Gd-La-Al合金的微观结构与磁热效应

以Gd_3-xLa_xAl₂ (x=0,0.1,0.2,0.3)磁制冷材料为研究对象,系统分析了合金的相组成、微观组织及磁热性能。结果表明,Gd_3-xLa_xAl₂(x=0,0.1,0.2,0.3)合金均由Gd₃Al₂相、GdAl相、Gd₂Al相组成。La原子主要分布于Gd₂Al相,且La元素的添加具有调控Gd Al相形貌的作用。对M-T曲线求一阶导数可得,Gd_3-xLa_xAl₂ (x=0,0.1,0.2,0.3)合金的居里温度T_C随La含量的增加呈逐渐降低的趋势,分别为275,267,261,252 K,适用于近室温领域的制冷。利用Landau理论,分析了Gd_3-xLa_xAl₂ (x=0,0.1,0.2,0.3)合金的磁相...     

锂离子电池高镍正极材料掺铝的作用及掺铝方法的研究

为了探究铝对高镍层状氧化物在结构、形貌及性能方面的影响,本文采用两种不同的方式掺铝以制备NCA正极材料 （LiNi_0.8Co_0.15Al_0.05O₂）：一是固相法即将共沉淀合成的NC前驱体（Ni_0.84Co_0.16(OH)₂）在混锂烧结过程混入铝源（纳米Al₂O₃或Al(NO₃)₃）;二是共沉淀法即直接在合成前驱体过程中混入铝源（Al₂(SO₄)₃或NaAlO₂）即合成NCA前驱体（Ni_0.8Co_0.15Al_0.05(OH)_2.05）后再混锂烧结. 结果表明,掺铝能够降低阳离子混排程度、维持层状结构的稳定性,改善材料在充放电循环过程的放电电压及中值电压大幅下降的情况,提高其循环性能. 其中以NaAlO₂为铝源合成NCA前驱体所制备的NCA材料性能最优：在3.0 ~ 4.3 V充放电区间,0.1C倍率下首圈放电比容量达198 mAh·g^-1,首次库仑效率可达94.6%,1C倍率下循环200圈后容量保持率达70%.     

猝冷速度对骨架Ni催化剂结构和催化性能的影响

在5种不同猝冷速度下制备Ni-Al合金,然后以碱处理并活化得到多孔猝冷骨架Ni催化剂.通过电感耦合等离子发射光谱(ICP)、X射线粉末衍射(XRD)、H₂-程序升温脱附(H₂-TPD)和氮物理吸附等方法对催化剂的物理化学性质进行了表征.结果发现,随着冷却速度的增加,活化后的催化剂具有更多的残余Ni₂Al₃相、更低的比表面积、更大的孔容和孔径、更小的Ni晶粒、更大的Ni-Ni间距和更加单一的活性位.另外,还发现在肉桂醛选择加氢反应中,冷却速度的提高也促进了催化剂的活性和对目标产物3-苯丙醛选择性的提高.以RQNi₅为催化剂,加氢产物3-苯丙醛的收率达到88.8%,转化率为98.4%,明显优于工业上广泛使用的RaneyNi催化剂.同时,对猝冷骨架Ni催化剂的结构与催化性能之间的关系进行了讨论.     

载体ZrO2的d带电子对Ni13催化CH4脱氢过程的影响（英文）

C-H键活化是甲烷转化的关键，分散于ZrO₂（111）表面的活性Ni₁₃微粒能实现这一过程。密度泛函理论结果表明，相比Ni₁₃催化过程，Ni₁₃-ZrO₂（111）更能活化CH₄逐步脱氢并稳定其解离物种；且在载体ZrO₂存在下，C-H键长增加，C-H断键活化能降低，放热量增多，达过渡态时，解离H与残留CH_x间距减小，因此，负载催化剂Ni₁₃-ZrO₂（111）具有更好的催化性。究其原因，对于Ni-C-H,ZrO₂丰富的d带电子使得Ni 3d电子密度增强，C 2p与Ni 3d轨道重叠增多，Ni-C键增强，C-H键减弱，基于此，CH_x吸附增强，C-H键活性亦增强。因此，载体ZrO₂的d带为Ni₁₃活化CH₄促进C-H键解离提供着电子。     

