TiNi和TiNiCu记忆合金可逆应变能与温度的经验关系

在实验基础上研究了Ti_(50)Ni_(50),Ti_(50)Ni_(45)Cu_2)和Ti_(50)Ni_(45)Cu_5的可逆形状记忆效应,得到可逆应变能U_r与温度的经验关系: U_r=U_0[1-exp(-mT_R^N)] 式中,n是形状一温度敏感指数,m是与材料特性有关的常数.移植Johnson-Mehl-Avrami描述相变-时间关系的唯象方法,得到与可逆形状记忆效应相伴随的热弹性马氏体相变与温度的半定量关系,且与上述经验关系对应.

拉伸应变对Bi-2223银及银合金包套带材临界电流的影响

研究了Bi-2223带材的应力-应变特征,比较了包套材料、芯丝数目和Ag/超比例对Bi-2223带材不可逆拉伸应变的影响。实验发现,采用高强度的AgMn合金包套材料可提高芯丝的残余压应变,并通过提高Ag/超界面的平整性,减少因为界面不均匀而产生的应力集中,芯丝中微裂纹的出现和扩展将被延迟到更高的应变状态,因此可显著提高带材的不可逆拉应变。同时,通过增加芯丝数量和Ag/超比例也可增强带材抗拉伸应变能力。

多孔形状记忆合金的变形特性及热-机械循环对形状记忆性能的影响

研究了传统粉末烧结制备工艺及热－机械循环压缩变形对多孔ＮｉＴｉ形状记忆合金变形和记忆特性的影响结果表明，随烧结温度升高，合金的轴向应变恢复率和弹性应变均显著提高可见，提高烧结温度有利于合金的形状记忆和弹性性能同时发现，少量（二次）热－机械循环压缩变形可显著提高合金的应变恢复率和可逆应变。

三轴循环荷载下砂岩变形及损伤力学试验研究

在MTS815 Flex Test GT岩石力学试验系统上,对砂岩进行单轴压缩和三轴循环加卸载试验。结果表明,砂岩的侧向变形和体积变形都与岩石破坏有密不可分的关系;岩石微裂纹的压缩和释放并不一致,内凹现象和推进效应是岩石内部微裂纹压密、闭合、扩展等引起的;在循环加卸载持续作用下,岩石的破坏是一个累积的过程;滞回环面积受到围压、荷载大小和加载次数的影响;轴向和侧向累计不可逆应变在循环荷载作用下的增长趋势呈线性关系,围压的增大可有效限制岩石侧向累计不可逆应变。

粗粒土与结构接触面受载过程中的损伤

进行了粗粒上与结构接触面单调和循环加载试验,基于宏细观测量结果,扩展了损伤概念以描述该类接触面在受载过程中的物态演化,及由于物态演化导致的力学特性从初始状态到最终稳定状态的连续变化过程.揭示了接触面损伤的细观物理基础主要是接触面内土的颗牲破碎和剪切压密这两种物态演化;指出接触面的剪胀体应变可以划分为可逆性和不可逆性剪胀体应变两部分,其中不可逆性剪胀体应变可作为接触面损伤发展的宏观量度,因此其归一化形式可作为一种损伤因子的定义;提出了建立粗粒土与结构接触面一种损伤本构关系的基本思路.

三轴循环荷载作用下混凝土的力学性能及损伤特征研究

开展了不同循环加卸载(荷载分别为单轴抗压强度20%、30%、40%、50%、60%、70%和80%)作用下的三轴试验,研究了不同循环荷载作用对灌注桩混凝土力学性能的影响,并分析了混凝土的损伤特征。结果表明:在各级循环加卸载作用下,混凝土的应力-应变曲线出现内凹和右移推进现象;弹性模量随循环次数的增加先增加后减小;在各级循环内,泊松比呈“减小-稳定-增大”的变化规律,第90次循环后超过名义泊松比,混凝土损伤逐渐积累加深,轴向和横向不可逆应变均随循环次数的增加而增加;屈服阶段前混凝土的累计损伤小,屈服阶段后混凝土的横向累计损伤参数比轴向大。

基于GTN损伤模型的塑性粘结炸药棘轮增长模拟

基于GTN损伤模型对热循环下塑性粘结炸药(PBX)的不可逆变形进行研究时,由于该模型大多应用于韧性金属材料的损伤演化研究,因此需要通过研究各参数对计算结果的影响,开展GTN模型用于描述PBX在热循环中产生不可逆应变的适应性研究。对PBX炸药件进行-30~60℃的热循环处理,以炸药件柱面中间位置的应变为目标量,采用有限元分析软件Workbench中的多目标遗传算法对各参数进行多目标优化,得到基准参数集。逐一变化各参数,对比分析参数变化取值时基于GTN模型对不可逆膨胀规律描述的影响。结果表明:通过调节、优化初始屈服强度、硬化指数及各GTN模型参数值,GTN模型可以用来定量描述PBX在热循环加载下的不可逆膨胀规律。

