质子入射Al_(x)Ga_(1-x)N材料的位移损伤模拟

氮化镓材料由于优良的电学特性以及耐辐照性能,其与不同含量Al_(x)Ga_(1-x)N材料组成的电子器件,有望应用于未来空间电子系统中.然而目前关于氮化镓位移损伤机理研究多关注于氮化镓材料,对于Al_(x)Ga_(1-x)N材料位移损伤研究较少.本文通过两体碰撞近似理论模拟了10 keV-300 MeV质子在不同Al元素含量的Al_(x)Ga_(1-x)N材料中的位移损伤机理.结果表明质子在Al_(x)Ga_(1-x)N材料中产生的非电离能损随质子能量增大而下降,当质子能量低于40 MeV时,非电离能损随着Al含量的增大而变大,当质子能量升高时该趋势相反;分析由质子导致的初级撞出原子以及非电离能量沉积,发现不同Al_(x)Ga_(1-x)N材料初级撞出原子能谱虽然相似,然而Al元素含量越高,由弹性碰撞产生的自身初级撞出原子比例越高;对于质子在不同深度造成的非电离能量沉积,弹性碰撞导致的能量沉积在径迹末端最大,而非弹性碰撞导致的能量沉积在径迹前端均匀分布,径迹末端减小,并且低能质子主要是通过弹性碰撞造成非电离能量沉积,而高能质子恰好相反.本研究揭示了不同Al元素含量的Al_(x)Ga_(1-x)N材料质子位移损伤机理,为GaN器件在空间辐射环境下的应用提供参考依据.

Mo_(1-x)W_(x)C碳化物稳定性及力学性质的第一性原理计算

金属碳化物作为基体的增强相,对钢铁的力学性能起到至关重要的作用.采用基于密度泛函理论的第一性原理方法,通过虚拟晶体近似构建Mo_(1-x)W_(x)C(0≤X≤1)碳化物模型,计算Mo_(1-x)W_(x)C的晶格常数、形成能、结合能、弹性常数、弹性模量、泊松比u、维氏硬度、电子态密度等性质参数,分析W元素对MoC碳化物稳定性及力学性能的影响.本次计算值与其他理论计算值及试验值吻合度较高;随着W含量的增加,晶格常数增加,Mo_(1-x)W_(x)C的形成能、结合能皆为负值,结合能、形成能的绝对值均随着W含量的增加而增加.不同掺杂含量下的Mo_(1-x)W_(x)C均满足Born判据,在力学上是稳定的,随着W含量的增加,Mo_(1-x)W_(x)C的弹性常数、体模量、杨氏模量、剪切模量呈线性增加,B/G、泊松比降低.Mo_(1-x)W_(x)C在费米能级处的态密度值均不为0,态密度值随着W含量的增加而降低.Mo_(1-x)W_(x)C能自发形成且能稳定存在,随着W含量的增加,Mo_(1-x)W_(x)C碳化物的稳定性、弹性模量、硬度及耐磨性均增加,Mo_(1-x)W_(x)C呈脆性,脆性大小随着w含量的增加而增加.

Ag/LaNi_(x)Co_(1-x)O_(3)触点材料的制备及电接触性能研究

本文运用溶胶-凝胶燃烧法合成了双钙钛矿型LaNi_(x)Co_(1-x)O_(3)(LNCO)纳米材料,利用粉末冶金和热挤压技术制备了相应的Ag/LNCO触点材料及元件样品。重点考察了不同Ni、Co含量对Ag/LNCO触点材料微观结构、物相组成、物理性能、力学性能及电寿命服役能力的影响,对其电弧侵蚀失效行为进行了研究,并与SnO2粉体增强Ag基触点材料进行对比。结果表明:溶胶凝胶法合成的LNCO纳米颗粒粒径为20-30 nm,经粉末冶金工艺制备的Ag/LaNi_(0.5)Co_(0.5)O_(3)触点材料电学性能和电寿命都优于Ag/SnO_(2)触点材料,其电阻率低至2.10μΩ∙cm,电寿命性能达到51287次。表明Ag/LaNi_(0.5)Co_(0.5)O_(3)触点材料性能较佳,是一种可以取代Ag/CdO的新型触点材料。

