Ultra-light Alloys Research Articles

Effects of heat input on microstructures and mechanical properties of LAZ931 magnesium-lithium alloy in High-Speed TIG welding

LAZ931 magnesium-lithium (Mg-Li) alloy is a novel ultra-light alloy material. This research investigates the Tungsten Inert Gas (TIG) welding process of a 2.15 mm thick LAZ931 magnesium-lithium alloy thin plate without wire filling. The objectives are to determine the appropriate heat input range, achieve welded joints with good forming quality, and examine the effect of heat input on the microstructure and mechanical properties of the welded joints. The results show that post-TIG welding at high welding speed, the melt width of the entire welded joints is very narrow only about 9 mm, and a small amount of MgLiAl2 (θ) phase and AlLi (γ) phase precipitate in the weld seam zone(WSZ), while a significant amount of θ phase precipitates in the heat-affected zone (HAZ), making the HAZ the highest in strength due to precipitation strengthening. With increasing heat input, the quantity of θ phase decreases, resulting in reduced strength and hardness but increased plasticity in the HAZ. The highest hardness in the HAZ was measured at 87.6 HV, with the base material (BM) exhibiting the lowest hardness. The tensile strength of the joint reaches 163.2 MPa, with an elongation of 23.9 %, and the fracture mode is a mixed ductile–brittle fracture.

Operando-XRD of Electrochemical Reactors for Selective Li+ Extraction from Brines and Seawater

In times of rising demand of Li for use in Li-ion batteries (LIBs), and ensuring its supply for aluminum electrolysis, ultralight alloys, optics, synthesis, nuclear research, and pharmaceuticals, it is essential to simplify the processing of Li sources in a sustainable manner. Current extraction from ores is complex and requires large energy input while generating high amounts of waste. This causes the danger of making Li a limited resource and even more expensive.[1] A new promising way is the electrochemical extraction of Li by desalination batteries (DBs) from brines or seawater[2]. Thereby, selective extraction of ions can be promoted by the chemistry of the electrode material, e.g., by using FePO4. To further enhance the selectivity, potentiostatic application proved to be useful[3]. DBs are superior to other extraction methods in terms of energy efficiency, and waste generation. Still, varying Li+ concentrations in brines[1b], competitive intercalation of other cations with similar size - especially Na+ [2] -, and degradative effects of anions[4], H2O, and O2 [5] are major challenges to overcome for DBs with FePO4.In this contribution, we focus on the selective extraction of Li+ using FePO4 electrodes by specifically-designed multi-step potentiostatic application. Results are shown for salt solutions containing a mixture of Na+/Li+, and artificial seawater. It is vital to understand the atomic-scale processes so that the electrodes, and electrochemical parameters can be optimized. Therefore, we used operando high-energy X-ray diffraction (HEXRD) microscopy to investigate the crystal structure of FePO4 during the electrochemical process. The experiments showed that the energy barrier for Na+ (de)intercalation was higher than that of Li+ during galvanostatic cycling, i.e., FePO4 is selective for Li+. Using a multi-step potentiostatic procedure, the (de)intercalation process could be enhanced, as evident from our HEXRD results and simultaneous conductivity measurements. Our tentative interpretation is that Li+ is highly selectively (de)intercalated, although electrochemical signatures hinted on a two-step process during deintercalation, which may indicate the intercalation of Na+. To selectively deintercalate the remaining Na+ over Li+, we further optimized the applied potentials. During galvanostatic cycling in artificial seawater, the (de)intercalation potentials were at more positive and more negative potentials, respectively, likely caused by the variety of cations. We expect that our results contribute to the design of high-performance DBs and inspire the exploration of further systems based on our proposed multi-step process.

Modelling of photoactivation process to plasma-electrolyte coating on magnesium alloy

The possibility of using alloys based on magnesium modified by plasma-electrolyte treatment for photocatalysis purposes is considered. A brief description of the nature of the occurrence of photoactivatable centers in oxides is given; examples of similar studies in the field are provided. Under the assumption of photogeneration of plasmon and exciton quasiparticles, a conceptual model of photosensitization of dielectric oxides has been proposed. Using simulation software COMSOL Multiphysics, numerical calculations were performed to determine the conditions for the occurrence of resonant phenomena in nanoscale MgO. The results of experiments to evaluation of the photocatalytic ability of the Mg–8Li–1Al-0.6Ce-0.3Y ultralight alloy after plasma-electrolyte treatment are presented.

