Electrochemical co-deposition of magnesium based alloy from molten salts

Magnesium based alloys with aluminum and zinc were obtained through electrochemical co-deposition from LiCl-NaCl-MgCl2 melt. The possibility of electrochemical co-deposition was discussed in detail by electro-analytical methods including cyclic voltametry,square wave voltametry,and chronopotentiometry. The co-deposition happens when the concentration of aluminum and zinc ions is kept at low value and the current density is high enough. The components of alloy elements can be controlled by fixing the components of the feeding salts. A laboratory experiment of the preparation by step-current co-deposition was also performed and certain compositions of the Mg-Al,and Mg-Zn were obtained. The alloys obtained from the co-deposition show a typical as-cast microstructure. The best conditions of electrolysis such as temperature,amount of addition and mode of feeding were discussed in detail.

Statistical model for combustion of high-metal magnesium-based hydro-reactive fuel

We investigate experimentally and analytically the combustion behavior of a high-metal magnesium-based hydro- reactive fuel under high temperature gaseous atmosphere. The fuel studied in this paper contains 73% magnesium powders. An experimental system is designed and experiments are carried out in both argon and water vapor atmo- spheres. It is found that the burning surface temperature of the fuel is higher in water vapor than that in argon and both of them are higher than the melting point of magnesium, which indicates the molten state of magnesium particles in the burning surface of the fuel. Based on physical considerations and experimental results, a mathematical one-dimensional model is formulated to describe the combustion behavior of the high-metal magnesium-based hydro-reactive fuel. The model enables the evaluation of the burning surface temperature, the burning rate and the flame standoff distance each as a function of chamber pressure and water vapor concentration. The results predicted by the model show that the burning rate and the surface temperature increase when the chamber pressure and the water vapor concentration increase, which are in agreement with the observed experimental trends.

Comprehensive Utilization of Natural Magnesium-Containing Resources and the Development of MgO-Based Refractories

This paper presents the ways of comprehensive utilization of the natural magnesium containing resources and the trends of the MgO based refractories used in high temperature industries. In the first part, the uses and productions of metal Mg, sorel cement, Mg (OH) 2 fire retardant, light magnesium carbonate, light magnesia and magnesium sulphate are described. In the second part, the developments of MgO based refractories used in steelmaking process, nonferrous metallurgy, cement rotary kiln and waste melting furnace are described from some applied theories, including corrosion resistant and slaking resistant MgO CaO materials, chrome free bricks such as MgO CaO ZrO 2 , MgO MgO Al 2 O 3 , MgO MgO·Al 2 O 3 ZrO 2 , MgO MgO·Al 2 O 3 2MgO ·TiO 2 and MgO FeO·Al 2 O 3 , and MgO containing monolithic refractories etc.

Attack of Limestone Cement-based Material Exposed to Magnesium Sulfate Solution at Low Temperature

Limestone in cement could be a source of CO3^2- needed for thaumasite formation which will result in thanmasite form of sulfate attack （TSA） probably. TSA has more deterioration than ettringite or gypsum form of sulfate attack because it targets the calcium silicate hydrates （C-S-H） which is the main binder phase in all Portland cement-based materials. By means of physical and mechanical property testing as well as erosion phases analysis, magnesium sulfate attack of cement-based material containing 35% limestone powder by mass at 5 ± 2 ℃ is investigated. The compressive strength and flexural strength of mortar specimen immersed in MgSO4 solution increase firstly, then decrease rapidly with the immersing age. Relative dynamic elastic modulus of mortar specimen changes in a phased process. After immersing in MgSO4 solution for 15 weeks, the main erosion phases in paste specimen change from four phases compounds, three phases compounds to two phases compounds from surface to inside. Deterioration course of limestone cement-based material exposed to magnesium sulfate aggressive environment appears progressive damage layer by layer, and every layer probably suffers four stages, which are property strengthening stage, initial degradation stage, thaumasite formation stage and cementation loss stage, respectively.

Microstructure of Cu-based Amorphous Composite Coatings on AZ91D Magnesium Alloy by Laser Cladding

To improve the sliding wear resistance of AZ91D magnesium alloy, Cu-based amorphous composite coatings made of CuaTTi34Zr11Nis and Cu47Ti34Zr11Ni8＋20 wt pct SiC powders were fabricated on AZ91D magnesium alloy by laser cladding, respectively. SEM （scanning electron microscopy）, EDS （energy dispersive X-ray spectroscopy）, XRD （X-ray diffraction） and TEM （transmission electron microscopy） techniques were employed to study the phases of the coatings. The results show that the coatings mainly consist of amorphous phase and different intermetallic compounds. The reason of formation of amorphous phase and the function of SiC particles were explained in details.

