Molybdenum isotope composition of the upper mantle and its origin:insight from mid-ocean ridge basalt

The molybdenum(Mo)isotope system is pivotal in reconstructing marine redox changes throughout Earth’s history and has emerged as a promising tracer for igneous and metamorphic processes.Understanding its composition and variation across major geochemical reservoirs is essential for its application in investigating high-temperature processes.However,there is debate regarding theδ^(98/95)Mo value of the Earth’s mantle,with estimates ranging from sub-chondritic to super-chondritic values.Recent analyses of global mid-ocean ridge basalt(MORB)glasses revealed significantδ^(98/95)Mo variations attributed to mantle heterogeneity,proposing a two-component mixing model to explain the observed variation.Complementary studies confirmed the sub-chondriticδ^(98/95)Mo of the depleted upper mantle,suggesting remixing of subduction-modified oceanic crust as a plausible mechanism.These findings underscore the role of Mo isotopes as effective tracers for understanding dynamic processes associated with mantle-crustal recycling.

Measurement of 2p-3d absorption in a hot molybdenum plasma

We present measurements of the 2p-3d transition opacity of a hot molybdenum-scandium sample with nearly half-vacant molybdenum M-shell configurations.A plastic-tamped molybdenum-scandium foil sample is radiatively heated to high temperature in a compact D-shaped gold Hohlraum driven by∼30 kJ laser energy at the SG-100 kJ laser facility.X rays transmitted through the molybdenum and scandium plasmas are diffracted by crystals and finally recorded by image plates.The electron temperatures in the sample in particular spatial and temporal zones are determined by the K-shell absorption of the scandium plasma.A combination of the IRAD3D view factor code and the MULTI hydrodynamic code is used to simulate the spatial distribution and temporal behavior of the sample temperature and density.The inferred temperature in the molybdenum plasma reaches a average of 138±11 eV.A detailed configuration-accounting calculation of the n=2–3 transition absorption of the molybdenum plasma is compared with experimental measurements and quite good agreement is found.The present measurements provide an opportunity to test opacity models for complicated M-shell configurations.

Robust T_c in element molybdenum up to 160 GPa

Element superconductors with the single atoms provide clean and fundamental platforms for studying superconductivity.Although elements with d electrons are usually not favored by conventional BCS,the record superconducting critical temperature(T_(c))in element scandium(S_(c))has further ignited the intensive attention on transition metals.The element molybdenum(M_o)with a half-full d-orbital is studied in our work,which fills the gap in the study of Mo under high pressure and investigates the pressure dependence of superconductivity.In this work,we exhibit a robust superconductivity of Mo in the pressure range of 5 GPa to 160 GPa via high-pressure electrical transport measurements,the T_(c) varies at a rate of0.013 K/GPa to 8.56 K at 160 GPa.Moreover,the superconductivity is evidenced by the T_(c) shifting to lower temperature under applied magnetic fields,and the upper critical magnetic fields are extrapolated by the WHH equation and GL equation;the results indicate that the maximum upper critical magnetic field is estimated to be 8.24 T at 137 GPa.We further investigate the superconducting mechanism of Mo,the theoretical calculations indicate that the superconductivity can be attributed to the strong coupling between the electrons from the partially filled d band and the phonons from the frequency zone of 200-400 cm^(-1).

Preparation of sodium molybdate from molybdenum concentrate by microwave roasting and alkali leaching