新型镁基储氢合金的合成及电化学性能的研究

用扩散法成功地合成了Mg_1.5Al_0.5-xNiV_x(x=0,0.1,0.2,0.3,0.4)系列合金。XRD结构分析表明,合金中出现一个新的物相,其化学式为Mg₃AlNi₂,属立方晶系,Fd3m空间群,新相具有很好的电化学性能。钒的添加使合金的容量进一步提高。未经任何预处理的Mg_1.5Al_0.3V_0.2Ni合金的最大放电容量达到333mA·h·g^-1(50mA·g^-1,-0.5Vvs.Hg/HgO).Al对六方晶系Mg₂Ni合金结构中Mg的部分取代对于延长合金的循环寿命有重要作用。     

Synthesis of spherical LiNi0.8Co0.15Al0.05O2 cathode materials for lithium-ion batteries by a co-oxidation-controlled crystallization method

Spherical Ni_0.8Co_0.15Al_0.05OOH precursor,prepared by a co-oxidation-controlled crystallization method,was used to synthesize LiNi_0.8Co_0.15Al_0.05O₂.The obtained LiNi_0.8Co_0.15Al_0.05O₂ materials showed excellent electrochemical performance,with an initial discharge capacity of 193.5 mAh/g and capacity retention of 95.1%after 50 cycles when cycled at 0.2℃rate between 2.8 and 4.3 V.     

纳米MgO掺杂改善LiNi1/3Co1/3Mn1/3O2正极材料

将氢氧化物共沉淀法制备的(Ni_1/3Co_1/3Mn_1/3)（OH）₂在500℃热处理5 h得到具有尖晶石结构、纳米尺寸的氧化物M₃O₄(M=Ni_1/3Co_1/3Mn_1/3).将其与LiOH及不同量的纳米MgO混合均匀,并在850℃热处理24 h制备了Li(Ni_1/3Co_1/3Mn_1/3)_1/xMg_xO₂（x=0,0.01,0.02,0.03,0.04,0.05）正极村料.随着Mg掺杂量的增大,正极材料的晶胞参数增大;少量的Mg掺杂增大了锂离子的扩散系数,而过度掺杂却使锂离子扩散系数有所降低,其中Li(Ni_1/3Co_1/3Mn_1/3)_0.98Mg_0.02O₂的锂离子扩散系数最大,其脱出和嵌入扩散系数分别为D_Li-dein=29.20×10^-11cm²·S^-1和D_Li-in=4.760×10^-11cm²·s^-1;其以3C倍率充放电的平均放电比容量为139.3 mAh·g^-1,比未掺杂的原粉约高9.5 mAh·g^-1;另外其循环性能也得到了大幅度改善.     

Ni3S2@碳纳米管复合材料的制备及其储钠性能

采用一步固相煅烧工艺制备了碳纳米管原位封装Ni₃S₂纳米颗粒（Ni₃S₂@CNT）,并研究了其作为钠离子电池（SIBs）负极材料的电化学性能. 通过X射线衍射（XRD）、扫描电子显微镜（SEM）、透射电子显微镜（TEM）、循环伏安测试、恒流充放电以及交流阻抗等研究了Ni₃S₂@CNT的物相结构、形貌特征以及电化学性能. 电化学测试表明,材料在100 mA·g ^-1电流密度下,放电容量可以达到541.6 mAh·g ^-1,甚至在2000 mA·g ^-1的大电流密度下其放电比容量也可以维持在274.5 mAh·g ^-1. 另外,材料在100 mA·g ^-1电流密度下,经过120周充放电循环后其放电和充电比容量仍然可以保持在374.5 mAh·g ^-1和359.3 mAh·g ^-1,说明其具有良好倍率性能和循环稳定性能. 良好的电化学性能归因于这种独特的碳纳米管原位封装Ni₃S₂纳米颗粒结构. 碳纳米管不但可以提高复合材料的导电性,也可以缓冲Ni₃S₂纳米颗粒在反复充放电过程中产生的体积膨胀效应,明显改善了Ni₃S₂@CNT负极复合材料的电化学性能.     