骨组织工程镁基支架的制备研究进展

骨组织工程为受损骨、病变骨的治疗提供了重要的途径。如何获得易于骨修复、高强度且具有良好生物相容性的支架,是当前骨组织工程支架应用的技术难点和研究热点之一。支架材料的种类及制备方法是影响骨组织工程结构及性能的主要因素。镁基合金因在生物相容性、降解行为等方面具有突出表现而受到了普遍的关注,被认为是一种前景广阔的骨组织工程支架材料。常见的骨组织工程镁基支架制备方法有熔体发泡法、渗流铸造法、固/气共晶定向凝固法和增材制造法等,然而现有制备方法在孔隙结构精细控制及造孔残留物对镁基支架生物相容性的影响等方面仍需进一步研究。本文综述了骨组织工程镁基支架的制备方法,分析了影响镁基支架孔隙结构和性能的因素,总结了每种制备方法的优缺点,并对未来的研究方向进行了展望。

地聚物混凝土干燥收缩性能及活性氧化镁补偿收缩研究

制备粉煤灰-矿渣基地聚物混凝土,并进行地聚物混凝土28 d抗压强度和干燥收缩测试,探究分析活性氧化镁含量、水玻璃模数、碱当量和矿渣含量对其抗压强度和干燥收缩的影响机理。结果表明:随着活性氧化镁掺量增大,地聚物混凝土28 d抗压强度下降,干燥收缩变形显著减小;与0%(质量分数,下同)活性氧化镁混凝土相比,掺量为3%、6%和9%时混凝土28 d抗压强度分别下降8.0%、8.2%和18.2%,干燥收缩分别减小21.5%、26.4%和38.2%,此外,当活性氧化镁掺量为3%和6%时,不仅有效补偿了干燥收缩,且抗压强度损失较小;随着水玻璃模数升高,地聚物混凝土28 d抗压强度和干燥收缩变形增大;随着碱当量升高,地聚物混凝土28 d抗压强度下降、干燥收缩变形增大;随着矿渣含量增加,地聚物混凝土28 d抗压强度增大、干燥收缩变形减小。综合考虑抗压强度及收缩的要求,建议实际应用中选择高活性、大掺量氧化镁,掺量宜控制在3%~6%。

硅酸镁基胶凝材料的制备与性能研究进展

硅酸镁基胶凝材料是由活性氧化镁和硅质原材料及外加剂按照一定比例混合制得,具有低碳排放、轻质高强、隔热保温等优良特点,受到了国内外学者的广泛关注。主要从原料配比、水化机理及其性能的影响因素综述了硅酸镁基胶凝材料的研究进展,硅酸镁基胶凝材料的性能主要受MgO活性、养护温度、Mg/Si比和外加剂、掺合料掺量的影响。其中MgO活性与Mg/Si比对体系反应产物影响显著,养护温度对反应进程起到了控制作用。概述了当前硅酸镁基胶凝材料存在的问题,并提出了可行的改进措施。

改良的电感耦合等离子体发射光谱(ICP-OES)法测定石灰性土壤中交换性盐基钙、镁、钠、钾

为提升石灰性土壤中交换性盐基钙、镁、钠、钾的分析效率与精确度,笔者采用电感耦合等离子体发射光谱(ICP-OES)技术测定其含量。结果表明,最优条件为用70%乙醇溶液反复淋洗样品,再用pH值为8.5的0.1 mol/L的氯化铵-70%乙醇溶液进行交换处理,蒸干后加入10mL 20%~30%的硝酸溶液进行酸化处理。经此处理,把传统的单标溶液转变为混标配置,选择谱线分别为钙317.933 nm、镁279.553 nm、钠589.592 nm、钾766.491 nm,测得国标样品的加标回收率为98.0%~100.7%,检出限分别为0.008、0.005、0.004、0.007 mg/L。对两个国标样品GBW(E)070337、GBW(E)070341进行验证,测得的相对标准偏差(RSD)为0.29%~0.98%(n=5)。对吉林土壤(样品1)测得的结果与火焰光度计+原子吸收分光光度法测得的结果无显著性差异。结果表明该方法适用于石灰性土壤交换性盐基钙、镁、钠、钾的分析。