The preparation process of sodium molybdate has the disadvantages of high energy consumption,low thermal efficiency,and high raw material requirement of molybdenum trioxide,in order to realize the green and efficient development of molybdenum concentrate resources,this paper proposes a new process for efficient recovery of molybdenum from molybdenum concentrate and preparation of sodium molybdate by microwave-enhanced roasting and alkali leaching.Thermodynamic analysis indicated the feasibility of oxidation roasting of molybdenum concentrate.The effects of roasting temperature,holding time,and power-to-mass ratio on the oxidation product and leaching product sodium molybdate (Na_(2)MoO_(4)·2H_(2)O) were investigated.Under the optimal process conditions:roasting temperature of 700℃,holding time of 110 min,and power-to-mass ratio of 110 W/g,the molybdenum state of existence was converted from MoS_(2) to Mo O3.The process of preparing sodium molybdate by alkali leaching of molybdenum calcine was investigated,the optimal leaching conditions include a solution concentration of 2.5 mol/L,a liquid-to-solid ratio of 2 mL/g,a leaching temperature of 60℃,and leaching solution termination at pH 8.The optimum conditions result in a leaching rate of sodium molybdate of 96.24%.Meanwhile,the content of sodium molybdate reaches 94.08wt%after leaching and removing impurities.Iron and aluminum impurities can be effectively separated by adjusting the pH of the leaching solution with sodium carbonate solution.This research avoids the shortcomings of the traditional process and utilizes the advantages of microwave metallurgy to prepare high-quality sodium molybdate,which provides a new idea for the highvalue utilization of molybdenum concentrate.

Multiscale confinement nitridation in molybdenum carbide for efficient hydrogen production

The molybdenum carbide(Mo_(2)C)has been regarded as one of the most cost-efficient and stable electrocatalyst for the hydrogen evolution reaction(HER)by the virtue of its Pt-like electronic structures.However,the inherent limitation of high density of empty valence band significantly reduces its catalytic reactivity by reason of strong hydrogen desorption resistance.Herein,we propose a multiscale confinement synthesis method to design the nitrogen-rich Mo_(2)C for modulating the band structure via decomposing the pre-coordination bonded polymer in a pressure-tight tube sealing system.Pre-bonded c/N-Mo in the coordination precursor constructs a micro-confinement space,enabling the homogeneous nitrogenization in-situ happened during the formation of Mo_(2)C.Simultaneously,the evolved gases from the precursor decomposition in tube sealing system establish a macro-confinement environment,preventing the lattice N escape and further endowing a continuous nitridation.Combining the multiscale confinement effects,the nitrogen-rich Mo2C displays as high as 25%N-Mo concentration in carbide lattice,leading to a satisfactory band structure.Accordingly,the constructed nitrogen-rich Mo_(2)C reveals an adorable catalytic activity for HER in both alkaline and acid solution.It is anticipated that the multiscale confinement synthesis strategy presents guideline for the rational design of electrocatalysts and beyond.

基于熔盐堆尾气提取的99Mo生产评估

基于熔盐堆尾气提取99Mo同位素的生产方法引起了广泛的关注,但目前的工作局限于评估堆芯中99Mo的产量,对于其在整个回路中的迁移行为的关注不足。本文建立了一个熔盐堆中的贵金属迁移模型,并基于8 MW熔盐实验堆(Molten-Salt Reactor Experiment,MSRE)进行了贵金属分布验证,而后对MSRE尾气中99Mo粗产品的产量、比活度及运行状态的变化对生产的稳定性的影响进行了分析。结果表明,尾气中的99Mo有较高含量和比活度,移除率增加的工况对99Mo的比活度的影响是有益的,空泡比例及氧化还原电势变化的工况对99Mo的比活度影响不大,该方法可作为一种潜在的99Mo生产备选方案。

Mo添加对WC-Ni硬质合金微结构及性能的影响

采用X射线衍射(XRD)、扫描电子显微镜(SEM)和性能检测等方法研究了不同Mo添加量对WC-Ni-Mo硬质合金的WC粒度、硬度、摩擦磨损和耐腐蚀性能的影响。结果表明:在研究的成分范围内(w(Mo)=1.5%~2.0%),WC的平均晶粒尺寸基本不随Mo添加量的变化而变化;随Mo添加量的增加,WC-Ni-Mo硬质合金的硬度略微有所下降,而摩擦磨损性能得到提升。Mo质量分数为2%的WC-Ni-Mo硬质合金在酸性溶液中的耐腐蚀能力要高于Mo质量分数为1.5%的合金,并且具有更好的电化学稳定性。总体来看,WC-8.0%Ni-2.0%Mo合金的综合性能优于WC-8.5%Ni-1.5%Mo硬质合金。