纳米多孔Ni、Ni3S2/Ni复合电极的制备及其电催化析氢性能

采用脱合金化和水热合成的方法制备纳米多孔Ni和纳米多孔Ni₃S₂/Ni复合电极。通过N2吸附-脱附测试、XRD、SEM、TEM等方法表征电极的孔径分布、物相和微观结构。在1 mol·L^-1的NaOH溶液中,运用线性扫描伏安(LSV)曲线、交流阻抗(EIS)谱图、恒电流电解法等测试电极的电催化析氢性能。结果表明:在电流密度为50 mA·cm^-2时,与纳米多孔Ni相比,Ni₃S₂/Ni合金具有更低的析氢过电位以及更高的析氢活性,同时纳米多孔Ni₃S₂/Ni复合电极具有更低表观活化能和电子转移阻抗,进一步明确了过渡金属硫化物对电催化析氢性能的特殊贡献。     

Zr改性Ni2P/SBA-15催化剂的制备及其加氢脱氧性能

以正丙醇锆（n）和Zr（SO₄）₂（m）为锆源制备了Zr改性的Ni₂P/ZrO₂-SBA-15（n）和Ni₂P/ZrO₂-SBA-15（m）催化剂,并采用XRD、BET、CO吸附、XPS、NH₃程序升温脱附等手段对催化剂进行了表征。以苯并呋喃（BF）为模型化合物,研究了催化剂加氢脱氧（HDO）性能。结果表明,Zr改性后,形成了新的层状结构的ZrP;Zr的引入有助于生成更多、更小粒径的Ni₂P活性相,催化剂的酸强度和酸量均提高。与正丙醇锆相比,Zr（SO₄）₂为锆源能够获得比表面积大、酸性强、酸量大的催化剂,得到更多的ZrP相、更小粒径的Ni₂P晶粒,暴露更多的Ni活性位点。Ni₂P/ZrO₂-SBA-15（n）和Ni₂P/ZrO₂-SBA-15（m）的BF HDO产率分别为71.5%和85.9%,较Ni₂P/SBA-15分别提高了14.0%和28.4%。催化剂HDO活性、脱氧产物选择性和产率大小顺序为：Ni₂P/ZrO₂-SBA-15（m） > Ni₂P/ZrO₂-SBA-15（n） > Ni₂P/SBA-15。     

原始合金制备方法对RaneyNi催化剂结构及加氢活性的影响

骨架镍催化剂由纳米级镍晶粒、未转变的ＮｉＡｌ３和Ｎｉ２Ａｌ３母相及其界面区组成。Ｘ射线衍射及高分辨电子显微观察发现，脱铝过程中ＮｉＡｌ３晶粒碎裂成纳米级尺寸，而Ｎｉ２Ａｌ３相则不出现碎裂现象。     

Molecular dynamics simulation of surface segregation in a (110) B2-NiAl thin film

Surface segregation in (110) B2-NiAl film approximately 3 nm thick is investigated by using molecular dynamics simulation with a reliable embedded-atom potential. The simulation is performed for the stoichiometric composition at a temperature of 1500 K, just below the melting temperature of the film model. It is found that the (110) surface is structurally stable but develops adatoms, vacancies and antisites. The coverage of an adatom layer is estimated to be ～0.07 ML (monatomic layers) and it contains on average ～95% of Al atoms. The top (surface) and second (subsurface) layers of the (110) surface is the most enriched in Ni relative to the bulk composition. These layers contain on average ～51% of Ni atoms. The Ni fraction in the third and forth layers of the film is estimated as ～50.5%. The deeper layers have essentially the bulk composition. Vacancies in the film model are found only on the Ni sublattice. The vacancy concentration on the Ni sublattice in the top layer is ～7.5%. The second layer almost does not contain vacancies. The next layers have essentially the constant bulk vacancy composition which can be estimated as ～1.3-1.4%.     

液体和非晶态NiAl3合金结构的从头算分子动力学模拟

应用从头算分子动力学方法模拟了液体以及淬冷形成的NiAl₃合金体系,得到了它们的对相关函数、结构因子、键对分析信息.结果分析表明,在淬冷条件下得到的体系呈现非晶态性质,且非晶态结构类似于液态NiAl₃合金的结构,可以用液体结构近似描述非晶态性质.还进行了电子结构分析,得到液体NiAl₃合金的电子态密度和电荷分布.在液体镍铝合金中,镍为电子受体,部分电子由铝向镍转移,支持了Candy等人的XPS实验结果.镍铝间强烈作用,形成带有弱共价键性质的金属键.镍在合金中相当分散,这能部分解释由淬冷形成的NiAl₃合金制得的骨架镍催化剂活性增强的原因.     