鸟粪石基载镁生物炭对干湿交替灌溉水稻产量与品质的影响

鸟粪石(MgNH4PO_(4)·6H2O)普遍存在于镁改性生物炭对废水氮磷去除后的回收产物中,其可以作为缓释肥料使用。为探究鸟粪石基载镁生物炭(struvite-based magnesium modified biochar,MAP-BC)在农田中的应用效果以及对不同灌溉和施肥模式的适用性,该研究依托大田试验,以东研18号(粳稻)为供试材料,设置常规淹灌(ICF)、干湿交替(IAWD)2种灌溉模式,以及常规施肥(conventional fertilization,N_(1)B_(0))、常规施肥+5 t/hm^(2)MAP-BC(conventional fertilization+5 t/hm^(2)MAP-BC,N_(1)B_(1))、常规施肥+10 t/hm^(2)MAP-BC(conventional fertilization+10 t/hm^(2)MAP-BC,N_(1)B_(2))、减施氮磷肥25%+5 t/hm^(2)MAP-BC(25%less nitrogen and phosphate fertilizer+5 t/hm^(2)MAP-BC,N_(3/4)B_(1))和减施氮磷肥25%+10 t/hm^(2)MAP-BC(25%less nitrogen and phosphate fertilizer+10 t/hm^(2)MAP-BC,N_(3/4)B_(2))5种施肥模式。结果表明:与ICF相比,IAWD显著提高了乳熟期叶片叶绿素含量,并显著降低了2021年无效分蘖数(P<0.05);MAP-BC不仅能够高效弥补减施氮磷肥对水稻叶绿素含量的不利影响,还具有一定的超补偿效果;MAPBC中高纯度的鸟粪石组分通过缓释氮磷素,保障了对植株氮磷养分的长期供应。与N_(1)B_(0)相比,N_(3/4)B_(2)不仅可以满足水稻生长后期对氮磷养分的需求,还使穗部吸氮量和吸磷量分别显著增加(P<0.05)4.77%~7.06%和4.26%~12.69%;与N_(1)B_(0)相比,施加10 t/hm^(2)MAP-BC使2a的最高分蘖数和最终分蘖数分别显著增加(P<0.05)6.75%~9.64%和13.16%~16.88%;2 a试验中,在IAWD模式下,与N_(1)B_(0)相比,N_(1)B_(1)和N_(1)B_(2)的产量分别显著提高(P<0.05)了7.66%~8.43%和11.49%~12.64%,并且10 t/hm^(2)的MAP-BC可以弥补减施25%氮磷肥对产量造成的不利影响;IAWD模式下N_(3/4)B_(1)和N_(3/4)B_(2)可以显著降低消减值、垩白粒率和垩白度,显著提高崩解值,从而显著改善(P<0.05)水稻外观品质与食味值;此外,N_(1)B_(1)和N_(1)B_(2)较N_(1)B_(0)处理显著提高(P<0.05)稻米蛋白含量2.66%和5.79%,表明施用MAP-BC有助于改善稻米的营养品质。因此,在IAWD模式下减施氮磷肥25%配施10 t/hm^(2)MAP-BC可在节水条件下实现减施氮磷肥、增产、提质,从而为水稻绿色高效生产提供理论依据。

改性镁基水滑石制备及其对金黄色葡萄球菌的活性抑制研究

利用成核晶化法制备了镁基水滑石(MAL),天门冬氨酸(ASP)负载水滑石(MALA)及ASP、Ag^(+)共同负载的水滑石(MALAA),通过X射线衍射和透射电子显微镜等手段对其结构和形貌进行表征,ASP和Ag+均成功负载到MAL上且形貌发生变化.采用菌落计数法测试质量浓度对不同材料抑制金黄色葡萄球菌(S.aureus)生长的影响,结果表明,当质量浓度为4 mg·mL^(−1)时,MAL对S.aureus的抑制率仅为5.8%,而MALAA的抑菌率达到99.7%.通过电感耦合等离子体和紫外可见分光光度计等技术分析改性镁基水滑石的抑菌机制.改性镁基水滑石MALA通过改变其形貌、增大与细菌的接触面积并利用静电作用吸附在带负电的S.aureus上.Ag^(+)的引入进一步增加二者的电势差,促进S.aureus细胞膜破裂,细菌细胞膜的完整性下降,导致细胞外的金属离子(K^(+)、Ca^(2+)、Mg^(2+))含量、蛋白质含量均有显著提升,MALAA具有更好的抑菌效果.该类材料有望应用于对微生物安全要求较高的食品、化妆品等包装领域.

