0.1~800 MPa压力下方解石拉曼光谱的实验研究

 利用石英的拉曼谱峰与温度和压力的关系，检验了在金刚石压腔中用方解石拉曼谱峰确定体系压力的可行性，并初步确定了在常温下方解石的拉曼谱峰与压力的关系。实验研究结果表明：在实验的压力范围内方解石稳定，且其1 085 cm^-1 谱峰约为石英464 cm^-1谱峰的3倍强度，因此非常适合作为热液金刚石压腔的压力标定物。在温度26 ℃、压力0.1~800 MPa条件下，方解石的拉曼谱峰（1 085 cm^-1）随着压力的增加，呈线形增大，其关系式为：p(MPa)=192×(ν_p－1 085)－21.8，1 085 cm^-1<ν_p<1 090 cm^-1。     

常温高压下水的拉曼谱峰标定压力的研究

 利用金刚石压腔测定了26 ℃高压下水的O—H伸缩振动拉曼谱峰的变化,并对其进行分峰处理,初步确定了水的拉曼拟合峰ν_{3 244}的峰位置与体系压力的关系,且论证了利用水的拉曼拟合峰ν_{3 244}的变化标定金刚石压腔压力的优点以及应用上的局限性。实验结果表明：26 ℃时,在实验的压力范围内,由水的拉曼谱峰拟合得到的ν_{3 244}峰位置随着体系压力的增加呈线性减小。其关系式为p (MPa)=32.9(ν_p)_{3 244}+200.7（3 215 cm^-1< ν_{3 244}<3 244 cm^-1）。     

压力对GdoBr:Eu晶场参数的影响

 在室温下测量了GdoBr:Eu的常压和高压荧光谱，光谱范围在13 000~21 500 cm^-1之间，压力至12 GPa。由光谱数据得到了Eu³⁺晶场能级随压力的变化曲线。⁷F_0～5能级随压力的变化规律比较复杂，而⁵D_0~2各能均随压力的升高几乎线性地降低。在基态谱项⁷F的49个状态上进行了晶场拟合计算，所得常压下的5个非零晶场参数分别为：B₀²＝-1 124.0 cm^-1，B₀⁴＝-969.6 cm^-1，B₄⁴＝827.9 cm^-1，B₀⁶＝889.6 cm^-1，B₄⁶＝377.0 cm^-1。高压下的计算结果表明，B₀⁴、B₀⁶这两个晶场参数随压力的增加而增大，B₄⁶随压力的增加而减小，而B₀²、B₄⁴随压力的变化有些起伏。晶场强度在8 GPa以下随压力增加而减小，其后开始变强。     

立方氮化硼的振动光谱及反射光谱的研究

 将黑色、黄色、棕色三种小于50 μm立方氮化硼粉末为样品，研究了其红外光谱、拉曼光谱、反射光谱，结果表明：（1）样品的红外光谱中，1 818 cm^-1和1 548 cm^-1属于cBN的晶格本征振动，而立方氮化硼的晶格本征振动外的晶体缺陷吸收则发生在~800 cm^-1，1 580 cm^-1~1 740 cm^-1和大于2 400 cm^-1处。（2）拉曼光谱测试表明，在1 052 cm^-1和1 304 cm^-1附近出现的散射与cBN不具有反演中心及cBN具有立方结构这样的事实相一致，并且这种散射伴随着布里渊区中心声子的横向和纵向发射。144 cm^-1附近出现的散射，被认为是由于局部振荡模式的出现，在反斯托克斯区造成的信号，这与晶格中杂质缺陷有关。（3）依据得到的反射光谱，计算了cBN单晶禁带宽度，发现这三种cBN都具有大于金刚石的禁带宽度值，分别为：E_g(黑)=6.21 eV，E_g(黄)=5.73 eV，E_g(棕)=5.71 eV。     

高压下FexN化合物的相分解

 本文研究了室温下压力对Fe_xN化合物相分解的影响。X射线衍射分析表明，高压促使氮原子从Fe_xN化合物的晶格中脱溶出来，引起相分解，形成母相与α-Fe。这种相分解现象随压力增大而加强。通过分析不同压力下母相Fe_xN与α-Fe的相对含量，研究了氮从Fe_xN中脱溶的动力学过程，并计算出激活体积。对于Fe₃N和Fe₄N化合物，其激活体积分别为2.24×10^-5 m³/mol和1.62×10^-5 m³/mol。本实验还指出，通过对Fe_xN化合物的高压处理以及适当条件下退火，可以获得Fe₁₆N₂化合物。     

