of the binary alloys Sb-Sn, Au-Sn, and Au-Sb and of the ternary alloys Sn-Au-Sb for all three cross-sections was also calculated using the same model and analyzed with the relevant experimental values accessible in the articles to determine the sustainability of the model parameters. The agreement between the theoretical and experimental results has been found to be satisfactory for both the binary and ternary systems.

Devising a technology for manufacturing hollow cast steel structures with composite and reinforced non-metallic functional filler

The object of this study is the structure of hollow steel modules filled with various types of functional materials, as well as the technology of their production using lost foam casting. Computer simulation of hydrodynamic and heat-mass exchange processes and solidification was carried out to establish the laws and prerequisites for designing state-of-the-art hollow cast structures and to devise their production technology. The study investigated the influence of reinforced steel elements and reinforcement directly from the liquid alloy of the shell on the peculiarities of hydrodynamic, heat-mass transfer processes, and solidification during the production of hollow steel structures with functional fillers. It has been determined that the presence of polystyrene membranes in the functional filler for subsequent reinforcement from the liquid phase of the shell metal affects the hydrodynamics of filling the casting. In the thin channels formed in the filler, the metal flow rate increases from 2 m/s to 8 m/s in the upper channels, and from 3 m/s to 12 m/s in the lower channels, which is associated with an increase in metallostatic pressure. The presence of metal reinforcement in the functional filler and the reinforcement of the functional material from the liquid phase of the shell metal accelerates the heating of the non-metallic filler by 1.2–1.4 and 1.4–1.8 times, respectively. Reinforcement also helps increase the maximum heating temperature of the functional filler by 200–300 °C, which creates better conditions for its sintering. The grades of steels for their use as a matrix alloy in the production of hollow cast castings were determined; their structure and physical-mechanical properties were studied. The recommended modes of heat treatment of low-alloy steel to obtain the required properties have been determined. The study reported here is a theoretical prerequisite for verification in the manufacture of experimental cast hollow structures with metallic and non-metallic reinforcing phase

Application of liquid metal driven-abrasive flow to material removal for the inner surface of channel

Gallium-based eutectic liquid metal alloys possess unique properties such as deformability, high electrical conductivity, and low vapor pressure. These characteristics have generated significant interest in their application for stretchable electronics and microelectromechanical systems (MEMS). Precise manipulation of liquid metal within electrolytes is essential to meet specific functional requirements. This study investigates the electrostatic manipulation of liquid metal in an alkaline solution with abrasives for material removal from the inner surfaces of flow channels. The polarization of the double layer at the gallium‑indium alloy and electrolyte interface is analyzed, elucidating the principle of electrolyte propulsion via continuous electrowetting. A theoretical model is developed, and two- and three-dimensional transient and steady-state simulations of the liquid metal-driven abrasive flow are conducted. Results demonstrate that this method effectively removes material from the inner walls of straight channels during cyclic motion. Utilizing continuous electrowetting, an experimental apparatus was designed, where gallium‑indium liquid metal propelled silicon carbide abrasives against PMMA channel walls. Experimental results showed effective material removal, consistent with finite element simulations, confirming the feasibility of this innovative approach.

Gold and Gold Alloys Electropolishing in Choline Chloride-Glycerol Deep Eutectic Solvents