可降解镁基金属引导骨再生膜的研究现状与展望

可降解镁基金属引导骨再生(GBR)膜具有良好的机械性能、生物降解性和生物促成骨性能,是治疗颌面部骨缺损的理想植入物。本文对镁基金属引导骨再生膜的现状和未来的研究趋势进行阐述。首先介绍了镁基金属的研究历史及应用领域,随后从镁基金属GBR膜的机械性能、生物相容性和促成骨性能及其机制方面介绍了镁基金属制备GBR膜的应用优势,最后对当前镁基金属GBR膜的局限性及在口腔医学中的应用和展望进行介绍。镁基金属GBR膜在基础和转化研究方面都取得了重要的进展,为治疗口腔颌面部的骨缺损奠定了重要的基础。

碳材料在镁基固态储氢领域中的应用进展

镁基储氢材料因其理论储氢密度高(MgH_(2),7.6%(质量分数))、来源广、成本低的特点,被认为是最具应用前景的固态储氢材料之一。但MgH_(2)的放氢焓值高(75 kJ/mol)、放氢温度高(>380℃),造成其动力学和热力学性能差,限制了在固态储氢领域的应用和发展。近年来,碳材料因结构多样化、可调控性强、比表面积大、力学性能高和电子传输能力强等优势,在镁基储氢材料的掺杂改性、纳米限域等方面应用广泛,可以有效改善吸放氢温度、循环性能和吸放氢活化能等性能指标,并取得了大量成果。本文主要针对碳材料在镁基储氢材料中的研究现状,归纳了碳材料的合成和改性方法,重点阐述了不同维度碳材料在镁基储氢领域的应用进展,并展望了未来的发展方向。

基于文献计量学的镁及镁合金材料领域研究进展

镁合金作为最有潜力的轻量化节能材料和储能材料,其研究发展对中国双碳战略意义重大。本文基于文献计量学系统分析了2019~2023年发表的镁及镁合金相关论文(Web of Science核心合集数据库),分析探讨了镁及镁合金领域热点研究方向。分析表明,在结构镁合金方面,微观组织、力学性能和腐蚀与防护仍是主要研究热点。生物镁材料、镁离子电池和镁基储氢材料正在受到广泛关注。基于目前镁基节能材料和储能材料发展现状,对未来研究重点进行展望。

生物可降解镁基材料在颅颌面外科的应用及其研究进展

作为一种新型骨植入材料,生物可降解镁基材料在颅颌面外科显示出广阔的应用前景。与传统骨植入材料相比,镁具有良好的降解特性、生物相容性、力学特性和成骨特性,其降解产物镁离子具有抗凋亡、抗炎的作用,能够促进骨折和骨缺损部位的愈合。多项研究将生物可降解镁基材料应用于颅颌面部骨内固定、引导骨再生技术、骨替代材料、药物负载、种植体表面涂层等领域,其结果显示该类材料能够为骨愈合提供稳定的支持,并发挥出良好的促进成骨作用。此外,镁在口腔其他领域,如牙组织工程、促进软组织愈合等方面也表现出应用潜能,显示出生物可降解镁基材料具有重要的研究价值。

两种镁盐复配在改性PVC能源线缆中的应用

两种镁基无机矿物粉体是绿色环保的天然产物,分别可以在热稳定性和抑烟性能方面实现更宽区间、更大范围优势互补,采用物理研磨法分别制备了水镁石粉(MH)和不同目数的水菱镁石粉(HM),并尝试将MH复配不同目数的HM粉体添加到聚氯乙烯(PVC)能源电线电缆中制备复合材料。利用极限氧指数、烟密度测试箱、万能力学实验机和热失重仪等对该PVC能源电线电缆的燃烧性能、烟密度、力学性能和热性能等进行了测试,并且使用拉曼光谱仪、扫描电子显微镜和能谱仪对最终的燃烧残炭进行了检测。结果表明,MH复配高目数HM能够在一定程度上提高PVC复合材料的阻燃特性,尤其是最大烟密度和烟密度等级分别下降了33.6%和42.9%;同时,可以有效地提高PVC能源电线电缆的热稳定性,体现在初始降解温度和热解50%时温度分别提高了5.3%和56.5%,且能够大幅提高燃烧后的残炭率,在600℃和800℃分别提升了3.6倍和4.3倍。MH和高目数HM复配添加还能够有效改善残炭的有序化程度,使得残炭更为致密连续,既能够有效地抵抗热流、质流和气流的传递,又能促进MgO在残炭表面的凝聚,有效提升物理阻隔效果。最后,物理法制备高目数镁基粉体价格低廉,综合应用成本低。