基于BP神经网络模型优化Fe_(1-x)O基氨合成催化剂

运用BP神经网络建立了助催化剂含量与催化剂活性之间的预测模型,对Fe_(1-x)O基氨合成催化剂的助催化剂进行优化。首先将前期实验数据整理归纳为含有3、4、5、6和7个助催化剂等5类催化剂,以助催化剂含量(体积分数)为输入变量,以425℃反应器出口氨浓度(活性)为输出变量,对助催化剂进行优化。结果表明,BP神经网络预测模型拟合值均方误差最高为0.2784,预测值均方误差最高为0.1592,构建的BP神经网络模型准确度较高。在该模型的基础上,运用多种群遗传算法进行极值寻优,求解最优的催化剂配方,并进行实验验证。结果表明,根据优化结果制备5个样品的实验测定值与预测值的相对误差最高为2.88%,优化结果较为准确;含有7个助催化剂的催化剂活性最高为18.83%,比原样本的统计平均活性值(17.52%)高1.31%,相对提高7.48%,助催化剂含量优化取得满意的结果。

PEG-2000添加量对Pr_(x)Zr_(1-x)O_(2-δ)催化氧化NO活性的影响

采用溶胶-凝胶法制备了Pr_(x)Zr_(1-x)O_(2-δ)催化剂,并用于NO催化氧化。以聚乙二醇-2000(PEG-2000)为模板剂对催化剂进行改性,研究了不同模板剂添加质量分数对NO催化氧化活性的影响。结果表明,催化剂活性随PEG-2000添加质量分数的增加而降低;在300℃、PEG-2000添加质量分数为2%时,Pr_(x)Zr_(1-x)O_(2-δ)的催化活性最高,NO转化率达到了94.81%。利用XRD、SEM、N2吸附-脱附、XPS及FT-IR对催化剂进行表征,结果表明,模板剂添加质量分数的变化不会改变催化剂Pr_(2)Zr_(2)O_(7)晶型;催化剂为介孔结构,质量分数为2%时的比表面积和孔容最大,有利于催化氧化NO。此外,模板剂质量分数的增加会增强催化剂的亲水性。

Structure and superconducting properties of Ru_(1-x)Mo_(x)(x=0.1-0.9)alloys

We report the detailed crystal structures and physical properties of Ru_(1-x)Mo_(x)alloys in the solid solution range of x=0.1-0.9.Structure characterizations indicate that the crystal structure changes from the hcp-Mg-type,toβ-CrFe-type,and then bcc-W-type.The measurements of physical properties show that the Ru_(1-x)Mo_(x)samples with x≥0.2are superconductors and the superconducting transition temperature T_c as a function of Mo content exhibits a dome-like behavior.

具有Ruddlesden-Popper结构的杂化非本征铁电体(Ca_(1-x)Sm_(x))_(3)Ti_(2)O_(7)陶瓷的制备及其物理性能

为探究稀土离子掺杂对Ca_(3)Ti_(2)O_(7)物理性能的调控,采用固相反应法制备了Sm^(3+)掺杂的(Ca_(1-x)Sm_(x))_(3)Ti_(2)O_(7)(x=0,0.02,0.04)陶瓷样品,通过XRD、XPS、紫外-可见光吸收光谱以及第一性原理计算等方法对样品的晶体结构、光学性能、电学性能和磁学性能进行分析.结果表明:随着Sm^(3+)含量的增加,(Ca_(1-x)Sm_(x))_(3)Ti_(2)O_(7)的晶胞参数逐渐增大.Sm^(3+)掺杂导致氧空位减少,因此样品的漏电流随着Sm^(3+)掺杂量的增加而减小.同时,随着Sm^(3+)掺杂量的增加,样品的光学带隙呈现增大趋势.此外,第一性原理研究表明,Sm^(3+)掺杂可在体系中诱导出磁性能,进一步丰富了该材料的物理性能.