医用同位素^(99)Mo吸附分离研究进展

医用同位素^(99)Mo是一种广泛应用于核医学领域的重要核素。由于常规的高浓缩铀裂变生产^(99)Mo的过程中存在安全隐患,人们已经开始寻找其他可靠的^(99)Mo生产途径。在分离^(99)Mo和^(99)mTc的方法中柱层析法具有很大优势,其中的关键是层析柱的材料,材料对^(99)Mo吸附能力关系到未来新一代^(99)Mo-^(99)mTc发生器的制备。本研究对医用同位素^(99)Mo的吸附分离进行综述,介绍^(99)Mo生产方式,^(99)Mo和^(99)mTc分离方法,以及目前对Mo具有一定吸附效果的吸附材料,为未来利用低比活度^(99)Mo吸附制备^(99)Mo-^(99)mTc发生器提供参考。

右江盆地大际山U-(Mo)矿床围岩蚀变特征及微量元素迁移规律——对区域内U、Au成生关系的指示

位于扬子地块西南缘的右江盆地,是全球第二大的卡林型Au矿(共伴生有Sb、Hg、Tl异常/矿化)矿集区,有着滇黔桂“金三角”的美誉。值得注意的是,该区除发育Au(-Sb-Hg-Tl)矿床外,还产有大量赋矿岩性和控矿构造相似的U矿床(点),成矿特色鲜明。前人对该区Au矿开展了大量研究,而U矿研究较少,对U、Au的成生关系尚不清楚。基于此,文章选取右江盆地内典型的U矿床——大际山U-(Mo)矿床为研究对象,通过开展岩矿相学研究和地球化学分析,厘定了矿化的围岩蚀变为硫化、沥青质化、磷铝锶石化、硅化和伊利石化,揭示了矿化过程中Re、Tl、Mo、U、Cd、Ni、Co、As、Sb、MREE的相对富集。蚀变矿物组合及元素迁移规律约束大际山U-(Mo)矿床中成矿物质可能来源于牛蹄塘组,成矿流体应为还原性有机流体与地表-近地表酸性、氧化性流体的混合,矿质沉淀发生在低温、酸性、还原环境中。综合分析认为,右江盆地内U、Au分布特征及矿床成因具有明显差异,二者应是不同成矿事件的产物。

秘鲁Morococha斑岩-矽卡岩-浅成低温热液型矿床成矿地质特征与区域找矿方向

秘鲁中部Morococha地区位于中安第斯秘鲁中新世成矿带,是全球最具代表性的世界级斑岩-矽卡岩型和浅成低温热液型成矿系统之一。系统总结了该区斑岩型、矽卡岩型、浅成低温热液型等多种铜钼铅锌银多金属矿化成矿作用特征和最新的研究进展,结合区域岩浆-热液成矿作用过程,提出了下一步找矿方向。Morococha矿区位于秘鲁中部Yali穹隆北段,由中心部位的Toromocho斑岩型铜钼矿床及外围铅锌银金多金属矿脉组成。区内主要构造为北西向Morococha背斜,地层主要为二叠纪—三叠纪Mitu群火山碎屑岩、侏罗纪Pucara群碳酸盐岩、早白垩世Goyllarisquizga群海相碎屑岩和碳酸盐岩。矿区中新世岩浆活动主要为中中新世不含矿的闪长质侵入岩(14.3~14.1 Ma)和晚中新世与成矿有关的花岗闪长岩和长石斑岩岩株(9.4~7.7 Ma)。Morococha岩浆-热液系统(8.5~7.2 Ma)是其形成超大型斑岩型铜矿成矿的原因之一,铅锌银多金属矿化主要发生在斑岩型矿化之后约0.5 Ma,受区域构造控制。矿床在空间上显示出明显的金属分带特征,中心斑岩区域为富铜矿石,而远离斑岩区出现更多的富铅锌银矿石。秘鲁中部中新世成矿带分布着众多具有重要经济价值的脉状热液型铅锌银多金属矿床,总结近年来综合地质调查和研究成果,表明这些多金属矿床都属于斑岩-矽卡岩成矿系统的一部分,因此斑岩-矽卡岩型铜矿床及浅成低温热液型贵金属矿床是秘鲁中部重要的找矿方向。