循环荷载下煤岩弹塑性损伤的能量机制分析

为探究采动应力周期性扰动下煤岩的损伤变形及能量演化机制,利用含瓦斯煤热-流-固耦合三轴伺服渗流试验装置,开展不同稳定时间下煤岩三轴循环荷载试验;基于能量参数分析,推导出循环荷载作用下煤岩弹塑性损伤变量计算公式,分析煤岩弹塑性损伤演化行为。研究结果表明:不同稳定时间下煤岩主应力差-轴向应变曲线呈现周期性滞回环演化趋势,在稳定时间和外部荷载下弹性模量并没有随循环次数的增大而减小,煤岩损伤机制发生变化;煤岩吸收的总能量U与耗散能Ud随循环次数的增加总体变化趋势为L型,弹性能Ue逐渐减小而后趋于稳定;基于能量计算的煤岩弹塑性损伤变量值在30次循环荷载过程中,均在一稳定值附近呈波动性稳定变化趋势。

Improved nitrogen reduction electroactivity by unique MoS_(2)‐SnS_(2) heterogeneous nanoplates supported on poly(zwitterionic liquids)functionalized polypyrrole/graphene oxide

Unique MoS_(2)‐SnS_(2)heterogeneous nanoplates have successfully in‐situ grown on poly(3‐(1‐vinylimidazolium‐3‐yl)propane‐1‐sulfonate)functionalized polypyrrole/graphene oxide(PVIPS/PPy/GO).PVIPS can attract heptamolybdate ion(Mo7O246−)and Sn^(4+)as the precursors by the ion‐exchange,resulting in the simultaneous growth of 1T’‐MoS2 and the berndtite‐2T‐type hexagonal SnS_(2)by the interfacial induced effect of PVIPS.The obtained MoS_(2)‐SnS_(2)/PVIPS/PPy/GO can serve as electrocatalysts,exhibiting good NRR performance by the synergistic effect.The semi‐conducting SnS_(2)would limit the surface electron accessibility for suppressing HER process of 1T’‐MoS_(2),while metallic 1T’‐MoS_(2)might efficiently improve the NRR electroactivity of SnS_(2)by the creation of Mo‐Sn‐Sn trimer catalytic sites.Otherwise,the irreversible crystal phase transition has taken place during the NRR process.Partial 1T’‐MoS_(2)and SnS_(2)have electrochemically reacted with N_(2),and irreversibly converted into Mo^(2)N and SnxNz due to the formation of Mo−N and Sn−N bonding,meanwhile,partial SnS_(2) has been irreversibly evolved into SnS due to the reduction by the power source in the electrochemical system.It would put forward a new design idea for optimizing the preparation method and electrocatalytic activity of transition metal dichalcogenides.

Reversible magnetocaloric effect and refrigeration capacity enhanced by two successive magnetic transitions in DyB2

A large and reversible magnetocaloric effect is found in the compound DyB2, which is associated with two successive mag- netic transitions： a spin-reorientation-like transition followed by a ferromagnetic-paramagnetic transition. These two transitions appreciably enlarge the magnetic-refrigeration temperature window and yield a huge refrigeration capacity of 610 J kg^-1, with a maximum magnetic entropy change -ASmax of 17 J kg^-1K^-1, at a magnetic-field change of 5 T. The corresponding values for low magnetic-field change of 2 T are 193 J kg^-1 and 7.4 J kg-lK^-1, respectively.

Monitoring disulfide bonds making and breaking in biological nanopore at single molecule level

Monitoring subtle changes in ionic current flow through a nanopore could be applied to observe single molecule reaction. Here,we introduced cysteine to substitute for lysine at position 238 constructing a mutant aerolysin K238 C. It could be regarded as a nanoreactor to efficiently visualize chemical bonds making and breaking. The compound 5,5′-dithiobis-(2-nitrobenzoic acid)(DTNB) was selected as a reactant coming into collisions on the interface of the pore to occur a reversible reaction. Our results showed that the mutant aerolysin could respond to three molecules of DTNB simultaneously and reflect corresponding levels with distinguishable current signals. Therefore, this method constitutes a simple, generic tool for monitoring single molecule reaction, which evokes a guidance for the mutant aerolysin towards the application of tracking other more reactions at single molecule level.