Photocatalytic Ability of Coating Synthesized in Electrolyte Plasma on the Surface of an Ultra-Light Magnesium Alloy

A possibility of using alloys based on magnesium modified by plasma-electrolyte treatment for photo-catalysis purposes is considered. A brief description of the nature of photoactivatable centers occurrence in oxides is given, examples of similar studies in the area are provided. Results of own experiments on the determination of the photocatalytic ability of an ultralight alloy with composition Mg-8Li-1Al-0.6Ce-0.3Y after plasma-electrolyte treatment are presented. A conceptual model of induced photocatalysis in dielectric oxides is proposed.

Effects of heat input on microstructures and mechanical properties of LAZ931 magnesium-lithium alloy by CO2 laser welding

LAZ931 magnesium-lithium (Mg-Li) alloy is a novel ultra-light alloy material. It is added with important alloying elements aluminum and zinc to form a quaternary Mg-Li alloy, which has high strength and low density, and improved mechanical properties. Due to the natural aging softening of multiphase Mg-Li alloys, their strength will decrease at room temperature. The welding research of LAZ931 Mg-Li alloy is only friction stir welding, and there is no report on laser welding. The industrial circle has put forward an increasingly urgent demand for the welding technique of LAZ931 Mg-Li alloy. CO2 laser welding of LAZ931 Mg-Li alloy with 2.15 mm in thickness was studied to explore a reasonable heat input range. CO2 laser welding can make the welded seam zone(WSZ) grain significantly refined. The base metal(BM) softening phase disappears after laser welding. Dispersion strengthening of the precipitated phase in the heat-affected zone(HAZ), resulting in enhanced strength of the HAZ. The WSZ is mainly composed of fine needle-like α-phase, granular α-phase, β-phase, and granular precipitation phase, and the grain interior and the grain boundary distribution of α-phase along β-phase; The width of the HAZ is narrow, and it partially melted to form a coarse needle-like α phase. The tensile strength of the welded joints obtained by laser welding is all fractured in the BM, indicating that improved strength after laser welding, and with the increase in heat input, the ultimate tensile strength and elongation rates of the welded joints show a descending trend; The microhardness of the WSZ is the highest, followed by the HAZ, and the microhardness of the BM is the lowest, and the microhardness of the WSZ is higher than that of the BMs under different heat inputs. With the increase in heat input, the WSZ grain becomes coarse, which in turn makes the mechanical properties of the welded joint decrease. The research results can provide a theoretical basis and technical support for the engineering application of this type of ultra-light Mg-Li alloy.

Phase transformations in an ultralight BCC Mg alloy during anisothermal ageing

Mg-Li-Al alloys with a body-centred cubic (BCC) structure can exhibit exceptional specific strengths in combination with excellent ductility and corrosion resistance. In general, the strength of these alloys is very sensitive to the processing temperature due to the occurrence of various phase transformations. Although different phases have been identified in these alloys, their corresponding transformation mechanisms and unique role played in controlling the mechanical properties have never been studied in depth. In this work, we identified the phase transformation sequence by in-situ synchrotron X-ray diffraction. Moreover, we investigated the evolution of precipitation and their morphology using transmission and scanning electron microscopy, together with simulations based on the phase field modelling and first-principles calculations. Phase transformation sequence of Al-rich zone → θ (D03−Mg3Al) → AlLi was confirmed during anisothermal ageing. A braided structure resulting from spinodal decomposition was found to be the optimized microstructure for achieving the peak strength. Nanocrystalline α-Mg phase at the interface between θ and the matrix was identified as the main reason for softening in the alloy. The core-shell model for θ → AlLi transformation is observed and verified. Our findings deepen the understanding of BCC Mg-Li-Al alloys and pave a pathway to develop new generation of ultralight alloys with stronger strength and better stability.