高压对以沸石分子筛基质的Eu（Ⅲ）稀土发光材料荧光光谱影响的研究

 本文研究了高压下无机微孔材料的相转变，并讨论了压力对离子交换的Eu（Ⅲ）NaA和Eu（Ⅲ）NaY两种以沸石分子筛为基质的稀土发光材料发光性质的影响。实验结果表明，对于不同基质材料，压力对Eu（Ⅲ）离子的光谱结构的影响，尤其是对⁵D₀→⁷F₁磁偶极跃迁与⁵D₀→⁷F₂电偶极跃迁强度比（I_m/I_e）的影响十分显著。对于Eu（Ⅲ）NaA样品来说，I_m/I_e值随压力的增加而增加，而对于Eu（Ⅲ）NaY样品，I_m/I_e值随压力的增加而减少。     

PbMoO4原位高压拉曼光谱和电导率的研究

 钼酸铅（PbMoO₄）具有高的声光品质因数、低的声损耗、良好的声阻抗匹配等性质，被广泛应用于声光偏转器、调制器、可调滤光器、声表面波器件等各类声光器件，其优异的低温闪烁性能亦引起人们的注意，具有在核设备方面的应用潜力。为探讨其晶体结构和物理性质，在金刚石对顶砧上原位测量了PbMoO₄的拉曼光谱，并测量了其在几个不同压力点下电导率随温度的变化。实验发现，压力在12.5 GPa时，拉曼峰完全消失，说明压力在10.8～12.5 GPa之间PbMoO₄样品出现了非晶态转变。当从26.5 GPa卸压到9.4 GPa时，PbMoO₄的拉曼谱在低波数出现无序化，而在2.4 GPa压力下858 cm^-1峰又重新出现，说明样品结构由无序向晶化回复。压力在10.8 GPa以上时，电导率随着温度的增加而显著增加，且随着压力的增加也明显增加。     

高压下正戊烷的稳定性研究

 利用Raman散射光谱在碳硅石压腔下研究了常温下的正戊烷从0.07~4.77 GPa的稳定性。结果表明：正戊烷的 CH₃、CH₂对称和反对称伸缩振动2 877 cm^-1、2 964 cm^-1和2 856 cm^-1、2 935 cm^-1以及－(CH₂)_n －同步扭曲振动1 303 cm^-1均随压力增大而基本呈线性向高频方向移动,并在2.47 GPa附近发生过压凝固,这是一种平衡稳定态之外的亚稳态现象。另外推测正戊烷在高压下可能发生固－固相变,最后通过平衡的固液共存相确定了正戊烷的平衡凝固压力为(1.90±0.05) GPa。     

硅酸锶掺Er3+的高压合成及发光特性

 首次采用高压高温方法合成了Sr₂SiO₄:Er³⁺Bi³⁺和SrSiO₃:Er³⁺Bi³⁺发光材料，研究了合成压力、合成温度对发光特性的影响。与常压合成产物相比较，发光谱发生了红移；谱线半宽度显著增大；发光强度和量子发光效率下降。X射线衍射分析得出，SrSiO₃:Er³⁺Bi³⁺发生了结构相变，Sr₂SiO₄:Er³⁺Bi³⁺结构未变但晶格参数发生了变化，且主衍射峰强度发生了反转。分析表明，发光特性的变化是压致晶场、库仑及自旋-轨道相互作用的变化引起的。     

甲醇作为压标的拉曼研究

 利用立方氧化锆压腔研究了甲醇在温度301 K、压力169.2~713.8 MPa下C—H伸缩振动ν_{2 835}的拉曼特征,实验结果表明：在试验的压力范围内甲醇稳定,其拉曼位移和压力具有很好的线性关系。加上常压下的数据,拟合后得出压力与甲醇2 835 cm^-1拉曼线频率位移的关系为：p= -3.508 9[(Δν_p)_{2 835}]²+135.17 (Δν_p)_{2 835}+54.397(0.1~713.8 MPa)。因此在实验的压力范围内甲醇作为压标非常合适。     

Raman Investigation of Sodium Titanate Nanotubes under Hydrostatic Pressures up to 26.9GPa

High pressure behavior of sodium titanate nanotubes （Na2Ti2O5） is investigated by Raman spectroscopy in a diamond anvil cell （DAC） at room temperature. The two pressure-induced irreversible phase transitions are observed under the given pressure. One occurs at about 4.2 GPa accompanied with a new Raman peak emerging at 834 cm-1 which results from the lattice distortion of the Ti-O network in titanate nanotubes. It can be can be assigned to Ti-O lattice vibrations within lepidocrocite-type （H0.7Ti1.825V0.175O4＆#12539;H2O）TiO6 octahedral host layers with V being vacancy. The structure of the nanotubes transforms to orthorhombic lepidocrocite structure. Another amorphous phase transition occurs at 16.7 GPa. This phase transition is induced by the collapse of titanate nanotubes. All the Raman bands shift toward higher wavenumbers with a pressure dependence ranging from 1.58-5.6 cm-1/GPa.     