Development and experimental validation of kinetic models for the hydrogenation/dehydrogenation of Mg/Al based metal waste for energy storage

With the increased use of renewable energy sources,the need to store large amounts of energy will become increasingly important in the near future.A cost efficient possibility is to use the reaction of recycled Mg waste with hydrogen as thermo-chemical energy storage.Owing to the high reaction enthalpy,the moderate pressure and appropriate temperature conditions,the broad abundance and the recyclability,the Mg/Al alloy is perfectly suitable for this purpose.As further development of a previous work,in which the performance of recycled Mg/Al waste was presented,a kinetic model for hydro-and dehydrogenation is derived in this study.Temperature and pressure dependencies are determined,as well as the rate limiting step of the reaction.First experiments are carried out in an autoclave with a scaled-up powder mass,which is also used to validate the model by simulating the geometry with the scaled-up experiments at different conditions.

不同催化剂对镁基合金吸放氢动力学影响的研究进展

文章主要综述了不同催化剂对镁基合金吸放氢速率的影响,通过研究发现,金属复合催化剂催化效率最佳,比如MoNi合金纳米粒子表现出色的催化效果,甚至比大多数先进的Ti基催化剂效果更好,并且在简短时间内释放出高达6.7%的氢。复合材料催化剂的效果也相当显著,不仅可以缩短脱氢时间,同时降低反应活化能。

卡瓦下座用表面改性可溶性镁合金耐腐蚀性能研究

采用可溶性镁合金制作的节流器卡瓦下座,在井下服役过程中常因其降解速率过快而引起节流器失效,为此对可溶性镁合金表面进行了改性。为了解可溶性镁合金表面改性后的耐腐蚀性能,采用扫描电子显微镜观察了表面改性镁合金腐蚀前后表面的微观结构,采用X射线衍射仪和红外光谱仪分析了表面改性镁合金表腐蚀前后的物相结构,通过电化学试验和浸泡失重试验评价了其在pH值为3.0,7.2和9.0模拟井液中的耐腐蚀性能。与镁合金相比,在不同pH值的模拟井液中,表面改性镁合金的腐蚀电位均正移了约1.1 V,腐蚀电流密度均降低了3个数量级,腐蚀速率均降低了约3 mm/a;与pH值为7.2的模拟井液相比,在pH值为3.0的模拟井液中,表面改性镁合金的电荷转移电阻从9.13×10^(6)Ω·cm^(2)降至1.91×10^(6)Ω·cm^(2)。研究表明,与镁合金相比,表面改性镁合金在pH值为3.0,7.2和9.0模拟井液中的耐腐蚀性能均显著提高,但其在酸性模拟井液中的耐腐蚀性能大程度降低,易降解。对表面改性镁合金卡瓦下座节流器进行了现场试验,试验表明,表面改性镁合金卡瓦下座的承压性能、耐腐蚀性能满足要求,且易于打捞。研究和现场试验结果均表明,表面改性镁合金的耐腐蚀性能满足可溶性卡瓦下座的要求,为其应用于井下节流器提供了依据。

AZ31镁合金表面磁控溅射铁基复合涂层的耐蚀性和生物相容性

采用射频磁控溅射方法在AZ31镁合金表面制备铁基复合涂层。借助XRD、XPS及SEM对涂层的物相、元素组成和微观形貌进行表征,采用模拟体液浸泡和电化学测试手段检测涂层的耐蚀性。结果显示,相较于AZ31基体,复合涂层AZ31的腐蚀电位提升了约170 mV,腐蚀电流密度则降低了2个数量级。将样品在RPMI1640培养基中的浸提液与人脐静脉内皮细胞(HUVEC)进行共培养,通过CCK-8实验评价其细胞毒性,发现复合涂层AZ31的毒性最小,内皮细胞具有较高的增殖率,铁基复合涂层AZ31镁合金具有良好的耐蚀性和生物相容性。