KBrO_3在高压下拉曼光谱和结构的研究（英文）

利用原位高压拉曼散射和X射线衍射技术,研究了KBrO3在高压下晶格振动和晶体结构演化行为。最高压力达30.9GPa。通过拉曼光谱发现,在高压下拉曼峰位除了单调移动,没有其它变化,表明KBrO3在研究的压力范围没有发生相变。原位高压X射线衍射实验数据显示,其在高压下依然保持常压的六方结构。通过进一步分析,分别得到了体弹模量B0=25.9(2)GPa(B′0=5.68(0.38))和部分拉曼峰的Grüneisen参数。     

天青石的等温状态方程和拉曼振动研究

利用金刚石对顶砧（DAC）装置产生高压,在室温下、0～32 GPa压力范围,对天青石（SrSO4）进行了原位高压X射线衍射和拉曼光谱研究. 根据高压X射线衍射的数据,测定了天青石的等温状态方程,得到天青石的零压体弹模量KT0＝83GPa（K'T0＝4）, 在所研究压力范围内没有观察到相变的发生. 高压拉曼光谱的数据显示,在5GPa左右,SO4四面体弯曲振动峰发生劈裂,这是由SO4四面体畸变引起的;同时,所有的拉曼振动峰都随着压力的增加而增加, 并且,高频模的平均压力导数要高于低频模的,根据以上数据获得了模格林奈森参数.     

BeO的高压能量色散X射线衍射研究

在北京同步辐射高压站进行了BeO高压原位能量色散X射线衍射实验. 在从常压下加压至42GPa的过程中,BeO保持常压的六方纤锌矿结构(Wurtzite),没有发生相变,晶胞体积随着压力增加单调减小.用Murnaghan方程拟合出BeO在0.6—42.0GPa范围内的P-V状态方程,得到体弹模量K₀=276GPa.     

β-FeSi2的高压研究

 对β-FeSi₂晶体进行了原位X射线衍射高压研究。利用同步辐射X射线衍射原位研究了β-FeSi₂的高压相演化，发现压力在4.3 GPa时出现相变，在25.8 GPa时相变完成。指标化结果表明：经高压处理后得到的产物具有四方结构，其晶格常数为：a=b=1.004 9 nm，c=0.339 4 nm。     

Re_3N的变温拉曼散射与高压同步辐射研究

本工作通过高压固相复分解反应(HPSSM)合成块体Re_3N。利用X射线粉末衍射(XRD)、扫描电子显微镜(SEM)和能量色散X射线分析(EDS)对高压样品进行结构表征与元素成分确定,结果表明利用HPSSM法合成的Re_3N具有较高的晶体质量。在77K到873K温度范围内利用拉曼散射研究Re_3N的晶格振动特性。基于三(四)声子耦合模型,研究Re_3N拉曼声子模频率的红移和拉曼峰的宽化现象,结果表明高温条件下Re_3N拉曼散射效应中三声子耦合过程占主导。高压同步辐射研究表明Re_3N具有很高的体弹模量(B0=417GPa),是一种潜在的超硬材料。     

高压下有机-无机杂化钙钛矿CH_3NH_3PbI_3的结构及光学性质研究

近年来,随着有机-无机杂化钙钛矿太阳能电池的飞速发展,对此类材料基本物性的探索引起了科学家们的广泛关注.本文利用金刚石对顶砧装置对甲胺基碘化铅(CH_3NH_3PbI_3)进行高压实验,研究了室温下压力诱导CH_3NH_3PbI_3的结构变化以及压力对其光学性质的调控,实验最高压力为7 GPa.原位高压同步辐射X射线衍射实验结果显示,CH_3NH_3PbI_3样品在0.3 GPa由四方相转变为正交相,在4 GPa左右开始非晶化.结合原位高压吸收和荧光光谱,分析了压力对CH_3NH_3PbI_3带隙大小的调控作用.进一步利用原位高压拉曼光谱和红外光谱实验研究了CH_3NH_3PbI_3晶体中有机阳离子(CH_3NH_3~+)在高压下的行为.完全卸压后,样品恢复到加压前的初始状态.研究结果可为深入了解有机-无机杂化钙钛矿的光学性质和结构稳定性提供一些信息.     