改性碳纤维-MoS_(2)复合涂层的高温摩擦学性能研究

为了改善高温下固体润滑复合涂层的稳定性,选择经过化学改性的纳米碳纤维对MoS_(2)涂料进行性能优化,制备添加不同比例的改性粉末的涂料.通过对粉末进行XPS、红外和形貌分析,表明碳纤维已经改性.借助CFT-I型高速往复摩擦磨损试验机分别在不同温度条件下进行摩擦试验,利用超景深显微系统对不同条件涂层表面磨损的形貌进行观测,对磨损机理进行分析,探究添加量的最优比例.试验结果表明:在试验温度分别为20、50和100℃时,添加质量分数1.5%CF-GO(氧化石墨烯改性碳纤维)涂料制备的涂层耐磨性能均优于其他的添加比例的涂层.在干摩擦5 N载荷,试验温度为200℃时,添加质量分数1.5%CF-GO的涂层比未改性的涂层的磨痕深度、宽度分别减少66.1%、29.2%,涂层的耐磨性能有了很大的提高,进一步采用扫描电子显微镜(SEM)分析涂层的内部形貌可知,添加质量分数1.5%的CF-GO时,涂层内部形成清晰的网状结构,从而使得该比例下的涂层同时具有抗高温变形、耐磨以及耐热等优异的性能.

Mo含量对激光熔覆CoCrFeNiW_(0.6)Mo_(x)高熵合金涂层组织与性能的影响

目的研究Mo含量的变化对激光熔覆CoCrFeNiW_(0.6)高熵合金涂层的影响。方法使用RFL-C1000光纤激光器,在45钢基体表面制备CoCrFeNiW_(0.6)Mo_(x)(x=0,0.2,0.4,0.6,0.8)高熵合金涂层,并利用Leica DVM6光学显微镜、扫描电镜(SEM)、X射线衍射仪(XRD)、能谱仪、显微硬度仪、电化学工作站对熔覆层的宏观形貌与稀释率、相结构、微观组织结构、硬度、耐腐蚀性能进行测试与分析。结果加入Mo元素后,结合状态与表面形貌良好,当x=0~0.4时,涂层微观组织主要呈树枝晶形态,且晶粒逐渐变细。当x≥0.6时,涂层表面开始有裂纹产生。随着Mo元素的添加,涂层逐渐析出σ相,晶粒尺寸逐渐减小。当x=0.8时,有共晶组织形成。涂层显微硬度随Mo元素的增加而增加,但由于x=0.8时出现较多裂纹,裂纹的出现影响了涂层硬度,导致x=0.8时的硬度减小。当x=0.6时,涂层平均显微硬度最高,达到了959.69HV0.3,约为CoCrFeNiW_(0.6)涂层平均硬度的20.32%。当x=0~0.6时,涂层耐腐蚀性能随着Mo元素含量的增加逐渐提升。当x=0.8时,耐腐蚀性能变差,其原因是裂纹的出现以及σ相的形成使得涂层耐腐蚀性变差。在x=0.6时,涂层耐腐蚀性能最好。结论Mo元素的加入使得涂层微观组织出现σ相,同时有细化晶粒的作用,可以显著改善涂层的硬度以及耐腐蚀性。