Asymmetric orbital hybridization in Zn-doped antiperovskite Cu_(1-x)Zn_(x)NMn_(3)enables highly efficient electrocatalytic hydrogen production

Rational design of efficient and robust earth-abundant alkaline hydrogen evolution reaction(HER)catalysts is a key factor for developing energy conversion technologies.Currently,antiperovskite nitride CuNMn_(3)has garnered significant interest due to its remarkable properties such as negative/zero thermal expansion and magnetocaloric effects.However,when utilized as hydrogen evolution catalysts,it encounters large challenge resulting from excessively strong/weak interactions with adsorbed H on Mn/Cu active sites,which leads to low HER activity.In this study,we introduce an asymmetric orbital hybridization strategy in Zn-doped Cu_(1-x)Zn_(x)NMn_(3)by leveraging the localization of Zn electronic states to reconfigure the electronic structures of Cu and Mn,thereby reducing the energy barrier for water dissociation and optimizing Cu and Mn active sites for hydrogen adsorption and H_(2)production.Electrochemical evaluations reveal that Cu_(0.85)Zn_(0.15)NMn_(3)with x=0.15 demonstrates exceptional electrocatalytic activity in alkaline electrolytes.A low overpotential of 52 mV at 10 mA cm^(-2)and outstanding stability over a 150-h test period are achieved,surpassing commercial Pt/C.This research offers a novel strategy for enhancing HER performance by modulating asymmetric hybridization of electron orbitals between multiple metal atoms within a material structure.

Modulating Co-Co bonds average length in Co_(0.85)Se_(1-x)S_(x) to enhance conversion reaction for potassium storage

While alloying transition metal chalcogenides(TMCs)with other chalcogen elements can effectively improve their conductivity and electrochemical properties,the optimal alloying content is still uncertain.In this study,we study the influence of dopant concentration on the chemical bonds in TMC and reveal the associated stepwise conversion reaction mechanism for potassium ion storage.According to density function theory calculations,appropriate S-doping in Co0.85Se(Co_(0.85)Se_(1-x)S_(x))can reduce the average length of Co-Co bonds because of the electronegativity variation,which is thermodynamically favourable to the phase transition reactions.The optimal Se/S ratio(x=0.12)for the conductivity has been obtained from experimental results.When assembled as an anode in potassium-ion batteries(PIBs),the sample with optimized Se/S ratio exhibits extraordinary electrochemical performance.The rate performance(229.2 mA h g^(-1)at 10 A g^(-1))is superior to the state-of-the-art results.When assembled with Prussian blue(PB)as a cathode,the pouch cell exhibits excellent performance,demonstrating its great potential for applications.Moreover,the stepwise K+storage mechanism caused by the coexistence of S and Se is revealed by in-situ X-ray diffraction and ex-situ transmission electron microscopy techniques.Hence,this work not only provides an effective strategy to enhance the electrochemical performance of transition metal chalcogenides but also reveals the underlying mechanism for the construction of advanced electrode materials.

Zn_(x)Cd_(1-x)S固溶体的制备及光降解亚甲基蓝的性能研究

本文通过水热法成功制备了Zn_(x)Cd_(1-x)S固溶体材料,并通过光催化降解亚甲基蓝(MB),探究了材料的光催化性能。光催化实验结果表明,Zn_(0.2)Cd_(0.8)S固溶体材料的去除效率达到了81.94%,接近于纯CdS的1.43倍和ZnS的1.47倍。通过XRD、UV-vis漫反射吸收光谱和EIS等表征,探究了光催化性能增强的可能原因。结果表明,所构建的Zn_(0.2)Cd_(0.8)S固溶体材料具有较高的载流子分离效率,并且在可见光区增强了光吸收能力,提高了光催化性能。

热电池用Co_(x)Fe_(y)Ni_(1-x-y)S_(2)正极材料的性能研究

采用高温固相法合成了Co_(x)Fe_(y)Ni_(1-x-y)S_(2)正极材料,并研究了掺杂金属比例对其性能的影响。测试结果表明,制备的Co_(x)Fe_(y)Ni_(1-x-y)S_(2)为单一的固溶体材料,微观形貌为多面体颗粒,材料的热分解温度在640℃以上,且随着x的增大和y值的减小而增大。当x=0.5,y=0.3时,Co_(x)Fe_(y)Ni_(1-x-y)S_(2)具有最佳的电性能,工作时间可达2774 s,比容量为1733.8 As/g,工作初期内阻低于15 mΩ。