Electropolishing is a finishing technique used to reduce the roughness of metallic surfaces while enhancing their brightness. Based on anodic dissolution, this process enables the treatment of parts with complex geometries and reduces processing time compared to conventional mechanical finishing methods.Concerning precious metals, the use of electrolytes containing cyanides and other toxic compounds reduces EP’s attractiveness from an industrial standpoint. A further challenge lies in the difficulty of dissolving alloy elements in a homogeneous way1. It often requires the adjustment of operating parameters or even of the electrolyte composition for each alloy. In addition, the underlying mechanisms that govern the process are not fully understood, making it more difficult to scale up. As a result, it has become essential to explore high-performance electrolyte solutions while complying with environmental and health safety standards.Deep Eutectic Solvents (DES) are emerging as a good alternative for the chemical2 and electrochemical3 dissolution of metals. Their advantages include an extended electrochemical window compared with aqueous electrolytes, non-toxicity, and moderate cost3,4. They have already demonstrated their effectiveness on a wide selection of metals, including silver5 and copper3, elements often present in gold alloys.This work aims to evaluate the effectiveness of choline chloride-based DESs in the electropolishing process of 18K gold alloys. Their performance will be assessed in terms of roughness reduction, brightness enhancement and color preservation, all characteristics associated with the presence of uniform dissolution. The electrochemical mechanisms involved will also be examined.(1) Rodriguez J. ; Doche M-L ; Hihn J-Y ; Electropolishing of gold and gold alloys in HCl-glycerol-ethanol electrolytes App. Surf. Sci. Adv. 21(2024) 100604 https://doi.org/10.1016/j.apsadv.2024.100604(2) Jenkin, G. R. T.; Al-Bassam, A. Z. M.; Harris, R. C.; Abbott, A. P.; Smith, D. J.; Holwell, D. A.; Chapman, R. J.; Stanley, C. J. The Application of Deep Eutectic Solvent Ionic Liquids for Environmentally-Friendly Dissolution and Recovery of Precious Metals. Miner. Eng. 2016, 87, 18–24. https://doi.org/10.1016/j.mineng.2015.09.026.(3) Lebedeva, O. Metals | Free Full-Text | Advantages of Electrochemical Polishing of Metals and Alloys in Ionic Liquids. Metals 2021. https://doi.org/10.3390/met11060959.(4) Sánchez-Ortiz, W.; Aldana-González, J.; Manh, T. L.; Romero-Romo, M.; Mejía-Caballero, I.; Ramírez-Silva, M. T.; Arce-Estrada, E. M.; Mugica-Álvarez, V.; Palomar-Pardavé, M. A Deep Eutectic Solvent as Leaching Agent and Electrolytic Bath for Silver Recovery from Spent Silver Oxide Batteries. J. Electrochem. Soc. 2021, 168 (1), 016508. https://doi.org/10.1149/1945-7111/abdb01.(5) Loftis, J. D.; Abdel-Fattah, T. M. Nanoscale Electropolishing of High-Purity Silver with a Deep Eutectic Solvent. Colloids Surf. Physicochem. Eng. Asp. 2016, 511, 113–119. https://doi.org/10.1016/j.colsurfa.2016.09.013. Figure 1

Electrochemical Studies on CO2 Reduction at Liquid Gainsn Alloy Electrodes

The electrochemical reduction of CO2 (CO2RR) offers a sustainable technology for converting CO2 into valuable products when using electricity generated from renewable sources. Application-oriented research is currently focused mainly on the electrolysis of CO2 to hydrogen-rich fuels or chemical feedstock materials. In contrast our project aims to form solid carbon or carbon rich products (e.g. oxalate), which can finally be disposed in geological repositories. This negative emission technology is developed for a long-term and thereby sustainable CO2 removal from the global CO2 cycle 1. The continuous electrochemical formation of solid carbon from CO2 has so far only been reported on liquid GaInSn-M alloys (M: Ce, V) in water-containing DMF 2,3. Liquid electrodes have the advantage over solid electrodes that solid products do not adhere at the interface and therefore deactivate the catalytic properties of the electrode (coking effect). In first experiments, we studied GaInSn without additional metal alloying in DMF/H2O/ TBAPF6 electrolyte and got differing results to the previously published data. In our experiments, even pure GaInSn shows a significant activity for CO2RR to carbon monoxide and formic acid accompanied by lower quantities of H2. The product distribution (faradaic efficiencies) depends strongly on the water content in the DMF electrolyte. The production rate of CO increases significantly even with small amounts of water. First DFT simulations of the CO2RR provide possible explanations of this effect. Furthermore, it was observed that, depending on the applied cathodic potential, metallic nano particles are released from the GaInSn surface into the organic electrolyte (expulsion effect) which indicates a possible change in the surface composition during CO2 electrolysis 4. In accordance with the literature, our findings confirm the production of carbon flakes from CO2 on cerium modified GaInSn. However, we observe it even independently from the addition of water to the DMF electrolyte. DFT calculations enable us to conclude that the high affinity of cerium to oxygen is responsible for the change in product selectivity, as it can extract oxygen from CO2.1: May, M. M. and Rehfeld, Earth Syst. Dynam., 10, 1–7.doi.org/10.5194/esd-10-1-2019, 2019.2: Dorna Esrafilzadeh, NATURE COMMUNICATIONS | (2019) 10:865.doi.org/10.1038/s41467-019-08824-83: Mehmood Irfan, J. Mat. Chem. A, Issue 27, 2023doi.org/10.1039/D3TA01379K4: Mahroo Baharfar, Chemistry of Materials 2022 34 (23), 10761-10771doi.org/10.1038/s41467-019-08824-8 Figure 1