Heat transfer coefficients of Mg70Li30 ultralight alloy

Heat transfer coefficients of Mg70Li30 ultralight alloy

Features of anodic plasma electrolytic treatment of an ultra-light alloy of the Mg-Li system in an aqueous electrolyte

The possibility of plasma electrolytic treatment of an alloy of the Mg-Li system in an aqueous solution of ammonium chloride, ammonium nitrate and boric acid has been studied. The specific features of the process in the voltage range from 10 to 600 V are determined. The current-voltage and voltage-temperature characteristics during alloy processing are shown, as well as the effect of the processing time on the temperature of the samples. Plasma electrolytic boronitriding of the alloy can be carried out to study the efficiency of the technology at avoltage of 240 V, which corresponds to a sample temperature of 300 ± 10 °C.

Protective and Thermophysical Characteristics of Plasma-Electrolytic Coatings on the Ultralight Magnesium Alloy

Abstract Magnesium alloys are now widely used for various purposes due to their unique properties despite the significant disadvantage associated with low corrosion resistance. The plasma-electrolytic oxidation (PEO), which allows the formation of ceramic coatings on the surface of magnesium alloys, is the most advanced and effective method for their protection. But first, PEO process of magnesium alloys has some difficulties, and second, PEO coatings affect the thermophysical characteristics of the modified materials; in particular, they reduce thermal diffusivity. The presented work is devoted to the development of the technological parameters for formation of protective coating on the ultralight alloy Mg–8Li–1Al–0.6Ce–0.3Y by the PEO method. The results analyses of electrolytes acidity and specific electrical conductivity before and after PEO process and also investigation data of the coatings structure and surface morphology are presented. An integral assessment of the ability of thermal diffusivity and corrosion resistance of the modified alloy was made. Studying of protective and thermophysical characteristics of the obtained coating showed that it provides a sufficiently high corrosion protection, despite the relatively small thickness, and the presence of pores and slightly (not more than 5%) reduces the thermal diffusivity of the magnesium ultralight alloy.

Extrusion of Light and Ultralight Alloys with Liquid Nitrogen Conformal Cooled Dies: Process Analysis and Simulation

Extrusion of Light and Ultralight Alloys with Liquid Nitrogen Conformal Cooled Dies: Process Analysis and Simulation

Investigation of Mg\u2013xLi\u2013Zn alloys for potential application of biodegradable bone implant materials

Implant therapy after osteosarcoma surgery is a major clinical challenge currently, especially the requirements for mechanical properties, degradability of the implants, and their inhibition of residual tumor cells. Biodegradable magnesium (Mg) alloy as medical bone implant material has full advantages and huge potential development space. Wherein, Mg–lithium (Li) based alloy, as an ultra-light alloy, has good properties for implants under certain conditions, and both Mg and Li have inhibitory effects on tumor cells. Therefore, Mg–Li alloy is expected to be applied in bone implant materials for mechanical supporting and inhibiting tumor cells simultaneously. In this contribution, the Mg–xLi–Zinc (Zn) series alloys (x = 3 wt%, 6 wt%, 9 wt%) were prepared to study the influence of different elements and contents on the structure and properties of the alloy, and the biosafety of the alloy was also evaluated. Our data showed that the yield strength, tensile strength, and elongation of as-cast Mg–xLi–Zn alloy were higher than those of as-cast Mg–Zn alloy; Mg–xLi–Zn alloy can kill osteosarcoma cells (MG-63) in a concentration-dependent manner, wherein Mg–3Li–Zn alloy (x = 3 wt%) and Mg–6Li–Zn alloy (x = 6 wt%) promoted the proliferation of osteoblasts (MC3T3) at a certain concentration of Li. In summary, our study demonstrated that the Mg–6Li–Zn alloy could be potentially applied as a material of orthopedic implant for its excellent multi-functions.