家蚕Tret1-X1基因对家蚕核型多角体病毒(BmNPV)的基因表达和基因组复制的影响

家蚕促海藻糖转运蛋白1异构体X1(Bombyx mori facilitated trehalose transporter Tret1-like isoform X1,BmTret1-X1)主要参与家蚕糖代谢过程。为探究其在家蚕抗BmNPV感染过程中的作用,克隆BmNPV抗性家蚕品系AN与易感品系C108的BmTret1-X1基因,发现基因编码区存在4个SNP导致的氨基酸改变,两者的预测蛋白质结构存在差异。利用pIZT/V5-His-mCherry表达载体在BmN细胞中过表达BmTret1-X1,BmNPV感染后24 h、48 h的BmNPV增殖受到抑制,BmNPV基因lef-3、vp39、p10和gp64的转录水平低于对照组(P<0.05),其中感染后24 h vp39基因的表达量与对照组相比差异达1 089倍,细胞中病毒基因组DNA复制也受到明显抑制。转染BmTret1-X1基因siRNA使BmN细胞中该基因表达量降低约一半,BmNPV的lef-3、vp39、p10和gp64转录水平升高,但BmNPV增殖和基因组DNA复制水平未见明显变化。综上所述,BmN细胞中BmTret1-X1基因的高表达对BmNPV的基因表达、DNA复制及病毒增殖具有抑制作用,该基因在家蚕对BmNPV的抗性形成过程中具有一定作用。

拓扑绝缘体(Bi_(1-x)Sb_(x))_(2)Te_(3)薄膜制备及其电输运性能研究

文章利用分子束外延(molecular beam epitaxy, MBE)法,在超高真空的条件下,于蓝宝石衬底上制备超薄的高质量拓扑绝缘体(Bi_(1-x)Sb_(x))_(2)Te_(3)薄膜。利用反射高能电子衍射(reflection high-energy electron diffraction, RHEED)仪、X射线衍射(X-ray diffraction, XRD)仪、显微共焦激光拉曼光谱仪(micro confocal laser Raman spectrometer)和X射线光电子能谱(X-ray photoelectron spectroscopy, XPS)仪对不同Sb掺杂量的样品进行表征,并获得最佳的制备参数。研究结果表明:衬底温度为460℃时Bi和Te的流量比为1∶16左右;在Sb温度为350、360、370、380℃时,可以制得高质量的(Bi_(1-x)Sb_(x))_(2)Te_(3)薄膜。利用霍尔效应测量系统测量样品的电阻率、霍尔系数、迁移率和载流子浓度;测量结果表明,(Bi_(1-x)Sb_(x))_(2)Te_(3)薄膜的载流子浓度和主要载流子类型随x的变化而发生相应的变化,并伴随着费米能级位置的调谐,随着x的增加,在x=0.53到x=0.68的掺杂过程中,费米能级从导带下移到带隙,最终进入价带,多数载流子类型也从自由电子转变成空穴,(Bi_(1-x)Sb_(x))_(2)Te_(3)实现了从n型到p型的转化。

Dual-functional marigold-like Zn_(x)Cd_(1-x)S homojunction for selective glucose photoreforming with remarkable H_(2)coproduction