新型固定床Raney Ni制备过程中晶相结构的转化

以拟薄水铝石制备粘结剂，加入镍铝合金粉和田菁粉捏合、成型，在空气中高温焙烧，然后用苛性碱溶液充分浸取，制备出可应用于固定床加氢的活性Raney Ni催化剂。采用XRD和TG-DTA分析了催化剂制备过程中晶相结构的转化，结果表明，成型合金焙烧过程中，富铝合金相（如Al₃Ni-Al和Al₃Ni）逐渐转变为贫铝合金相（如Al₃Ni₂和AlNi），释放出的金属铝依次发生氧化，同时抑制金属镍的氧化；在高于1 123～1 133K焙烧时金属铝氧化生成α-Al₂O₃，使催化剂获得较高的颗粒强度。苯加氢活性评价结果表明，该新型固定床Raney Ni催化剂活性高于负载型镍催化剂，也高于参照专利方法制备的有机聚合物粘结的同类型催化剂，并且具有较好的低温加氢活性。     

The negative adsorption of chromium atoms on alloy-oxide film boundaries during oxidation in air and anodic passivation of Fe-Cr and Ni-Cr alloys

Equilibrium of Cr atoms between the surface layer and bulk of a binary alloy was analyzed. The Gibbs adsorption equation was used to obtain the dependence of the adsorption activity of atoms in the surface layer on their activity in the bulk. An approximate thermodynamic method was used to calculate the adsorption of Fe (Ni) and Cr atoms in the surface layers of Fe-Cr and Ni-Cr alloys. According to calculations, there was negative adsorption, X _Cr ≪ 1, in the surface layer of the alloys caused by a large difference between the Gibbs surface energies of Cr and Fe (or Ni). The negative adsorption of Cr shifted chemical reaction equilibria on the alloy-oxide film boundary both in oxidation in air and in anodic passivation, 3FeO (NiO) + 2Cr = Cr₂O₃ + 3Fe(Ni), toward oxide film enrichment in the FeO (or NiO) oxide. A unified method for calculating the composition of oxide films on alloys was used for both processes. The method was based on the use of the initial data on the Gibbs surface energy of metals constituting alloys. The calculated oxide film compositions were close to the experimental X-ray photoelectron spectroscopy data.     

Ni／ZrO2-Al2O3制备表征及催化性能的研究

本文采用浸渍沉淀法制备了不同配比的ZrO2-Al2O3复合载体。并通过浸渍法制备Ni/ZrO2-Al2O3催化剂,以苯加氢制环己烷反应为探针,考察了ZrO2与Al2O3的配比对Ni催化剂催化加氢性能的影响;采用X射线衍射(XRD)、程序升温还原(TPR)、程序升温脱附(TPD)等技术考察复合载体对Ni催化剂的体相结构、还原性能以及表面吸附性能的影响。研究结果表明,ZrO2质量分数为20%的复合载体所负载的Ni催化剂有很好的加氢活性,优于单组分载体负载的Ni催化剂;采用浸渍沉淀法制备的ZrO2-Al2O3复合载体中ZrO2以非晶态形式存在,这是由于Al2O3的存在影响了ZrO2的内部结构;该载体负载的Ni催化剂较其他催化剂更容易被还原,吸附中心数量增加。     

Chemical and icosahedral short-range orders in liquid and undercooled Al80Mn20 and Al80Ni20 alloys: a first-principles-based approach

Atomic structures of stable liquid and undercooled liquid Al(80)Mn(20) and Al(80)Ni(20) alloys have been calculated by first-principles molecular-dynamics simulations. For both alloys, the local structure as defined by the Faber-Ziman pair-correlation functions is characterized by a strong Al-transition-metal affinity, which leads to a well-pronounced chemical short-range order which is more temperature dependent for Al(80)Mn(20) than for Al(80)Ni(20). In addition, a structural analysis using three-dimensional pair analysis techniques has been performed in details. More particularly, we find that the fivefold local symmetry around Mn atoms is predominant in both stable and undercooled Al(80)Mn(20) alloys and displays no significant variation with temperatures. On the contrary, in Al(80)Ni(20), a strong variation of the topological short-range order is observed since in the undercooled state, the local environment of Ni atoms is characterized by the predominance of the fivefold symmetry over the close-packed local symmetry which is opposed to what occurs in the stable liquid phase.     