Raman Investigation of BaWO4-II Phase under Hydrostatic Pressures up to 14.8GPa

The BaW04-17 phase is synthesized at 5.0 GPa and 610~C with a cubic-anvil apparatus and identified by XRD. Raman scattering measurement is carried out to investigate the phase behaviour of a pure BaW04-Ⅱ phase （space group P21/n, Z = 8） under hydrostatic pressures up to 14.8 GPa at ambient temperature. In each spectrum recorded for this phase, 27 Raman modes are observed, and all bands shift toward higher wavenumber with a pressure dependence ranging from 3.8 to 0.2 cm- 1/GPa. No pressure-driven phase transition occurs in the entire pressure range in this study. Our results indicate that the previously reported high pressure phase of Ba WO4 at pressure above about 10 GPa and room temperature （Errandonea et al. Phys. Rev. B 73（2006）224103） is not the BaW04-Ⅱ phase.     

DISCOVERY OF MULTIPLE,COLLECTIVE BAND STRUCTURES IN NUCLEI WITH A=60—80

Recent studies of levels in even-even ^68,70,72Ge,^70,72,74Se,^74,76,78,80Kr and ⁶⁵Ga and ⁷⁴Br have led to the discovery of a wide variety of different collective band structures.These include bands built on near spherical ground states and excited more well de-formed shapes that may include triaxial shapes,rotation-aligned bands built on thesame orbital （g_（9/2））² for both protons and neutrons,RAL negative parity bands witheven and odd spins,and ΔI=1 γ-type vibrational bands in even-even nuclei.As recent as 1974,a survey of the energy level in the even-even Ge and Se iso-topes^[1] revealed little was known above a spin of 4⁺ （see for examples Figs.1 and 2 of Ref.1）.With the exception of the unusally low-lying excited 0⁺ states in ^70,72Ge,first discovered in ⁷²Ge in 1948 at Vanderbilt^[2],the theoretical treatment of thesenuclei was limited primarily to some variation of the vibrational model.However,very recently there has been a surge of information on nuclei in this region that hasrevealed fascinating new features and also provided new insight into the excited 0^+’states.Particularly striking are the multiple,independent and highly collective bandstructures which we have discovered in our in-beam γ-ray spectroscopy studies fol-lowing heavy-ion induced reaction.Evidence for and the theoretical understandingof the richness of the collective band structures that are found in our studies of^68,70,72Ge （Refs.3—6）,^70,72,74Se （Refs.7—13） and ^74,76,78,80Kr （Refs.14—18）,as illustratedby the at least seven different bands found in our studies of the levels of ⁶⁸Ge ⁷⁴Se,and ⁷⁶Kr （Figs.1—3）,are described in this paper.These multiple structures includethe following:a) coexistence of ground bands built on near-spherical shapes andexcited bands with larger deformation built on O^+′ band heads;b) bands with 8⁺ band heads interpreted as rotation-aligned,RAL,bands built on both neutron and/orproton （g_（9/2））² quasiparticle configurations coexisting with the ground-state band;c)RAL neutron and proton odd-parity bands formed from coupling of a g_{（9/2 ）}quasipar-ticle and a p_（1/2）,p_（3/2） or f_（5/2）,quasiparticle with the core;d) ΔI=1 even-parity bands,which are best characterized as gamma-vibrational bands;and e) additional bandswhose nature are presently not known.     

Raman and X-Ray Investigation of Pyrope Garnet （Mg0.76Fe0.14Ca0.10）3Al2Si3O12 under High Pressure

The compressional behavlour of natural pyrope garnet is investigated by using angle-dlspersive synchrotron radiation x-ray diffraction and Raman spectroscopy in a diamond anvil cell at room temperature. The pressureinduced phase transition does not occur under given pressure. The equation of state of pyrope garnet is determined under pressure up to 25.3 GPa. The bulk modulus KTO is 199 GPa, with its first pressure derivative K′TO fixed to 4. The Raman spectra of pyrope garnet are studied. A new Raman peak nearly at 743 cm^-1 is observed in a bending vibration of the SiO4 tetrahedra frequency range at pressure of about 28 GPa. We suggest that the new Raman peak results from the lattice distortion of the SiO4 tetrahedra. All the Raman frequencies continuously increase with the increasing pressure. The average pressure derivative of the high frequency modes （650-1000 cm^-1） is larger than that of the low frequency （smaller than 650 cm^-1）. Based on these data, the mode Grǖneisen parameters for pyrope are obtained.     

Measurement of 125Ba High Spin States

The high spin states of ¹²⁵Ba populated via the ¹⁰⁹Ag(¹⁹F,3n) reaction are measured by using a BGO Compton suppressed HPGe detector array.The negative and positive parity bands built respectively on the h_11/2 and g_7/2 neutron hole states are extended to 35/2^－ and 23/2⁺.Backbending occurs in both signature branches of the negative band at the frequencies close to that of the ¹²⁴Ba yrast band.An onset of backbending in the positive band has been seen.