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用沉淀法制备了尺寸约为8 nm的YVO4∶Eu3+纳米粒子,然后用反相微乳液法在YVO4∶Eu3+纳米粒子的表面包覆了一层Si O2壳。利用XRD、TEM、UV-Vis吸收光谱和光致发光光谱对合成的样品进行了表征。得到的复合物具有较好的核壳结构,通过改变硅酸四乙酯的用量可以改变Si O2壳的厚度。研究了Si O2壳对YVO4∶Eu3+发光性质的影响,结果表明:包覆和未包覆的样品在紫外光激发下都有Eu3+的特征发射;随着Si O2壳厚度的增加,发光强度和量子效率越来越低,Eu3+格位对称性越来越高。 相似文献
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本文在5.1—5.6 GPa,1230—1600℃的压力、温度条件下,以FeNiMnCo作为触媒,进行单质硼添加宝石级金刚石单晶的生长研究.借助于有限元法,对触媒内的温度场进行模拟.研究得到了FeNiMnCo-C-B体系下,金刚石单晶生长的P-T相图.该体系下合成金刚石单晶的最低压力、温度条件分别为5.1 GPa,1230℃左右.研究发现,在单晶同一{111}扇区内部,硼元素呈内多外少的分布规律.有限元模拟结果给出,该分布规律是由在晶体生长过程中,{111}扇区的增长速度逐渐减小所致.{111}晶向的晶体生长实验结果表明,硼元素优先从{111}次扇区进入晶体.研究发现,这是该扇区增长速度相对较快,硼元素扩散逃离可用时间短导致的.另外,同磨料级掺硼金刚石单晶生长相比,对于温度梯度法生长掺硼宝石级金刚石单晶,由于晶体的增厚速度较慢,即使硼添加量相对较高,也可以实现表面无凹坑缺陷的优质金刚石单晶的生长. 相似文献
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硼在高压下具有复杂的结构和多样的物理性质,对其结构和性质的深入研究具有很重要的意义,一直引起理论和实验研究领域的关注。高压下进行电学性质测量是获得物质物理性质的有效手段,利用集成在金刚石对顶砧上的微电路,在高压下和两个不同温度范围内对β相硼进行了电导率测量,分析了导电机制随压力的变化规律。在0~28.1 GPa范围内,β相硼的电导率随着压力的增大是逐渐增大的,卸压后样品的电导率不能回到最初的状态,是一个不可逆的变化过程;由室温到423 K的范围内,β硼的电导率随着温度的不断增加有明显的上升趋势,并且随着压力的升高,电导率变化逐渐加快。此外,对样品在14.5 GPa和18.6 GPa压力下,用溅射到金刚石对顶砧上的氧化铝薄膜做绝热层,对样品进行了激光加热实验,最高温度达到2 224 K,电导率随着温度的上升而增大,结果显示,β相硼的电学特征仍然属于半导体的特征范围内。 相似文献
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Using a microcircuit fabricated on a diamond anvil cell, we have measured
in-situ conductivity of HgSe under high pressures, and investigated the
temperature dependence of conductivity under several different pressures. The result
shows that HgSe has a pressure-induced transition sequence from a semimetal
to a semiconductor to a metal, similar to that in HgTe. Several
discontinuous changes in conductivity are observed at around 1.5, 17, 29
and 49GPa, corresponding to the phase transitions from zinc-blende to
cinnabar to rocksalt to orthorhombic to an unknown structure, respectively.
In comparison with HgTe, it is speculated that the unknown structure may be
a distorted CsCl structure. For the cinnabar-HgSe, the energy gap as a
function of pressure is obtained according to the temperature dependence of
conductivity. The plot of the temperature dependence of conductivity
indicates that the unknown structure of HgSe has an electrical property of a
conductor. 相似文献
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Electrical properties of stoichiometric iron sulfide (FeS) are investigated under high pressure with a designed diamond anvil cell. The process of phase transition is reflected by changing the electrical conductivity under high pressure, and the conductivity of FeS with the NiAs structure is found to be much smaller than other phases. Two new phase transitions without structural change are observed at 34.7 GPa and 61.3 GPa. The temperature dependence of the conductivity is found to be similar to that of a semiconductor when the pressure is higher than 35 GPa 相似文献
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利用温度梯度法, 在5.3-5.7 GPa压力、1200-1600 ℃的温度条件下, 将B2O3粉添加到FeNiMnCo+C合成体系内, 进行B2O3添加宝石级金刚石单晶的合成. 研究得到了FeNiMnCo触媒生长B2O3添加宝石级金刚石单晶的相图分布规律. 结果表明B2O3添加会使晶体生长的“V”形区上移和低温六面体单晶生长区间变宽. 通过晶体生长实验, 研究合成了不同形貌的B2O3添加宝石级金刚石单晶. 研究同时证实, B2O3的过量添加会对宝石级金刚石单晶生长带来不利影响. 当B2O3的添加量高于约3 wt‰、生长时间超过20 h时, 很难实现优质B2O3添加宝石级金刚石单晶的生长. 但B2O3的适量添加(不超过1 wt‰), 有助于提高低温板状六面体宝石级金刚石单晶的成品率. 通过对晶体生长速度的研究发现, B2O3的添加使得优质晶体的生长速度明显降低, 随着晶体生长时间的延长, B2O3添加剂对晶体生长的抑制作用会越发明显. 扫描电镜测试结果表明, 合成体系内B2O3添加剂的引入, 导致晶体表面的平整度明显下降. 相似文献
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We perform the in-situ conductivity measurement on BaF2 at high pressure using a microcircuit fabricated on a diamond anvil cell. The results show that BaF2 initially exhibits the electrical property of an insulator at pressure below 25 GPa, it transforms to a wide energy gap semiconductor at pressure from 25 to 30 GPa, and the conductivity increases gradually with increasing pressure from 30 GPa. However, the metallization predicted by theoretical calculation at 30-33 GPa cannot be observed. In addition, we measure the temperature dependence of the conductivity at several pressures and obtain the relationship between the energy gap and pressure. Based on the experimental data, it is predicted that BaF2 would transform to a metal at about 87 GPa and ambient temperature. The conductivity of BaF2 reaches the order of 10^-3Ω^-1 cm^-1 at 37 GPa and 2400 K, the superionic conduction is not observed during the experiments, indicating the application of pressure elevates greatly the transition temperature of the superionic conduction. 相似文献