magnesium

摘要： The roles played by divalent cations(calcium,magnesium and iron)of rock minerals in the efficiency of mineral carbonation have been investigated.Statistical modeling with Artificial Neural Network(ANN)having configuration ANN[17-4-1]shows that carbonation efficiency largely increases as the quantity of calcium content increases.Averagely,there is approximately 5%rise in the original efficiency for 10%increase in the quantity of calcium.This changes to 3.4%and 1.6%increases in efficiency,relative to the original efficiency for 20%and 30%increases in calcium content,respectively.Iron content of minerals offers clear positive correlation to the carbonation efficiency.From the global average,there is approximately 17%rise in the original efficiency for 10%increase in the quantity of iron.This increases to 29%and 41%over the original efficiency for 20%and 30%increases in iron content,respectively..The influence of magnesium was found to be mainly negatively correlated to carbonation efficiency,after exceeding an unknown threshold.The global average of the efficiency changes with magnesium content results in original efficiency rising by 2%at 10%quantity increase and then reduces by 3%and 9%for 20%and 30%increase in magnesium quantity,respectively,relative to the original efficiency.Thus,iron compounds are found to be most potent of the divalent cations in carbonation reaction while calcium and magnesium content should maintain a threshold ratio with silica content for improved efficiency.

摘要： BACKGROUND Oxidative stress results in the production of excess reactive oxygen species(ROS)and triggers hippocampal neuronal damage as well as occupies a key role in the pathological mechanisms of neurodegenerative disorders such as Alzheimer’s disease(AD).A recent study confirmed that magnesium had an inhibitory effect against oxidative stress-related malondialdehyde in vitro.However,whether Magnesium-L-threonate(MgT)is capable of suppressing oxidative stress damage in amyloidβ(Aβ)_(25-35)-treated HT22 cells and the AD mouse model still remains to be investigated.AIM To explore the neuroprotective effect of MgT against oxidative stress injury in vitro and in vivo,and investigate the mechanism.METHODS Aβ_(25-35)-induced HT22 cells were preconditioned with MgT for 12 h.APPswe/PS1dE9(APP/PS1)mice were orally administered with MgT daily for 3 mo.After MgT treatment,the viability of Aβ_(25-35)-treated HT22 cells was determined via conducting cell counting kit-8 test and the cognition of APP/PS1 mice was measured through the Morris Water Maze.Flow cytometry experiments were applied to assess the ROS levels of HT22 cells and measure the apoptosis rate of HT22 cells or hippocampal neurons.Expression of B-cell lymphoma 2(Bcl-2),Bcl-2-associated X(Bax),hypoxiainducible factor(HIF)-1α,NADPH oxidase(NOX)4,Aβ_(1-42) and phosphatidylinositol-3-kinase(PI3K)/protein kinase B(Akt)pathway proteins was quantified by Western blot.RESULTS In vitro data confirmed that Aβ_(25-35)-induced HT22 cells had a significantly lower cell viability,higher ROS level and higher apoptosis rates compared with those of control cells(all P<0.001).MgT prevented the Aβ_(25-35)-triggered oxidative stress damage by elevating viability and decreasing ROS formation and apoptosis of HT22 cells(all P<0.001).APP/PS1 mice exhibited worse cognitive performance and higher apoptosis rate of hippocampal neurons than wild-type(WT)mice(all P<0.01).Meanwhile,significant higher expression of Aβ_(1-42) and NOX4 proteins was detected in APP/PS1 mice than those of WT mice(both P<0.01).MgT also ameliorated the cognitive deficit,suppressed the apoptosis of hippocampal neuron and downregulated the expression of Aβ_(1-42) and NOX4 proteins in APP/PS1 mouse(all P<0.05).Moreover,MgT intervention significantly downregulated HIF-1αand Bax,upregulated Bcl-2 and activated the PI3K/Akt pathway both in vitro and in vivo(all P<0.05).CONCLUSION MgT exhibits neuroprotective effects against oxidative stress and hippocampal neuronal apoptosis in Aβ_(25-35)-treated HT22 cells and APP/PS1 mice.