The global commitment to pivoting to sustainable energy and products calls for technology development to utilize solar energy for hydrogen(H_(2))and value-added chemicals production by biomass photoreforming.Herein,a novel dual-functional marigold-like Zn_(x)Cd_(1-x)S homojunction has been the production of lactic acid with high-yield and H_(2)with high-efficiency by selective glucose photoreforming.The optimized Zn_(0.3)Cd_(0.7)S exhibits outstanding H_(2)generation(13.64 mmol h^(-1)g^(-1)),glucose conversion(96.40%),and lactic acid yield(76.80%),over 272.80 and 19.21 times higher than that of bare ZnS(0.05 mmol h^(-1)g^(-1))and CdS(0.71 mmol h^(-1)g^(-1))in H_(2)generation,respectively.The marigold-like morphology provides abundant active sites and sufficient substrates accessibility for the photocatalyst,while the specific role of the homojunction formed by hexagonal wurtzite(WZ)and cubic zinc blende(ZB)in photoreforming biomass has been demonstrated by density functional theory(DFT)calculations.Glucose is converted to lactic acid on the WZ surface of Zn_(0.3)Cd_(0.7)S via the photoactive species·O_(2)^(-),while the H_(2)is evolved from protons(H^(+))in H_(2)O on the ZB surface of Zn_(0.3)Cd_(0.7)S.This work paves a promising road for the production of sustainable energy and products by integrating photocatalysis and biorefine.

Sulfur vacancies-induced“Electron Bridge”in Ni_(4)Mo/Sv-Zn_(x)Cd_(1-x)S regulates electron transfer for efficient H_(2)-releasing photocatalysis

Despite the existence of plentiful photocatalyst heterojunctions,their separation efficiency and charge flow precision remain low on account of lacking interfacial modulation.Herein,through a defect-induced heterojunction constructing strategy,Ni4Mo alloys were in-situ grown on the unsaturated coordinated sulfur atoms of sulfur vacancies-rich ZCS(Sv-ZCS)via interfacial Ni-S covalent bonds.The experimental and theoretical results reveal that these unsaturated sulfur atoms induced by sulfur vacancies vastly facilitate to anchor more Ni-Mo nanoparticles and form abundant Ni-S covalent bonds,meanwhile,these sulfur vacancies could form dual internal electric field(IEF)and work with Ni-S covalent bonds as“Electron Bridge”to further accelerate photoelectrons transfer,as well as promote the activation of water molecules and the desorption of hydrogen proton.Accordingly,the optimized Ni_(4)Mo/Sv-ZCS composite achieves an improved photocatalytic hydrogen evolution(PHE)rate of 94.69 mmol h^(-1)g^(-1)without an evident decrease after 6 cycles of photocatalytic tests,which is 21.2 and 1.94 times higher than those of Pt/ZCS and Ni_(4)Mo/ZCS,respectively.This tactic opens a new way for optimizing Zn_(x)Cd_(1-x)S-based heterojunctions by constructing sulfur vacancies and covalent bonds as“Electron Bridge”to enhance the activity of PHE.

室温脉冲激光原位沉积技术制备Cu_(2)(Zn_(1-x)Fe_(x))SnS_(4)/Bi_(2)S_(3)异质结及其光电性能

采用具有磁性的Fe取代Cu_(2)ZnSnS_(4)(CZTS)中Zn组分,制备Cu_(2)(Zn_(1-x)Fe_(x))SnS_(4)(CZFTS)薄膜。将电子传输层Bi_(2)S_(3)与CZFTS耦合,采用室温脉冲激光沉积技术(RT-PLD)制备了CZFTS/Bi_(2)S_(3)异质结构。研究了Fe掺杂对于CZFTS薄膜形貌、结晶度和吸光度的影响。测试了单层薄膜和异质结构的光电响应特性,实验表明与单层CZFTS薄膜相比,CZFTS/Bi_(2)S_(3)异质结在可见光区域内的光电响应速度至少提高了一个数量级,响应时间缩短至几十ms。

一维多孔Co_(1-x)S/NC纳米线的可控制备及储钠性能

发展高比容量、良好可逆性和长循环寿命的钠离子电池电极材料仍面临巨大的挑战。通过简单的水热法,合成氮基三乙酸(Co-NTA)前驱体,再分别在氮气气氛下退火和硫化,制得钠离子电池用一维多孔氮掺杂碳纳米线(Co_(1-x)S/NC)负极材料。以1.0 A/g的电流在0.01~3.00 V循环200次,电极有461.16 mAh/g的可逆比容量。这可归因于氮掺杂碳的多孔中空纳米线结构,不仅增强材料的导电性,还可提高比容量,并缓解充放电过程中较大的体积膨胀,延长材料的循环寿命。