6H型六方钙钛矿相BaGeO3的高温高压合成

利用金刚石对顶砧高压装置,结合显微激光双面加热技术,对BaGeO_3开展了高温高压实验研究。常温常压下赝硅灰石相的BaGeO_3于12 GPa左右开始非晶化。进一步加压到22 GPa并对已完全非晶化的BaGeO_3样品进行(1 800±200) K的高温处理,拉曼光谱显示其转变成一种未见报道的高压新相。在0～17.4 GPa压力范围对BaGeO_3高压新相开展同步辐射X射线衍射测试,其衍射谱可以用6H型六方钙钛矿相进行指标化,并且卸压到常压时仍保持稳定。以6H型钙钛矿相为结构模型,分别对17.4 GPa和常压下的X射线衍射谱进行Rietveld结构精修,获得其结构参数。应用二阶Birch-Murnaghan状态方程拟合实验体积-压力数据,得到其体弹模量K0=150(2) GPa和零压晶胞体积V0=373.0(3)?3。在实验研究的基础上,对6H型钙钛矿相BaGeO_3进行第一性原理理论计算,所得不同压力下的晶格常数和体积数据与实验结果符合得很好,状态方程参数K0=153(1) GPa,V0=374.2(1)?3。20.0 GPa时计算的拉曼光谱也很好地描述了拉曼实验测量结果。研究结果补充了赝硅灰石相BaGeO_3在更高温压条件下的结构相转变。6H型钙钛矿相BaGeO_3的获得为进一步表征该相的物理化学性质奠定了基础,为开发高性能钙钛矿结构锗酸盐材料提供了可能性,同时对于理解硅酸盐钙钛矿结构的相变规律及稳定性、地球下地幔物理化学性质及其变化等具有重要的指示意义。     

六角相B-C-N化合物的高压相变研究

采用原位高压同步辐射能散X射线衍射和金刚石压砧技术,实验研究了新型超硬材料六角相B0.47C0.23N0.30的高压相变及物理特性,压力范围为1.4～30 GPa.实验结果表明,六角相B..47C0.23N0.30在14.9 GPa压力下发生了相变,形成的新相为六方纤锌矿结构.计算得到了具有六方纤锌矿结构的B0.47C...     

四方相PbTeO3晶体在高压下的压缩行为

利用水热法在230℃以及水的饱和蒸汽压条件下合成出毫米尺寸的四方相PbTeO₃单晶样品,并研究了其晶体结构、微观形貌、热稳定性等性质。利用金刚石对顶砧和同步辐射原位X射线衍射技术,探讨了该四方相PbTeO₃晶体在高压下的压缩行为,发现在0～37 GPa的压力范围内四方相PbTeO₃无相变发生。拟合该PbTeO₃样品的压力-体积数据,得到其体弹模量为B₀=42(1) GPa,体弹模量的一阶导数B’₀=5.5(0.2)。晶格参数随压力的变化显示,该晶体在c轴方向更易压缩。     

高压下六方TaSi_2晶体基于结构稳定性的电学输运性质（英文）

作为一类稳定的低电阻及高温材料,二硅化钽(TaSi_2)被广泛应用于集成电路中。因此,其电学稳定性和结构稳定性同样重要。报导了高压下六方TaSi_2晶体基于结构稳定性的电学输运性质。通过同步辐射X射线衍射和拉曼光谱实验研究了TaSi_2晶体在压力高达20GPa时稳定的结晶学结构,并通过原位高压电阻测量发现,当压力增加到16.3GPa时,TaSi_2的电阻率趋于稳定在2μΩ·cm左右;进一步理论计算了压力下TaSi_2的电子结构,以进一步理解其金属性行为。     

X-ray difffraction studies on samarium up to one megabar pressure

Abstract

High—pressure crystal structure studies have been performed on Sm up to 100 GPa using synchrotron x-radiation and a diamond anvil cell. The structural sequence Sm-dhcp-fcc-dist.fcc has been confirmed. There is no evidence of any volume collapse. The bulk modulus and its pressure derivative have been determined (B₀ = 30.7 GPa, B₀’ = 2.5).     