摘要： In this work,the stable layer structure of serpentine,which seriously restricts the extraction of magnesium,was broken down,and a nearly 94%leaching efficiency of Mg was obtained by adding 5%fluorite powder.Compared with the system without fluorite,the Mg leaching efficiency increased by 36.42%.This result was achieved because the complexation of fluorinion(F
)with Si in serpentine promoted a distorted tetrahedral orientation,which led to a loose crystal structure of serpentine and contributed to exposing more Mg for a remarkable increase in Mg recovery.It is suggested that fluorite powder could replace expensive assisted reagents in the leaching process,which would markedly decreased the cost.Moreover,an energy-efficient‘‘solvent displacement crystallization”(SDC)method was employed to efficiently recover magnesium(99.04%)from pregnant solutions.At the same time,the reuse of fluorinecontaining solutions was explored.

摘要： Magnesium (Mg) is one of the most plentiful elements in the Earth’s crust and seawater. It possesses low density, high specific strength, high standard potential, and good biocompatibility. In addition, magnesium hydride shows the highest energy density of all reversible metallic hydrides applicable for hydrogen storage. These unique features make Mg and its alloys a class of very promising material for structural and functional applications pertaining to aerospace, transportation, and biomedical and energy sectors. Wide applications of Mg alloys are thus deemed to significantly contribute to the ever-increasing environmental problems and energy challenges in the worldwide.

摘要： The effects of multipass friction stir processing(FSP)and Mg powder addition on the different microstructure parts,including the stir zone(SZ),heat-affected zone(HAZ),and thermomechanically affected zone(TMAZ)of Al 1050 alloy were investigated.Microstructural observations revealed that with the increase in the number of FSP passes,the grain size of the SZ decreased in the non-composite and composite samples,whereas that of the TMAZ and HAZ increased in the non-composite sample.Furthermore,the addition of Mg powder resulted in considerable grain refinement,and increasing the number of the FSP passes resulted in a more uniform distribution of Al-Mg intermetallic compounds in the in-situ composite sample.Results of the tensile test showed that the non-composite sample that underwent four passes of FSP exhibited a higher elongation percentage and a ductile fracture in comparison with those of the base metal and the composite sample.However,this sample exhibited a brittle fracture and a higher tensile strength in comparison with the base metal and the non-composite sample.The fabrication of composite samples resulted in a remarkable enhancement in hardness in comparison with the base metal and the non-composite samples that underwent FSP.

摘要： This work investigates the effect of solid solution on ductility and on the activation of individual deformation mechanisms at moderate temperatures and at quasi-static strain rates in Mg-Zn and Mg-Al alloys. With that aim, four solid solution Mg-Zn and Mg-Al binary alloy ingots containing 1 and 2 wt.% solute atoms were subjected to hot rolling and subsequent annealing to generate polycrystals with similar average grain size and basal-type texture for each composition. The activity of the different slip systems after tensile testing at 150°C and at 250°C was evaluated in pure Mg and in the alloys by EBSD-assisted slip trace analysis. In addition, segregation of Zn and Al atoms at grain boundaries during the thermo-mechanical processing was characterized by HAADF-STEM and EDX. It was found that while the addition of Al and Zn atoms to pure Mg does not lead to major changes in the mechanical strength at the investigated temperatures, it does enhance ductility significantly, especially at 250°C. Our results show that this increase in ductility cannot be attributed to a higher activation of non-basal systems in the alloys, as reported earlier, as the incidence of non-basal systems is indeed considerably higher in pure Mg. This work suggests, on the contrary, that the ductility increase may be attributed to the presence of a more homogenous basal activity in the alloys due to a lower degree of orientation clustering, to grain boundary solute segregation, and to a higher slip diffusivity at grain interiors.