双交换作用下Li_(1±y)(Mg_(1-x)Cr_(x))As的半金属铁磁性

采用基于密度泛函理论的第一性原理方法,计算并分析了96原子Li_(1±y)(Mg_(1-x)Cr_(x))As体系的铁磁稳定性、电子结构、自旋电荷密度、投影态密度和差分电荷密度。结果表明,Cr的掺杂引入了自旋极化杂质带,形成了强于Mg-As的Cr-As共价键,体系表现出强的半金属性,产生7.03μB的净磁矩。体系的磁电性质还受到Li计量数的调控,减少Li含量使Cr-As间的共用电子对偏移程度略微增大,Cr-3d与As-4p的p-d杂化有所减弱,净磁矩减小为6.14μB;Li1.03125(Mg_(0.9375)Cr_(0.0625))As发生sp-d杂化,材料转变为n型掺杂,半金属能隙减小为0.375 eV,具有最大的净磁矩7.61μB。通过分析自旋电荷密度和Cr-3d轨道的投影态密度发现,体系的铁磁耦合起源于Cr离子间的双交换作用。As^(3-)作为桥梁形成Cr_(1)-As-Cr_(2)链,巡游d电子在Cr_(1)-As-Cr_(2)链间的跃迁导致Li_(1±y)(Mg_(1-x)Cr_(x))As中的两个Cr离子均具有平行磁矩,从而使体系具有稳定的铁磁性。

Fe_(1-x)S-BC/g-C_(3)N_(4)的制备及其光芬顿降解盐酸四环素的性能

通过浸渍联合原位煅烧方法成功制备了Fe_(1-x)S-BC/g-C_(3)N_(4)复合光催化材料,采用SEM、XRD、FTIR和XPS对Fe_(1-x)S-BC/g-C_(3)N_(4)催化剂的结构进行表征分析,并将其用于盐酸四环素(TCH)的光芬顿催化降解,考察了三聚氰胺加入量、催化剂投加量、TCH初始浓度、H2O2浓度和初始pH对TCH降解率的影响.结果表明,最佳反应条件为pH=3.0、H2O2=10 mmol·L^(−1)、催化剂投加量为1.0 g·L^(−1),光照1 h后,Fe_(1-x)S-BC/g-C_(3)N_(4)-2对40 mg·L^(−1)的TCH降解率达到98.5%,且铁溶出量仅为0.5 mg·L^(−1).对照实验显示,Fe_(1-x)S-BC/g-C_(3)N_(4)-2的光芬顿催化反应速率常数分别是其光催化反应和非均相芬顿反应的66.6倍和2.9倍.杂离子干扰实验表明Fe_(1-x)S-BC/g-C_(3)N_(4)-2对常见的阴离子有良好的耐受性,经过5次循环使用后,TCH的解率仍有87.1%.活性物种猝灭实验证实·OH和·O2−为主要的活性物种.

固体氧化物燃料电池Sr_(2)Fe_(1+x)Mo_(1-x)O_(6-δ)双钙钛矿阳极的改性研究进展

固体氧化物燃料电池(SOFC)是下一代能源系统的重要组成部分,拥有比传统发电方式更高的能量转换效率、燃料选择范围广、无需贵金属催化剂,环境友好。阳极作为SOFC中燃料氧化的电化学反应场所,其材料选择对电池性能的影响较大。截至目前,阳极材料的研究已经从最开始的金属基陶瓷材料发展到氧化物型材料。其中双钙钛矿作为钙钛矿材料的衍生物更是成为了目前的主流选择。Sr_(2)Fe_(1+x)Mo_(1-x)O_(6-δ)(SFMO)因为优异的电导率、抗积碳和耐硫性得到广泛关注,但将其用于商业化还有一些问题亟待解决,为进一步提升SFMO阳极的催化活性和稳定性,研究人员将目光放在了材料的改性上。概述了通过不同改性方法来提升SFMO阳极性能的研究进展,分别从掺杂(A,B掺杂和A/B共掺),A位缺位和表面修饰三个方面进行阐述,从物相、结构和电化学性能方面对阳极进行比较,分析了各改性方法对电化学性能,长期稳定性和氢裂解、氧化反应能力的影响。