Coating effect on thermal-physical and corrosion characteristics of ultralight Mg-based alloy

Due to its unique properties, magnesium alloys at present are widely used in aircraft and defence technologies, despite the significant drawback as low corrosion resistance. The most effective method of alloys protection is micro-arc oxidation (MAO). But firstly, the alloys oxidation has a number of difficulties, and secondly, the ceramic coatings have an effect on thermal-physical characteristics of modified material. The presented report devotes of the developed technological mode of a protective coating forming on the ultralight alloy Mg-8Li-1Al-0.6Ce by the MAO method. The role of cathodic polarization at the treatment was mentioned. An integrated assessment of the ability to thermal conductivity and corrosion resistance of the modified alloy was made. Despite the relatively small thickness and the presence of pores, the resulting coating provides sufficiently high corrosion resistance; the formed coating slightly (not more than 5%) reduces the thermal conductivity of the ultralight Mg alloy.

New quaternary carbide Mg1.52Li0.24Al0.24C0.86 as a disorder derivative of the family of hexagonal close-packed (hcp) structures and the effect of structure modification on the electrochemical behaviour of the electrode.

Magnesium alloys are the basis for the creation of light and ultra-light alloys. They have attracted attention as potential materials for the accumulation and storage of hydrogen, as well as electrode materials in metal-hydride and magnesium-ion batteries. The search for new metal hydrides has involved magnesium alloys with rare-earth transition metals and doped by p- or s-elements. The synthesis and characterization of a new quaternary carbide, namely dimagnesium lithium aluminium carbide, Mg1.52Li0.24Al0.24C0.86, belonging to the family of hexagonal close-packed (hcp) structures, are reported. The title compound crystallizes with hexagonal symmetry (space group P-6m2), where two sites with -6m2 symmetry and one site with 3m. symmetry are occupied by an Mg/Li statistical mixture (in Wyckoff position 1a), an Mg/Al statistical mixture (in position 1d) and C atoms (2i). The cuboctahedral coordination is typical for Mg/Li and Mg/Al, and the C atom is enclosed in an octahedron. Electronic structure calculations were used for elucidation of the ability of lithium or aluminium to substitute magnesium, and evaluation of the nature of the bonding between atoms. The presence of carbon in the carbide phase improves the corrosion resistance of the Mg1.52Li0.24Al0.24C0.86 alloy compared to the ternary Mg1.52Li0.24Al0.24 alloy and Mg.

Microstructure of Anodic Films Grown on Magnesium-Lithium-Yttrium Ultra Light Alloy

Microstructure of Anodic Films Grown on Magnesium-Lithium-Yttrium Ultra Light Alloy

Development of ultra light magnesium-lithium alloys

Magnesium-lithium alloys are among the lowest density metallic materials. Addition of lithium, with a relative density of 0·53, in magnesium reduces the density of the alloy significantly. Furthermore, addition of nearly 11 wt.% lithium converts hexagonal close packed structure of pure magnesium to a body centered cubic lattice, markedly improving formability of the alloy. The development of these alloys, however, had been hampered due to the high reactivity of lithium and magnesium in the molten state and also, due to poor creep resistance and instability of mechanical properties at room temperature. In an attempt to indigenize these ultra light alloys for possible applications in Indian satellite programme, detailed research work was initiated in DMRL. The difficulties associated with producing sound cast ingots have been overcome by controlling melting and casting parameters of these alloys. Extensive work has been done on structure-property correlation of alloys with varying lithium content and minor alloying additions. Based on these work, advanced magnesium-lithium alloys have been developed with improved tensile properties, room temperature stability and creep resistance. Wrought products (plates/sheets) of magnesium-lithium alloy have been supplied to ISAC, Bangalore and are being used in their INSAT-2 programme. This paper describes the systematic studies carried out in the laboratory to indigenize these ultra light alloys.