摘要： A new friction-based riveting technique, Rotating Hammer Riveting(RHR), is demonstrated to fully form AZ31 Mg rivet heads in a mere 0.23 s. Heat and pressure generated through severe plastic deformation during the process was sufficient to form the Mg rivet head without the need for a pre-heating operation. Due to preliminary twinning and followed by dynamic recrystallization, AZ31 Mg grains in the rivet head were refined during RHR, which enhance the formability of Mg rivets by triggering grain boundary sliding and reducing plastic anisotropy of Mg. In addition, RHR joints showed a metallurgical bond between the rivet head and top AZ31 Mg sheet, which eliminates a significant pathway for corrosion.

摘要： Mg and its alloys are suitable choices for implant materials due to their biodegradability and biocompatibility features. However, the high electrochemical activity of this family of biomaterials results in their fast degradation and severe corrosion in the physiological environment,producing hydrogen(H;) gas, and therefore increasing the p H of the environment. To meet the clinical requirements, the degradation rate of Mg biomaterials needs to be reduced. Nevertheless, higher corrosion resistance of Mg results in a low alkaline p H, weakening the antibacterial activity. Therefore, while the rapid degradation problem of Mg-based biomaterials needs to be addressed, good antibacterial properties are also necessary. By using the plasma electrolytic oxidation(PEO) surface modification technique, the antibacterial activity of Mg and its alloys can be enhanced while maintaining their corrosion protection properties at a high level. Throughout the PEO process, introducing antibacterial agents into solutions results in a major increase in antibacterial activity of the coatings. Moreover, post-or pre-processing on PEO coatings can provide better protection against bacteria. In this review, the antibacterial activity of PEO coatings applied on Mg and also its alloys will be discussed in more detail.

摘要： Even though Mg alloys containing Mn and rare earth elements lead to higher ductility and lower yield asymmetry due to the weak texture after extrusion, plastic instability, commonly known as the Portevin–Le Chatelier(PLC) effect, causes unexpected fragility in the service environment. In the present study, the PLC phenomenon and texture development during the deformation of Mg-Mn and Mg-Mn-Nd extruded alloys were investigated under various temperatures and strain rates. The addition of Nd causes not only texture weakening but also severe PLC phenomenon. The PLC phenomenon was significantly affected by the temperatures and the strain rates, which causes a difference in mechanical properties and development of texture. In the conditions of high temperature and low strain rate, the strength increased while the elongation decreased significantly, and obvious PLC phenomenon with severe serration and negative strain rate sensitivity. The initial texture was maintained even after deformation only under severe PLC conditions, and this is due to the restriction of basal slip and suppression of lattice rotation in PLC conditions. The series of results indicate that the PLC phenomenon causes a reduction of formability even at high temperature.

摘要： Magnesium(Mg)has emerged as one of the third-generation biomaterials for regeneration and support of functional bone tissue.Mg is a better choice over permanent implants such as titanium,stainless steel,cobalt-chrome as magnesium is biodegradable and does not require a second surgery for its removal after bone tissue recovery.It also reduces the risk of stress shielding as its elastic modulus is closer to human bone in comparison to permanent implants and other biodegradable metallic implants based on Iron and Zinc.Most importantly,Mg is osteoconductive thus stimulates new bone formation and possess anti-bacterial properties hence reducing the risk of failure due to infection.Despite its advantages,a major concern with pure Mg is its rapid bio-corrosion in presence of body fluids due to which the mechanical integrity of the implant deteriorates before healing of the tissue is complete.Mechanical properties of Mg-based implants can be enhanced by mechanical processing,alloying,and topology optimization.To reduce the corrosion/degradation rate,Mg has been alloyed with metals,reinforced with ceramics,and surface coatings have been applied so that the degradation rate of Mg-based implant matches with that of healing rate of bone tissue.The present review discusses the effect of alloying elements and reinforcing ceramics on microstructure,mechanical,and corrosion properties of Mg-based orthopedic implants.In addition,the biocompatibility of Mg-based alloys,composites,and coatings applied on Mg implants has been highlighted.Further,different methods of fabricating porous implants have been highlighted as making the implant porous facilitates the growth of new bone tissue through the pores.