Ni_(4)Ti_(3)沉淀相对NiTi形状记忆合金相变行为的影响

采用第二近邻修正型嵌入原子势的分子动力学方法,建立了共格沉淀相与半共格沉淀相块状/柱状模型,模拟了温度诱发相变和应力诱发相变,分析了Ni_(4)Ti_(3)沉淀相对Ni Ti形状记忆合金相变行为的影响.结果表明,Ni_(4)Ti_(3)沉淀相本征应变诱发的弹性应力场对相变中马氏体变体类型、形核位置、分布等有重要影响.在温度诱发相变时,共格沉淀相促进部分马氏体变体的形核生长,能显著提高Ni Ti超弹性形状记忆合金的马氏体相变开始温度;在应力诱发相变时,Ni_(4)Ti_(3)沉淀相使马氏体早于无沉淀相区域形核,导致了相变应力降低、抑制了马氏体解孪,减小了应力-应变曲线的滞回环.

TiNi形状记忆合金中富镍相的析出及其对机械行为的影响

本文评述了近年来有关 TiNi 形状记忆合金的时效及其对合金机械行为的影响方面的文献资料,系统地综述了 TiNi 形状记忆合金时效过程中富镍相的析出行为、析出相的结构及晶体学关系,探讨了富镍相对合金预马氏体相变及马氏体相变、伪弹性及记忆效应影响的机理,并提出了尚待解决的问题。

Pb（Ni_（1／3）Nb_（2／3））O_3－PbZrO_3－PbTiO_3三

对Ｐｂ（Ｎｉ１／３Ｎｂ２／３Ｏ３－ＰｂＺｒＯ３－ＰｂＴｉＯ３，即ｘＰｂ（Ｎｉ１／３Ｎｂ２／３）Ｏ３－（１－ｘ）Ｐｂ（ＺｒδＴｉ１－δ）Ｏ３（０．２≤ｘ≤０．６，０．２≤δ≤０．５）三元系固溶体的压电性能进行了研究，结果表明材料压电活性较高的配方位于准同型相界（ＭＰＢ）附近，压电常数ｄ３１值可达２６０×１０－１２Ｃ／Ｎ．讨论了结构相变对压电性能的影响．

添加Zr的60NiTi合金的热处理工艺优化

60NiTi合金具有高硬度、低密度和耐磨等优异的性能,在航空航天领域有广泛的应用前景。为了进一步提高60NiTi合金的力学性能,研究了Zr的添加及热处理工艺对60NiTi合金组织与硬度的影响。结果表明:Zr的添加提高了60NiTi合金的硬度并使其组织更加均匀。此外,在炉冷、空冷、油冷和水冷4种不同的冷却方式中,炉冷60NiTiZr合金中存在大量粗大的析出相,硬度也最低。冷却速度最快的水冷处理的60NiTiZr合金的硬度最高,且能够避免粗大析出相形成,但存在残余应力较大的问题。对水冷60NiTiZr合金在300~600℃温度范围进行时效处理,发现随时效温度的升高,合金的硬度先升高后降低,且在500℃时效时硬度达到最高。进一步对水冷60NiTiZr合金在500℃进行不同时间的时效处理,发现时效2 h后合金硬度达到峰值(61.7 HRC),时效后期还出现缓慢的二次硬化现象。

改进方法合成钛掺杂锂离子电池三元正极材料

采用改进溶胶-凝胶法合成了具有良好的晶体结构和电化学稳定性的正极材料Li[Ni_(1/3)Co_(1/3)Mn_(1/3)]_(0.9)Ti_(0.1)O_(2),通过优化前驱体的制备来提高原子混合程度,从而达到改善材料循环稳定性的目的。XRD测试表明,样品的Li^(+)/Ni^(2+)混排程度很低,TEM图片显示材料的结晶度很高,原子排列有序,这有利于实现更大的锂离子扩散系数。在0.5 C倍率下循环200次后,材料的容量保持率高达84.6%,与未掺钛的LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)仅为52.0%相比,钛掺杂的材料表现出优异的电化学性能。此外,掺钛材料在0.1、0.2、0.5、1.0、2.0和5.0 C时具有更好的充放电倍率性能,分别为164.9、162.4、152.4、142.4、129.7和102.8 mAh/g。研究成果可以为设计具有更好电化学性能的锂离子电池材料提供参考。

Ti_(3)(Zn_(x)Al_(1-x))C_(2)固溶体热学、电学和力学性质的理论研究

采用第一性原理的密度泛函理论平面波赝势法,通过投影缀加波(PAW)和广义梯度近似(GGA)系统地研究了Ti_(3)(Zn_(x)Al_(1-x))C_(2)的结构、能量、声子性质、电子性质和弹性性质。对MAX相Ti_(3)AlC_(2)晶体中A位置的Al元素用Zn元素进行替换掺杂,构建出Ti_(3)(Zn_(x)Al_(1-x))C_(2)(x=0,0.25,0.5,0.75,1)固溶体结构模型。计算分析表明:在所研究的掺杂浓度范围内Ti_(3)(Zn_(x)Al_(1-x))C_(2)均是热力学、动力学和力学稳定的脆性材料;此外,Ti_(3)(Zn_(x)Al_(1-x))C_(2)(x=0,0.25,0.5,0.75,1)均呈现金属性,在费米能级处的电子态密度主要贡献来自Ti-3d态,同时具有离子键、共价键和金属键的综合性质。随着Zn原子掺杂浓度的增加,在一定程度上其导电性和塑性均增强。