Metallic Glass Nanoparticles Synthesized via Flash Joule Heating for High Performance Catalysis

Metallic glasses (MGs) are a class of amorphous metal materials with remarkable properties. By leveraging an abundance of uncoordinated active sites that can serve as catalytic regions, MGs can have high catalytic activity and long-term stability as compared to their crystalline counterparts. Conventional synthesis methods cannot produce nanosized MGs with precise control over composition, phase, and morphology. This work presents flash Joule heating (FJH) as a novel one-step approach to synthesize fully amorphous MG nanoparticles while enabling unprecedented control over these critical parameters. The rapid heating (up to 2505 K/s) and ultrafast cooling rates (up to 1485 K/s) in FJH surpass the critical rates required for glass formation in metal-phosphide alloys like Pd-P, Pd-Ni-P, and Pd-Cu-P, preventing crystallization. Characterization techniques such as SAED, XRD, and XPS have confirmed the amorphous nature and metallic states of the nanoparticles.Remarkably, FJH allowed precise tuning of ternary alloy compositions spanning wide ranges from Pd-rich to Ni/Cu-rich regimes, closely matching designed precursor ratios. The technique significantly expanded the glass formation region compared to conventional methods, accessing previously unattainable compositions like binary Pd3P. Moreover, FJH enabled control over particle size from 2.33±0.83 nm to 36.5±10.1 nm with narrow distributions by optimizing precursors, thermal profiles, and alloy chemistries. Incorporation of multiple elements facilitated smaller nanoparticle formation due to enhanced entropy, reduced melting points, and decreased surface tension.The amorphous MG nanoparticles exhibited outstanding electrocatalytic performance and remarkable stability superiorities over their crystalline counterparts. For the oxygen evolution reaction, Pd-Ni-P MGs displayed ultra-low onset potentials ~300 mV below pure Pd and retained stable activity over 60 hours, contrasting rapid deactivation of crystalline samples of the same composition within 1 hour. PdCoP MGs for methanol oxidation showed high reaction rates and resilience against activity decline during accelerated durability testing, unlike rapidly decaying crystalline variants. This FJH synthesis approach unlocks new opportunities to realize the full potential of MGs by expanding the compositional space of alloy systems with precise control over MG properties, unlocking potential future transformative catalysts.Figure 1: Schematics for (a) a traditional heating-cooling process and (b) the FJH process. (c) Illustration of temperature vs. time diagram of supercooled liquid alloys and glass transformation.(d) Ternary phase diagrams of the Pd-Ni-P and Pd-Cu-P systems. Figure 1

Formation of Crystalline Si Film Using Liquid Zn Electrode in Molten KF–KCl–K2SiF6

