PbTe的高温高压合成

 以高温高压为手段，在4～5GPa压力和700～1 200 K温度条件下，成功地合成出了PbTe。对合成样品进行了X射线测试分析，结果表明，合成的PbTe样品是具有NaCl结构的多晶，而PbTe的取向随着合成压力的升高发生变化。扫描电镜分析结果显示：高压合成的PbTe样品，其晶粒有了明显的取向；电阻率比常压样品低1～2个数量级，并随合成压力的升高而降低；热导率也同时低于常压合成的PbTe样品。以上结果说明，高压合成方法是改善材料性能的重要手段。     

纳米晶钛酸铅镧体系的软模及铁电相变研究

采用Raman散射方法系统研究了Pb_1-xLa_xTiO₃(PLT)的软模行为和铁电相变.结果表明,随着晶粒尺寸的减小,Pb_0.86La_0.14TiO₃(PLT14)能从常温常压下的四方铁电相转化为立方顺电相;在高温常压及常温高压下纳米晶PLT14的相变温度和压力均比体材料情况下低;对于不同晶粒尺寸的PLT体系,系统从四方相转化为立方相的相边界随晶粒尺寸的减小移向更低的La离子浓度,还论述了软模随晶粒尺寸、温度、压力和La离子浓度的变化行为以及系统发生相变的机制.     

Effects of High Pressure on BC3

High-pressure phases of BC3 are studied within the local density approximation under the density functional theory framework. When the pressure reaches 20 GPa, the layered BC3 that is a semiconductor at ambient pressure, becomes metallic. As the pressure increases, the material changes into a network structure at about 35 GPa. To understand the mechanism of phase transitions, band structure and density of states are discussed. With the increase of pressure, the width of bands broadens and the dispersion of bands enlarges. Additionally, the density of states of the network bears great resemblance to that of diamond. Formation of the sp3 bonding in the network is the main reason for the structural transformation at 35 GPa.     

Effects of high pressure on the Raman and fluorescence emission spectra of two novel 1,3,4-oxadiazole derivatives

The effects of pressure on the fluorescence emission and Raman spectra of 1,4-bis[（4-methyloxyphenyl）-1,3,4-oxadiazolyl]- 2,5-bisheptyloxyphenylene （OXD-2） and on the fluorescence emission spectra of 1,4-bis[（4-methylphenyl）- 1,3,4-oxadiazolyl]phenylene （OXD-1） are investigated using a diamond anvil cell. With the increase of pressure, the intensity of the fluorescence emission increases and reaches maxima at 13GPa for OXD-1 and at 9.6GPa for OXD-2. The effect of pressure on the peak position of the emission shows a similar trend, red shift with the increase of pressure. But at higher pressures, the intensity of emission drops down dramatically. The Raman spectra of OXD-2 indicate that there appears a structural change at ca 3GPa.     

Structural Phase Transformations of ZnS Nanocrystalline Under High Pressure

In-situ energy dispersive x-ray diffraction on ZnS nanocrystalline was carried out under high pressure by using a diamond anvil cell. Phase transition of wurtzite of 10nm ZnS to rocksalt occurred at 16.0GPa, which was higher than that of the bulk materials. The structures of ZnS nanocrystalline at different pressures were built by using materials studio and the bulk modulus, and the pressure derivative of ZnS nanocrystalline were derived by fitting the equation of Birch-Murnaghan. The resulting modulus was higher than that of the corresponding bulk material, which indicates that the nanomaterial has higher hardness than its bulk materials.     

MgO在Mg-hBN体系中对合成cBN晶体的影响

 以金属镁粉为触媒，以六角氮化硼为原料，其中加入适量比例的氧化镁，在国产六面顶压机上，在约5.0 GPa压力、1 500～1 800 K温度条件下，合成出了颜色均匀、晶形完整的黄色立方氮化硼单晶体。实验结果表明，在Mg-hBN体系中，氧化镁对合成cBN晶体的颜色及合成温度有很大的影响。     

氮化硼固相转变的船形模型

 船形转变模型是有rBN结构向wBN结构的固相转变模型。在静高压下，相比于以椅形方式，rBN更容易以船形方式转变。     

室温下压致铁钴镍合金的bcc→hcp相变

 本文采用高压X光衍射方法在金刚石对顶压砧中在位地（in situ）研究了Fe₆₈Co₂₄Ni₈（wt%）合金在室温下的压致bcc→hcp结构相变和直到40.5 GPa的等温压缩行为。实验结果表明该合金在常压下为bcc结构，晶格常数a₀=(0.287 0±0.000 1) nm，体积V₀=(7.119±0.007) cm³/mol，密度ρ₀=(7.981±0.008) g/cm³；在20.9 GPa附近出现bcc→hcp结构相变，两相共存压力区约10 GPa，在此区域内有晶面间距d(002)_hcp=d(110)_bcc，且原子平面(002)_hcp//(110)_bcc，hcp相比bcc相体积减小(0.33±0.02) cm³/mol；高压相hcp结构的晶格参数比值c/a=1.608±0.004；相变后原子配位数的增加使得hcp相(002)平面内及(002)平面间的最近邻原子间距比bcc相最近邻原子间距分别增大约1.6%和0.5%；用Murnaghan状态方程对实验数据进行最小二乘法拟合，得到bcc相B₀=(130±13) GPa，B₀'=12.6±0.5；hcp相V₀=(6.62±0.04) cm³/mol，B₀=(243±21) GPa，B₀'=6.8±0.3；对于该合金的bcc→fcp相变时的结构转变机制做了详细的讨论。     

纳米氮化镓的拉曼光谱研究

纳米氮化镓的拉曼光谱研究罗薇邹广田崔启良赵永年崔田李红东韩杰（吉林大学超硬材料国家重点实验室长春１３００２３）ＳｔｕｄｙｏｆＲａｍａｎＳｐｅｃｔｒａｏｎＧａＮＮａｎｏｃｒｙｓｔａｌＬｕｏＷｅｉ，ＺｏｕＧｕａｎｇｔｉａｎ，ＣｕｉＱｉｌｉａｎｇ，Ｚｈａｏ...     

球笼烯（C_（60）／C_（70）载体钕系催化丁二烯聚合的研究

球笼烯（Ｃ_（６０）／Ｃ_（７０）载体钕系催化丁二烯聚合的研究赵春英，陈滇宝，仲崇祺，董文寰，徐玲，唐学明（青岛化工学院高分子材料系青岛２６６０４２）杨海滨，李明辉，邹广田（吉林大学超硬材料国家重点实验室长春１３００２３）关键词球碳载体钕系催化剂，聚丁...