高压下ZnSe 纳米带的结构相变及拉曼散射研究

 利用高压原位角散X射线衍射实验研究了ZnSe纳米带的结构稳定性。发现样品在12.6 GPa 附近存在一个从立方闪锌矿型到立方岩盐矿型的结构相变,并且在相变点附近存在较大的体积收缩,相对体积变化率达13%。利用Birch-Murnaghan 状态方程拟合,得到了闪锌矿相的体弹模量约为56 GPa,略低于体材料的体弹模量（约67 GPa）;并得到其立方岩盐矿相的体弹模量约为116 GPa。高压拉曼散射实验结果表明,横光学声子模散射峰在5.5 GPa压力附近发生劈裂,纵光学声子模散射峰在12.8 GPa压力以上逐渐消失。根据角散实验的体弹模量数据,计算得到了闪锌矿相中对应不同声子模式的格林爱森常数。     

Ultrastability and enhanced stiffness of approximately 6 nm TiO2 nanoanatase and eventual pressure-induced disorder on the nanometer scale

At 300 K ultrafine approximately 6 nm grain-size nanoanatase retains its structural integrity up to 18 GPa. There is progressive pressure-induced structural disorder to a highly disordered state at P>18 GPa. Signatures of short-range order persist to well beyond 18 GPa in both the synchrotron-x-ray diffraction and Raman data. Molecular dynamics simulations suggest disorder initiated in the surface shell of a nanograin with crystallinity being retained in the core. A bulk modulus B0=237+/-3 GPa for the nanoanatase (approximately 30% higher than the bulk value) is derived from the P-V data, concordant with the MD calculations.     

Phase transitions in KIO(3)

The high-pressure behavior of KIO(3) was studied up to 30?GPa using single crystal and powder x-ray diffraction, Raman spectroscopy, second harmonic generation (SHG) experiments and density functional theory (DFT)-based calculations. Triclinic KIO(3) shows two pressure-induced structural phase transitions at 7?GPa and at 14?GPa. Single crystal x-ray diffraction at 8.7(1)?GPa was employed to solve the structure of the first high-pressure phase (space group R3, a?=?5.89(1) ?, α?=?62.4(1)°). The bulk modulus, B, of this phase was obtained by fitting a second order Birch-Murnaghan equation of state (eos) to synchrotron x-ray powder diffraction data resulting in B(exp,second)?=?67(3)?GPa. The DFT model gave B(DFT,second)?=?70.9?GPa, and, for a third order Birch-Murnaghan eos, B(DFT,third)?=?67.9?GPa with a pressure derivative of [Formula: see text]. Both high-pressure transformations were detectable by Raman spectroscopy and the observation of second harmonic signals. The presence of strong SHG signals shows that all high-pressure phases are acentric. By using different pressure media, we showed that the transition pressures are very strongly influenced by shear stresses. Earlier work on low- and high-temperature transitions was complemented by low-temperature heat capacity measurements. We found no evidence for the presence of an orientational glass, in contrast to earlier dielectric studies, but consistent with earlier low-temperature diffraction studies.     

Structural transformations in single-wall carbon nanotubes under high pressure

Single-wall carbon nanotubes (SWNTs) under high pressure exhibit high structural stability and a series of structural transitions up to 35 GPa. As theoretically predicted, the irreversible transformation of SWNTs in the pressure range of 10–30 GPa can be attributed to the polymerization of nanotubes. The electrical conductivity of SWNTs is studied at high pressures up to 35 GPa using a diamond anvil cell (DAC) with electrically conductive anvils of the “rounded cone-plane” type made of synthetic carbonado-type diamonds. SWNTs are studied before and after the application of high pressure using the Raman confocal microscopy technique. Analysis of Raman spectra and pressure dependences of the SWNT resistance shows that the observed structural changes in SWNTs are reversible and no polymerization or collapse are observed.     