Introduction Recently, crystalline Si solar cells have been the mainstream in the solar cell market, and the demand for crystalline Si solar cells is expected to increase in the future. However, it is difficult to further improve productivity with the current manufacturing method. It is a multi-step process and includes processes with high energy consumption due to the inclusion of the Siemens method and a process with low yield due to kerf losses. As a new production method for crystalline Si solar cells, our research group has proposed direct electrodeposition of Si films in molten KF–KCl using SiCl4 as a Si source [1]. We have already reported electrodeposition of Si film with a dense and smooth surface in molten KF–KCl–K2SiF6, which is the same bath state as after SiCl4 introduction [2]. Although this method produced dense and smooth crystalline Si films, the grain size of electrodeposited Si was as small as 20 µm even at 1073 K. To fabricate Si solar cells with high efficiency, it is necessary to reduce the number of grain boundaries where electrons and holes generated by light recombine, which requires increasing the crystal size.Referring to a previous report of Si deposition using a liquid Ga electrode at 373 K [3], we focused on using a liquid metal electrode in high-temperature molten salt to increase the grain size. We have already reported the electrodeposition of Si using a liquid Zn electrode held in a BN crucible in molten KF–KCl–K2SiF6 at 923 K [4]. The maximum grain size of electrodeposited Si was approximately 2 mm. However, the obtained Si was not in film form.To obtain crystalline Si film with large grain size, we propose, in the present study, a direct film formation method using thin liquid Zn. Fig. 1 shows a schematic diagram of the proposed mechanism. In the initial stages, Si(IV) ions are electrochemically reduced to form Si–Zn liquid alloy on the liquid Zn electrode held on the substrate. As the electrodeposition progresses, Si forms a film on the substrate and crystals grow. Finally, Zn is removed to obtain a crystalline Si film with a large grain size on the substrate. The goal for this crystalline Si film is a grain size of at least 1 mm and a thickness of 50–100 µm. Experimental All electrodepositions were performed under an Ar atmosphere in a glove box. The electrodeposition process was carried out in two steps as shown in Fig. 2. Electrodeposition to prepare thin liquid Zn was performed in molten NaCl–KCl–ZnCl2 at 723 K using a Si substrate. After electrodeposition of Si in molten KF–KCl–K2SiF6, the samples were washed with water for salt removal, treated with HCl for Zn removal, and analyzed by SEM/EDX. Result and discussion Fig. 3(a) shows an SEM image of the sample after Zn deposition in molten NaCl–KCl–ZnCl2 at a current density of 50 mA cm–2 and charge density of 21 C cm–2. EDX analysis showed that the gray areas were Zn and the black areas were Si substrate. Si deposition was then performed using the obtained Zn deposit as a working electrode in molten KF–KCl–K2SiF6 at 923 K at a current density of 20 mA cm–2 and charge density of 90 C cm–2. Fig. 3(b) shows an SEM image of the sample after removal of Zn. Crystalline Si was observed over the entire surface, but the distribution was uneven for Si with large grain sizes. This was thought to be caused by the fact that the Zn film was not uniform.These results suggest that the preparation of uniform thin Zn is necessary to realize the proposed mechanism. The uniform Zn film may be achieved by adding ZnCl2 to molten KF–KCl–K2SiF6 to co-deposit Si and Zn. Since Zn has a more positive deposition potential than Si, Zn is preferentially deposited in co-deposition. Fig. 4 shows an optical image of the sample prepared at 150 mA cm–2 for 90 C cm–2 in molten KF–KCl–K2SiF6–ZnCl2 at 923 K. A film-like deposit with metallic luster was obtained. R eferences [1] K. Maeda, K. Yasuda, T. Nohira, R. Hagiwara, and T. Homma, J. Electrochem. Soc., 162, D444 (2015).[2] K. Yasuda, K. Saeki, T. Kato, R. Hagiwara, T. Nohira, J. Electrochem. Soc., 165, D825 (2018).[3] J. Gu, E. Fahrenkrug, and S. Maldonado, J Am Chem Soc, 135, 1684 (2013).[4] W. Moteki, Y. Norikawa, and T. Nohira, J. Electrochem. Soc., 170, 062506 (2023). Figure 1

Phase behavior and atomic dynamics in RbxNa1–x: insights from machine learning interatomic potentials based on ab initio molecular dynamics

Liquid alkali metal alloys have garnered significant attention because of their potential applications in coolant systems and batteries, driven by the need for environmental conservation and technological development. However, research on these complex systems is limited, necessitating a deeper understanding to ensure their safe and effective utilization. This study presents a comprehensive investigation of the factors that determine the phase diagram of RbxNa1-x. By reproducing the experimental results using the thermodynamic integration method and machine learning interatomic potentials based onab initiomolecular dynamics simulations, we uncovered the delicate balance between the energy and entropy contributions that influence the phase stability of these liquid metal alloys. Further analysis of the liquid phase revealed the crucial roles of volume and atomic mass. Additionally, the coordination numbers of the atoms revealed distinct clustering behaviors, where Na atoms tended to avoid proximity to other Na atoms, whereas Rb atoms exhibited a strong tendency to cluster together. Moreover, the diffusion dynamics further illustrated the asymmetry in the behavior of Rb and Na, with Rb showing increased diffusion at higher concentrations and Na exhibiting higher diffusion at lower concentrations. These findings offer significant insights into the phase stability and the dynamic and structural properties of these complex liquid metal alloys.

