高铁锻钢制动盘热疲劳裂纹扩展仿真及寿命评价

巨大的制动热能导致高铁制动盘面出现热斑或热点,形成沿径向扩展的热疲劳裂纹,严重危及行车安全.通过仿真获得热疲劳裂纹扩展规律,据此制定出合适、经济的检测周期,具有重要意义.基于断裂力学理论,采用扩展有限单元法和自主研发的裂尖网格加密技术,得到热点形成规律,植入半椭圆形裂纹进行热疲劳断裂仿真,得到制动速度为400 km/h...     

车轮多边形激励下高速列车制动界面摩擦学行为分析

高速列车车轮多边形磨耗是一种沿车轮周向的不均匀磨耗,是列车服役过程中常见的车轮失效现象,其产生的剧烈轮轨激励严重威胁车辆系统服役可靠性.制动系统作为保障高速列车服役安全的核心部件,其界面摩擦学行为直接受到轮轨激励的影响.为探究车轮多边形激励下的制动界面摩擦学行为,建立了刚柔耦合车辆动力学模型和制动系统热机耦合有限元模型,并分别通过线路试验和台架试验验证了模型的正确性.然后,提出一种考虑车轮多边形激励的制动界面摩擦学行为分析方法,能够真实地反映服役过程中制动界面摩擦学行为.基于此,研究了不同车辆运行速度下车轮多边形激励对制动系统动态接触、温度以及振动特性的影响规律.结果表明：车轮多边形磨耗导致系统接触面积、摩擦热、接触应力和振动等摩擦学行为更为复杂且剧烈.此外,系统接触面积标准差和振动加速度均方根值随速度的增加而增大.因此,车轮多边形磨耗对制动界面摩擦学行为具有不可忽略的影响.该研究成果可为制动系统界面摩擦学行为研究及结构优化设计提供有效方法与工程指导.     

Comments on the symmetry relations in the hyperon radiative decays

We demonstrate that in general Hara's theorem which gives various symmetry relations for the hyperon radiative decays is not valid. The new relations we derive are different from those given by Hara. But for the Σ⁺→P_γ decay, the asymmetry parameter is still zero in the exact SU(3) limit.     

一个新颖的三维异核锑(Ⅲ)-镨(Ⅲ)配合物[Sb2-μ4-(EDTA)2Pr(H2O)5]NO3·4H2O的合成、晶体结构及热分解研究

合成了锑-镨与乙二胺四乙酸形成的新颖三维配合物[Sb2-μ4-(EDTA)2Pr(H2O)5]NO3·4H2O,用元素分析、红外光谱、热分析及X射线单晶衍射法等进行了组成和结构表征.结果表明该配合物属正交晶系,空间群Pnn2;晶胞参数:a=1.07031(2)nm,b=2.30805(4)nm,c=0.72343(2)nm,V=1.78711(7)nm3,Z=2,Dc=2.202g/cm3,F(000)=1164,μ=2.955mm-1,GOF=1.000,最终偏离因子R1=0.0203,wR2=0.0545[I>2σ(Ⅰ)].在标题化合物中,每个镨(Ⅲ)离子的配位数为9,与五个水分子中的五个氧原子和四个羧基氧原子配位,形成三帽三角棱柱空间配位多面体.锑(Ⅲ)与EDTA离子中的四个氧原子和两个氮原子配位,在赤道平面上有一孤对电子.同时讨论了配合物的热分解过程.     