Mo-g-C_(3)N_(4)制备与可见光催化性能

以三聚氰胺和四水合钼酸铵为前驱体,利用一锅法制备了不同钼掺杂浓度的石墨型氮化碳光催化剂。利用X射线衍射(XRD)、红外光谱(FT-IR)、荧光光谱(PL)、扫描电子显微镜(SEM)等测试技术对合成催化剂进行了表征,结果发现:钼掺杂的氮化碳光催化剂具有石墨型结构,Mo的引入扩展了氮化碳的光谱响应范围,降低了光生电子和空穴的复合速率。亚甲基蓝的可见光降解测试表明,钼掺杂的氮化碳光催化剂比纯氮化碳展现出更高的光催化活性,掺杂浓度0.7%光催化剂的反应速率常数为纯氮化碳的1.4倍;同时,研究了Mo掺杂g-C_(3)N_(4)光催化降解性能的影响因素。

氧化石墨烯复合α-MoO_(3)的制备以及电化学性能的研究

通过水热法制备了α-MoO_(3)纳米棒前驱体,再通过退火的方式制备出超长α-MoO_(3)纳米棒(10μm),采用超声法将α-MoO_(3)纳米棒锚定在氧化石墨烯(GO)纳米网之间,制备三明治结构的GO@MoO_(3)纳米材料,对其进行物相形貌分析和电化学测试。实验结果表明,根据恒电流充放电曲线,GO@MoO_(3)电极在1A/g时显示出高达370F/g的高比容量,远高于原始MoO_(3)电极214F/g的比容量;根据循环伏安曲线,与原始的MoO_(3)电极相比,GO@MoO_(3)电极表现出显著增强的比电容,在5、10、20、30、40和50mV/s下,比电容可分别高达805、594、479、430、394和355F/g)。

Ag掺杂Mo-12Si-8.5B合金在25~600℃的摩擦学行为

本文中采用放电等离子烧结法制备了Mo-12Si-8.5B和Mo-12Si-8.5B-10%Ag这2种合金,通过高温真空摩擦磨损试验仪测试了2种合金与Al_(2)O_(3)摩擦副在25~600℃间的干摩擦学性能.结果表明:与Mo-12Si-8.5B合金相比,在25~600℃区间Mo-12Si-8.5B-10%Ag合金表现出更低的摩擦系数和磨损率.在600℃时,Mo-12Si-8.5B-10%Ag合金的摩擦系数和磨损率均可达到最小值,其值分别为0.41和1.14×10^(-5)mm^(3)/(N·m),此时Mo-12Si-8.5B-10%Ag合金的干摩擦性能表现最佳,这与Mo-12Si-8.5B-10%Ag合金磨损表面的MoO_(3)、SiO_(2)和Ag_(2)MoO_(4)等润滑相的存在及Ag在25~600℃范围内起到的润滑效果有关.此外,在25~200℃区间,Mo-12Si-8.5B-10%Ag合金的磨损机制主要为黏着磨损和剥层磨损,在400~600℃范围内,则以黏着磨损和氧化磨损为主.

基于MOS认证体系的统计数据处理与课证融通教学模式研究

MOS在全球具有广泛影响力,是评价企业数据处理与分析人员技术水平的重要依据,高等职业教育财经商贸大类所属专业类、专业对MOS有较高的依赖性,受限于教育行业兼任企业技术人员数量,目前尚未见到将MOS体系与相关专业课程有效融合的成熟案例。本文以MOS专家级认证为基本参照,探索统计实践教学与“Microsoft Excel Expert”的融合机制,系统研究基于MOS的课证融通教学模式。