High pressure study of the 2D polymeric phase of C60 by means of raman spectroscopy

Abstract

The effect of high hydrostatic pressure, up to 12GPa, on the intramolecular phonon frequencies and the material stability of the two-dimensional tetragonal Cm polymer has been studied by means of Raman spectroscopy in the spectral range of the radial intramolecular modes (200-800cm^?1). A number of new Raman modes appear in the spectrum for pressures ～ 1.4 and ～ 5.0 GPa. The pressure coefficients for the majority of the phonon modes exhibit changes to lower values at P=4.0 GPa, which may be related to a structural modification of the 2D polymer to a more isotropic phase. The peculiarities observed in the Raman spectra are reversible and the material is stable in the pressure region investigated.     

Structural phase transition of ScSb and YSb with a NaCl-type structure at high pressures

By use of synchrotron radiation, powder X-ray diffraction of ScSb and YSb with a NaCl-type structure has been studied up to 45 GPa at room temperature. A first-order phase transition from the NaCl-type (B1) to a CsCl-type structure (B2) began to occur at around 28 GPa for ScSb and at around 26 GPa for YSb. Crystal data of the high-pressure phase of both antimonides are obtained. The high-pressure structural behavior of ScSb and YSb is similar to that of heavier LnSb (Ln=Dy-Lu). The B1-B2 transition for ScSb and YSb can be understood according to the rigid sphere model. The bulk moduli of ScSb and YSb are about 58 GPa at ambient pressure.     

Raman analysis of insulin denaturation induced by high‐pressure and thermal treatments

Raman spectroscopy has been used to investigate different conformational states of bovine pancreatic insulin: the native form and several structurally modified states with different extent of denaturation induced by thermo‐chemical treatment and by applying very high pressure (up to 8 GPa) using a diamond anvil cell. High‐pressure results confirm the peculiar strength to volume compression of insulin and largely extend the pressure range of its structural stability (0–4.2 GPa). Above 4.2 GPa, insulin undergoes an irreversible structural transition that, once pressure is released, leaves the sample in a new conformational state. The protein secondary structure after the pressure treatment results in a structure that is somewhat intermediate between that of the native and the thermo‐chemical fibrillar samples. The analysis of the pressure dependence of the Raman spectrum and of several specific spectroscopic markers allows us to follow the path from the native to new pressure‐denatured protein conformation. Copyright © 2011 John Wiley & Sons, Ltd.     

石膏的高压原位Raman光谱和相变研究

 利用金刚石对顶砧（DAC）高压装置产生高压,在0~35 GPa压力范围,对石膏（Gypsum,CaSO₄·2H₂O）晶体进行了高压原位Raman光谱研究。根据高压Raman光谱的实验数据,给出了石膏晶体Raman振动频率与压力的依赖关系;在4.5 GPa附近,在对称性伸缩振动范围,发现新的Raman峰1 012  cm^-1出现,这个峰的强度随压力升高逐渐增强,据此断定在4.5 GPa 附近,石膏晶体发生了压力导致的结构相变。     

Effect of high pressure on the crystal and magnetic structure and on the raman spectra in Pr<Subscript>0.7</Subscript>Ba<Subscript>0.3</Subscript>MnO<Subscript>3</Subscript> manganite

The crystal and magnetic structure and the Raman spectra in Pr_0.7Ba_0.3MnO₃ manganite have been studied by the neutron diffraction technique at pressures up to 5 GPa as well as by the X-ray diffraction and Raman spectroscopy at pressures up to 30 GPa. The pressure dependence is determined for the lattice parameters, unit cell volume, Mn-O bond lengths in the orthorhombic structure of the Imma symmetry, and bending and stretching vibration modes for oxygen octahedra. In the low-temperature range at pressure P = 1.9 GPa, the magnetic transition from the initial ferromagnetic (FM) ground state (T _C = 197 K) to the A-type antiferromagnetic (AFM) state (T _N = 153 K) has been revealed. The FM and AFM phases coexist at pressures up to 5.1 GPa and exhibit negative and positive values of the pressure coefficient for the Curie and Néel temperature, respectively (dT _C/dP = −2.3 K/GPa and dT _N/dP = 8 K/GPa). The pressure dependence of the Curie temperature in Pr_0.7Ba_0.3MnO₃ differs drastically from that observed in other manganites of nearly the same composition with the orthorhombic Pnma and rhombohedral R[`3]cR\bar 3c structures, where the FM phase is characterized by the positive values of dT _C/dP. The structural mechanisms of these phenomena are discussed.