Synthesis of 15P-Conjugated PPy-modified Gold Nanoparticles and Their Application to Photothermal Therapy of Ovarian Cancer

In this work, we synthesized the polypyrrole（PPy） modified gold nanoparticles and demonstrated their negligible cytotoxicity in vitro. These nanoparticles have also been demonstrated to efficiently ablate different kinds of tumor cells in vitro under the irradiation of the near-infrared laser. When the PPy modified gold nanoparticles were conjugated with the tumor-targeted molecule of 15P（sequence： SHSWHWLPNLRHYAS）, these conjugates displayed hyperthermia effects on the human ovarian cancer cell line SK-OV-3 cells in vitro under the irradiation of near-infrared laser, showing great tumor-targeted treatment efficiency. To determine the potential hyperthermia effect of PPy modified gold nanoparticles or 15P-conjugate on tumor cells in vivo, the SK-OV-3 cells were used to induce the subcutaneous tumor-bearing nude mice. The significant inhibition effects of near-infrared laser mediated PPy modified gold nanoparticles or 15P-conjugate on the tumor growth were observed. These composite results suggest that the 15P-conjugated PPy modified gold nanoparticles exhibit great biocompatibility, particularly tumor-targeted effect and the effective photothermal ablation of tumor cells, which warrants the potential therapeutic value of this conjugate for further application to the in vivo localized tumor therapy.     

Cathepsin B-responsive nanodrug delivery systems for precise diagnosis and targeted therapy of malignant tumors

The tumor microenvironment (TME) significantly influences cancer evolution and therapeutic efficacy. Targeting biofunctional molecules to the TME has long been appreciated as a means of raising local drug concentrations and reducing systemic toxicities. The booming nanotechnology field has realized the importance of cathepsin B to derive a variety of intelligent enzyme-responsive nanosized drug delivery systems (nanoDDS) to improve treatment responses and clinical outcomes. In this tutorial review, after introducing the molecular structure and physiological/pathological functions of cathepsin B, the outstanding achievements of cathepsin B-responsive nanoplatforms in the precise diagnosis, targeted therapy, and synergistic theranostics of malignant tumors are systematically described. Finally, the challenges of enzyme-substrate incompatibility, low diagnostic sensitivity, mass production and biocompatibility of multifunctional nanoDDS are considered in order to successfully promote them to clinical applications     

新型脱氧胆酸钳形阴离子受体的设计合成及其对阴离子的识别性能研究

具有对阴离子选择性识别的人工受体的设计合成是生物有机化学和超分子化学前沿富于挑战性的领域之一[1].在许多识别阴离子的人工受体化合物中,脲和硫脲衍生物是重要的中性受体化合物之一.     

活化条件对活性碳纳米管比表面积的影响

以KOH为活化剂, 研究了多壁碳纳米管在制备活性碳纳米管过程中四个重要影响因素: 活化剂用量、活化温度、活化时间和活化过程中保护气体的流速对所得活性碳纳米管BET比表面积的影响并解释了原因. 研究表明上述四个因素都会对活性碳纳米管的比表面积产生较大的影响, 其中活化剂用量的影响最大, 在研究范围内可引起比表面积增大约241 m²•g^-1. 在这四个影响因素中除活性碳纳米管的比表面积随活化温度的增加而不断增加外, 其他三个影响因素的变化都会使活性碳纳米管的比表面积出现最大值, 而且四个影响因素的改变, 都不改变活性碳纳米管的孔洞主要是中孔和大孔的特点.     

压电胰岛素-C肽微阵列免疫传感器研究

以AT切型、基频10MHz的镀金膜石英晶体作为换能器,将抗人胰岛素和C肽单克隆抗体固定在石英晶体电极表面,用2×5检测池固定夹具构建一种新型压电胰岛素-C肽微阵列免疫传感器.研究了抗体固定方法、抗体工作浓度、固定量、一致性以及传感器的响应参数如检测温度、时间和特异性等的影响.该微阵列传感器在胰岛素浓度为2.5～160.0mIU/L、C肽浓度为0.375～12.0ng/mL范围内响应特性良好,压电晶体频率偏移值与胰岛素和C肽浓度呈良好的线性关系.将此微阵列传感器用于人血清标本的测定,结果与放射免疫法符合(r为0.92和0.94).此微阵列传感器具有灵敏度高、特异性好,低密度阵列结构,检测通量较高,不需标记,操作简单、能实时在线检测和重复使用等优点,能用于临床实验诊断,具有临床推广应用价值.