空间滚动轴承MoS_(2)薄膜润滑分子动力学模拟

针对空间滚动轴承往复运动状态下二硫化钼薄膜润滑失效机理不明的难题,提出了采用分子动力学对薄膜润滑过程进行分析的方法。建立了单层二硫化钼薄膜摩擦原子模型,针对载荷和环境温度这2个空间滚动轴承的重要影响因素展开了二硫化钼薄膜的往复摆动模拟,得到了摩擦过程中二硫化钼薄膜的摩擦力、粘附力和磨损情况。模拟结果表明:Fe-Ni-Cr合金探针在单层二硫化钼薄膜上的摩擦为黏滑运动,载荷在20~100 nN范围内探针的摩擦过程不会对薄膜造成磨损,但在往复运动过程中润滑性能有所提高;载荷从200 nN开始探针的摩擦过程会对薄膜造成磨损,往复运动过程中摩擦系数不断提高,润滑性能下降;400 nN为单层薄膜的载荷极限,在该载荷下探针会刺穿薄膜与基底接触此时薄膜迅速磨损失去润滑作用。环境温度在1 773.15 K以下对薄膜的润滑作用影响不明显,但达到该温度后薄膜边界处开始缓慢熔化,当环境温度达到二硫化钼熔点时薄膜的熔化速度加快并失去润滑作用。从这些发现得到如下结论:二硫化钼单层薄膜在接触载荷8 GPa以下拥有优异的耐磨性和润滑性;在薄膜未破损的条件下,反复摩擦过程提升了润滑性能;二维层状结构对单层二硫化钼薄膜润滑性能有重要的影响,高温和重载都会对薄膜层状结构造成破坏。

MOS器件Hf基高k栅介质的研究综述

随着金属氧化物半导体(MOS)器件尺寸的持续缩小,HfO2因其介电常数(k)高、带隙大等特点,成为取代传统SiO2栅介质最有希望的候选材料.本文综述了Hf基高k栅介质薄膜的近年的研究进展.针对HfO2结晶温度低、在HfO2薄膜和Si衬底间易形成界面层导致漏电流大、界面态密度高、击穿电压低等问题,回顾了最近论文报道的两种策略,即掺杂改性和插入缓冲层.接着举例讨论了Hf基材料从二元到掺杂氧化物/复合物的演变、非Si衬底上淀积Hf基高k栅介质、Hf基高k栅介质的非传统MOS器件结构,为集成电路(IC)中MOS器件的长期发展提供一些思路.

MoS_(2)的制备及其超声催化性能

以钼酸钠和硫脲为原料,用水热法制备了系列MoS_(2)催化剂,采用XRD、SEM、TEM等技术,对MoS_(2)催化剂的晶相结构及表面形貌尺寸等进行了表征,以染料亚甲基蓝探究了MoS_(2)样品的超声催化性能。结果表明,所得MoS_(2)催化剂粒径分布范围为0.5~5μm,当钼酸钠与硫脲摩尔比小于等于1∶9时,所得MoS_(2)样品具有六方晶相结构及结晶度相对较好;超声催化实验结果表明,钼硫摩尔比为1∶3时,所得MoS_(2)的超声催化性能最佳,超声12 min时,对亚甲基蓝的降解率可达94.08%。

黑龙江省准对称混合训练期MOS气温预报性能分析

本文选取ECMWF细网格地面2 m气温要素预报产品作为预报因子,选取中国气象局陆面数据同化系统(CLDAS-V2.0)地面2 m气温格点实况数据作为预报量,应用准对称混合训练期MOS方法,建立黑龙江省格点气温MOS方法,并对MOS方法在24 h预报时效内间隔3 h的格点气温预报性能进行检验分析。结果表明:MOS平均绝对误差≤1.5℃;MOS夏半年≤2℃预报准确率为84.1%,比ECMWF提高7.6%;冬半年预报准确率为71.5%,比ECMWF提高18.3%;预报技巧夏半年为14.2%,冬半年为29.8%。MOS夏半年预报效果好于冬半年,冬半年预报改善效果好于夏半年。大、小兴安岭和东南部山区MOS预报效果不如平原地区好,但是MOS改善效果明显好于平原地区。