Dielectric polarization in MgFe_(2)O_(4) coating and bulk doping to enhance high-voltage cycling stability of Na_(2/3)Ni_(1/3)Mn_(2/3)O_(2) cathode material

Charging P2-Na_(2/3)Ni_(1/3)Mn_(2/3)O_(2)to 4.5 V for higher capacity is enticing.However,it leads to severe capacity fading,ascribing to the lattice oxygen evolution and the P2-O2 phase transformation.Here,the Mg Fe_(2)O_(4) coating and Mg,Fe co-doping were constructed simultaneously by Mg,Fe surface treatment to suppress lattice oxygen evolution and P2-O2 phase transformation of P2-Na_(2/3)Ni_(1/3)Mn_(2/3)O_(2)at deep charging.Through ex-situ X-ray diffraction(XRD)tests,we found that the Mg,Fe bulk co-doping could reduce the repulsion between transition metals and Na+/vacancies ordering,thus inhibiting the P2-O2 phase transition and significantly reducing the irreversible volume change of the material.Meanwhile,the internal electric field formed by the dielectric polarization of Mg Fe_(2)O_(4) effectively inhibits the outward migration of oxidized O^(a-)(a<2),thereby suppressing the lattice oxygen evolution at deep charging,confirmed by in situ Raman and ex situ XPS techniques.P2-Na NM@MF-3 shows enhanced high-voltage cycling performance with capacity retentions of 84.8% and 81.3%at 0.1 and 1 C after cycles.This work sheds light on regulating the surface chemistry for Na-layered oxide materials to enhance the high-voltage performance of Na-ion batteries.

Variant selection map of external load during Ni_(4)Ti_(3) precipitation in nitinol:a theoretical and phase field study

The morphology of Ni_(4)Ti_(3) precipitates is important in tuning the martensitic transformation(MT)behavior and mechanical properties of nitinol.Constrained ageing is effective in engineering the morphology of Ni_(4)Ti_(3) precipitates due to the variant selection effect of external load which is still lacking.In this work,maps of variant selection effect of external load applied along all crystallographic directions are obtained by using a combination of theoretical analyses and phase field simulations.It is found that maps produced by uniaxial tension and uniaxial compression are quite different.The number and types of Ni_(4)Ti_(3) variants preferred by external load vary as the loading direction changes.Moreover,factors influencing the strength of variant selection effect are discovered.This work provides insights on understanding the Ni_(4)Ti_(3) precipitation process and sheds light on the engineering of morphology of Ni_(4)Ti_(3) precipitates for desired mechanical and functional properties.

Ti_(1)Li_(3)Al_(2)-LDHs/g-C_(3)N_(4)复合材料的制备及其光催化CO_(2)-甲苯反应特性

光催化CO_(2)还原是实现CO_(2)绿色转化利用的重要途径之一,但一直受其反应转化效率低的制约。开发新的CO_(2)还原反应体系和提高光催化剂的可见光利用率及光生电子与空穴的分离效率是解决上述问题的有效方法。本文利用甲苯作为底物,构建了光催化CO_(2)-甲苯耦合反应的新体系,并通过静电组装法合成了Ti_(1)Li_(3)Al_(2)-层状双氢氧化物(LDHs)/石墨相氮化碳(g-C_(3)N_(4))复合光催化剂。重点研究了该复合光催化剂的光电性质及在CO_(2)-甲苯耦合反应体系中的光催化反应特性。结果表明,在光催化CO_(2)-甲苯耦合体系中,Ti_(1)Li_(3)Al_(2)-LDHs/g-C_(3)N_(4)作用下,CO_(2)被还原为CO,甲苯被氧化为苯甲醇、苯甲醛及苯甲酸苄酯,其中苯甲醛和苯甲醇的含量可达到4.80和4.70 mmol/gcat。这主要归因于Ti_(1)Li_(3)Al_(2)-LDHs/g-C_(3)N_(4)中,g-C_(3)N_(4)将Ti_(1)Li_(3)Al_(2)-LDHs在紫外区的吸收扩展到了可见光区,并提高了Ti_(1)Li_(3)Al_(2)-LDHs的分散性,从而为光催化反应提供更多的活性位点;Ti_(1)Li_(3)Al_(2)-LDHs/g-C_(3)N_(4)的界面处形成了S型异质结,有利于界面处的光生电子的转移,提高了其光生电子与空穴的分离效率,而甲苯可作为有机底物加快空穴的消耗速度促进了CO_(2)还原反应的进行。为CO_(2)与小分子有机物协同转化提供了一种新思路。