Characterization of rapidly and naturally quenched skeletal iron catalysts for FT synthesis

The slurry phase is a promising system for Fischer-Tropsch (FT) synthesis. Since the liquid medium efficiently removes the heat of reaction so that the steady-state reaction is easily achieved. High catalytic activity is maintained due to removal of waxy products from the catalyst surface by the action of solvent. In addition, CO-rich syngas from coal gasification can be directly used in FT synthesis which may increase the thermal efficiency of the indirect coal liquefaction. One of the important problems to be solved for slurry phase FT is the catalyst attrition and separation from wax residue. Fused iron and Raney iron were found to have high attrition resistance and easy to separate from wax in slurry phase FT synthesis, but their activity is relatively low. Amorphous alloys made by rapid quenching techniques have drawn increasing interest due to their superior mechanical,chemical and magnetic properties compared to the thermodynamically stable crystalline alloys of the same compositions. It is reported that rapidly quenched skeletal Ni catalyst showed higher catalytic activity than Raney Ni in selective hydrogenation of unsaturated organic functional groups.In this paper, Fe50Al50 (by weight) alloys with different quenching rates, rapid quenching (RQ) and natural quenching (NQ) were prepared for FT synthesis. The phase composition of alloys was characterized by XRD. The physical properties, thermal-stability and adsorption properties of skeletal Fe that was prepared by leaching aluminum of the corresponding alloy with aqueous solution of NaOH were also studied by BET, in situ XRD and H2- and CO-TPD. It is found from XRD patterns of the alloys that RQ Fe50Al50 is composed of orthorhombic phase, and NQ Fe50Al50 alloy is mainly composed of monoclinic phase. Meanwhile, diffraction peaks of the RQ alloy are seriously broadened. After leaching aluminum by aqueous solution of NaOH at the same conditions,skeletal Fe from the RQ alloy give the higher specific surface area and larger pore volume. The in -situ XRD shows that skeletal Fe from RQ alloy is composed of elemental iron and magnetite (FeFe2O4) with poor crystalline. The skeletal Fe from NQ alloy is mainly composed of elemental Fe and minor magnetite. The higher content of the magnetite phase in RQ skeletal Fe may arise from the higher activity of the RQ alloy. When the skeletal Fe was heated under Ar flow, the content of magnetite phase increased with temperature and became the main composition at 400℃ for the skeletal Fe from the RQ alloy. For the skeletal iron from the NQ alloy, phase change under heating is less obvious compared with that for the RQ skeletal iron. The H2-TPD profiles of the catalysts showed that two H2 desorption peaks appeared in both NQ and RQ skeletal iron, but the temperatures at maximum desorption rate of RQ skeletal iron were higher than those of the NQ skeletal iron. The CO-TPD experiment showed that NQ skeletal iron had the stronger affinity to CO than RQ skeletal iron. The different properties were explained on the basis of structure.     

A high-resolution photoemission study of nanoscale aluminum oxide films on NiAl(110)

Using high-resolution soft X-ray photoemission, Al 2p, we have been able to quantify the relative populations of tetrahedrally (Al(tet)) and octahedrally (Al(oct)) coordinated Al(3+) in three distinct phases of nanoscale aluminum oxide films on NiAl(110). We have hence determined the bulk alumina phases that the nanoscale films most resemble. Adsorption of oxygen at room temperature produces a layer which predominately (90%) contains Al(tet) and is analogous to the amorphous bulk phase of alumina. Annealing this layer results in an Al enrichment of the oxide layer, through the diffusion of metal from the substrate, and an increase in the relative amount of Al(oct), producing a gamma-alumina-like layer with a relative Al(oct)/Al(tet) occupancy of 28 +/- 3%/72 +/- 3%. Oxygen adsorption at 823 K also produces a gamma-like phase, with a relative Al(oct)/Al(tet) occupancy of 27 +/- 3%/73 +/- 3%, although this layer is thicker than that formed at room temperature. Both oxidation methods produce gamma-alumina layers that display poor translational order. However, these poorly ordered layers have a relative Al(oct)/Al(tet) occupation similar to that of well-ordered oxide films produced using different oxidation conditions in previous studies. Both gamma layers undergo partial decomposition upon annealing to 1273 K, producing an alpha-alumina-like oxide, which contains only Al(oct), and is highly deficient in Al. There are significant oxide-free areas within the alpha-alumina oxide layer, which is characteristic of crystallite formation. Repeated cycles of oxidation and annealing to 1273 K do not produce a homogeneous film, but they do make the alpha-like oxide more Al rich.