Is the mechanism of "fast sound" the same in liquids with long-range interactions and disparate mass metallic alloys?

We present abinitio simulations of a large system of 2400 particles of molten NaCl to investigate the behavior of collective mode dispersion beyond the hydrodynamic regime. In particular, we aim to explain the unusually strong increase in the apparent speed of sound with wave number, which significantly exceeds the typical positive sound dispersion of 10%-25% observed in simple liquids. We compare dispersions of "bare" acoustic and optic modes in NaCl with abinitio simulations of other ionic melts such as CuCl and LiBr, metallic liquid alloys such as Pb44Bi56 and Li4Tl, and the regular Lennard-Jones KrAr liquid simulated by classical molecular dynamics. Analytical expressions for the "bare" acoustic and optic branches of collective excitations help us to identify the impact of the high-frequency optic branch on the emergence of "fast sound" in binary melts. Our findings show that in ionic melts, the high-frequency speed of sound is much larger than in the simple Lennard-Jones liquids and metallic melts, leading to an observed strong viscoelastic increase in the apparent speed of sound-more than double its adiabatic value.

Calorimetric study of the enthalpy of mixing in the liquid systems In-Li and In-Li-Sn

Enthalpies of mixing of liquid binary In-Li alloys at different temperatures as well as liquid ternary In-Li-Sn alloys at 1073 K were determined using drop calorimetry. The binary system was investigated over the whole composition range at 923 K and 1073 K. A common Redlich-Kister polynomial was used for fitting and to calculate the binary interaction parameters for In-Li. The system shows a quite strong exothermic behavior with a minimum molar mixing enthalpy of −20000 to −22000 J⋅mol−1, depending on the temperature, at xLi≈ 0.6. Limiting partial enthalpies of mixing were determined and associate formation was considered to explain temperature dependencies and different mixing behavior in the In- respectively Li-rich region. Eight sections in the ternary system In-Li-Sn were investigated at 1073 K. The respective binary starting concentrations for the sections were A: xLi/xSn ≈ 3:2, B: xLi/xSn ≈ 3:7, C: xIn/xSn ≈ 1:3, D: xIn/xSn ≈ 1:1, E: xIn/xSn ≈ 3:1, F: xIn/xLi ≈ 7:3, G: xIn/xLi ≈ 2:3, and H: xIn/xLi ≈ 3:7. The experimental ternary data was fitted based on a Redlich-Kister-Muggianu polynomial including ternary interactions. Additionally, a comparison with extrapolated binary data based on the Toop model and Muggianu model is presented.

Room-temperature CO2 conversion to carbon using liquid metal alloy catalysts without external energy input

Conversion of CO2 to carbon using a catalyst typically requires significant energy input such as heat, pressure, or electricity. This is due to its strong bonds and the energy needed to initiate the reaction. The energy requirement for CO2 conversion may also lead to carbon emissions if sources are fossil-based. There is less exploration at low temperatures and without an external energy CO2 conversion to solid carbon. Here, we show a liquid metal alloy (In0.2Ga0.8) used as a catalyst for converting CO2 to carbon at room temperature without external energy. The carbon formed was characterized, and the calculated free energy of the reduction reaction was −530 kJ mol−1.The catalyst coated over a ceramic surface observed similar phenomena of CO2 conversion to carbon at room temperature. The conversion was five times higher at catalyst-coated ceramic membranes than at bulk catalysts. The CO2 conversion efficiency was 60 % at the catalytic membrane for continuous flow of CO2 at room temperature. EDX and XPS studies confirmed the formation of carbon at the catalyst surface. Our study may open the topic of membrane-based catalysis of CO2 for practical carbon conversion at lower operating costs at the industrial scale to achieve net-zero emissions.