Large-scale Space Engineering

The absence of a corrosive environment in space may permit the structural use of ultralight reactive metals whose terrestrial application is limited. Alloys based on magnesium-lithium in particular could enable a substantial reduction in the payload mass required for large space structures. Magnesiunllithium alloys are about half as dense as aluminum alloys. The direct in-situ preparation of shaped structural units by· metal foaming techniques appears to offer particular advantages in increasing structural stiffness. The tendency for elements to oxidize more readily as they decrease in density is illustrated for twenty-five elements in Figure 1. Aluminum alloys are currently the materials of choice for space satellites. The corrosion-free nature of the space environment, however, allows consideration of ultralight alloys. For large-scale space applications which do not involve crew quarters or other oxygen or water vapor containing environments, such an increased tendency to oxidize might not be as important as the concomitant reduction in density. There are five metallic elements-Li, K, Ca, Na, and Rb-which are less dense even than magnesium. In pure form, these elements are all quite soft and, indeed, little or no metallurgical effort has been aimed at improving their strengths. Such an effort WOUld, in any case, be made difficult by their high reactivity and concomitant low solubility for other elements. As it happens, however, lithium and magnesium do show substantial solubility. Beyond approximately 10 wt% lithium, magnesium-lithium alloys show a body-centered cubic structure which enormously improves the fabrication characteristics of these alloys. Above approximately 30 wt% lithium, however, the liquidus temperature decreases to below 250C. Because of this solubility, commercial alloys were at one time developed, as, for example, LA 141 A, which consisted of magnesium with 14 weight percent of lithium and 1 of magnesium with 14 weight percent of lithium and 1 weight percent of aluminum. 1 This alloy has a density of only 1.35 g/cm3 and, after heattreatment to produce age-hardening via the preCipitation of MgLi2AI, showed an ultimate tensile strength of 310 MPa (45Ksi). Importantly, the modulus of elasticity of this alloy (42. 7 GPa, 6.2 x 10 psi) is closer to that of magnesium (45 GPa, 6.5. x 10 psi) than to that of lithium (4.9 GPa, 0.7 x 10 psi). Regarding corrosion properties, if the rate of chemical reaction were assumed to be proportional to gas pressure, then the 10-11 decrease in pressure that occurs in going from sea level to 300 km would effectively reduce any reaction rate to a very low level. Materials that were rapidly and extensively attacked at sea level would be only minimally affected at 300 km. Because the elastic modulus of ultralight reactive metals, even magnesium-lithium, is relatively low, it could be beneficial to increase structure stiffness by increasing the crosssectional area of structural components by the use of metal foams. ConSider, for example, a beam of square cross-sectional area. If the cross-sectional area is increased by a factor of ten through foaming and the material modulus were decreased by this same factor, the resulting beam stiffness, as measured by its deflection under load would still be raised by a factor of ten. This increase in stiffness occurs because, for such beams, the second moment of the beam cross-section increases as the square of the cross-sectional area. A comparison of properties on this basis shows that LA 141 A foamed to a density of 0.135 g/cm could produce beams which are, on a stiffness to mass per unit length basis, several times better than those of solid aluminum. Unlike plastic foams, metal foams would not be expected to be affected . by ultraviolet radiation. It is also worth noting that, in the event of orbital failure, the possibility of any material reaching the surface of the earth would be considerably reduced through the use of reactive metals as the material of construction. Finally, on a mass-required basis, early work has shown that the micrometeriod impact resistance of LA 141 A is more than twice that of aluminum and 1.3 times that of magnesium. 1 To test these concepts, a'n experimental payload has been designed and built to be flown as part of the AcnVE ll'~' ~~,-----.---,-----.----,------.-----,----r-'~--'-'---'-'~ +30 "-:.co .80 t +20 No .Mg .s,

The Corrosion of Electron Alloy AM 503 by Leaded Fuels: Part I.—Mechanism of Attack

Tetraethyl lead is a constituent of most fuels of high anti-knock value, but such fuels cause serious corrosion of magnesium-base alloy tanks and may completely penetrate them in a few months. No work on the mechanism of this attack has been published and no satisfactory method for protection exists, so that magnesium-base alloy tanks cannot be used for leaded fuels. Since tanks constructed from an ultra-light alloy would be of advantage for aircraft, experiments have now been carried out to elucidate the mechanism of their corrosion, this work representing the first stage of an attack on the problem of providing protection against such corrosion.