超细氧化硅纳米线阵列的制备和发光特性

以液态金属Ca作为催化剂合成了大量的非晶SiO2纳米线阵列。这些纳米线具有高度取向性,直径分布均匀,平均约8nm,长度大于300μm。研究发现,载气的湿度对非晶SiO2纳米线阵列的生长有重大影响,提出了一种可能的生长模型,以解释这一与传统的VLS机制不同的生长过程。对样品的光致荧光(PL)谱的测量表明,非晶SiO2纳米线阵列在蓝光波段附近存在两个很强且稳定的发射峰,它们直接与样品中的缺陷和空位有关。首次发现了一个稳定的PL峰,存在于红外波段,作为光源,非晶SiO2纳米线阵列可能会在纳米光电子器件中得到应用。由于SiO2是传统的光纤材料,单根SiO2纳米线也有希望应用于近场光学扫描显微镜(SNOM)之中。     

MgAPO-11分子筛的合成、表征及其催化正己烷裂解反应的动力学研究

以二异丙基胺为有机模板剂,采用静态水热法合成了具有不同镁含量的镁铝磷酸盐分子筛MgAPO-11,并利用X射线衍射、扫描电子显微镜、傅里叶变换红外光谱、魔角旋转核磁共振和电感耦合等离子体原子发射光谱等方法对其进行表征.当0相似文献   

腐植酸钠/聚N-异丙基丙烯酰胺/粘土杂化水凝胶的合成及脱色性能

腐植酸钠;聚N-异丙基丙烯酰胺;粘土;水凝胶;亚甲基蓝     

用集合的观点解释和研究概率

课程标准中指出,“集合语言是现代数学的基本语言,是一种特殊的符号语言,使用集合语言可以简洁准确的表达数学中的一些基本内容”．因此,在高中我们是将集合作为一种语言来学习的．     

液相色谱-串联质谱法检测淡水养殖环境中地西泮及其代谢物

建立了养殖水、植物、沉积物和鲫鱼中地西泮及其代谢物(去甲西泮、奥沙西泮和替马西泮)的液相色谱-串联质谱检测方法。养殖水经0.45μm玻璃纤维膜过滤,用氨水调至pH 8.0后通过反相固相萃取柱(HLB)净化;植物和沉积物经盐析提取后,通过QuEChERS方法净化上样;鲫鱼样品经盐析提取后,通过固相萃取柱(Prime HLB)净化上样。采用Luna C₁₈柱(100 mm×2.1 mm,1.6μm)进行分离,多反应监测(MRM)模式进行测定,外标法定量。结果表明：地西泮及其3种代谢物在0.1～10μg/L质量浓度范围内呈良好的线性关系(r²>0.999)。4种目标物在养殖水体中的检出限为1.0～1.2 ng/L,定量下限为5.0～6.0 ng/L;在植物、沉积物和鲫鱼中的检出限为0.03～0.10μg/kg,定量下限为0.10～0.25μg/kg。在低、中、高3个加标水平下,地西泮及其代谢物的回收率为83.4%～106%,相对标准偏差(RSD,n=6)为1.2%～9.4%。该方法成功应用于养殖水、沉积物、植物和鲫鱼样品中地西泮及其代谢物的检...     

锰掺杂的钙钛矿型钛铌酸盐基复合阴极高温电解水蒸气

通过在氧化还原稳定的钙钛矿材料钛铌酸盐的B位晶格中掺杂具有氧化还原活性的锰元素提高固体氧化物电解池复合电极电催化性能．研究发现,锰元素成功取代钛铌酸盐B位的Ti／Nb．掺杂后的样品的离子电导率在800℃下的氧化气氛和还原气氛下的离子电导率分别提高了约1和0．5个数量级．基于掺杂后的钛铌酸盐基复合阴极,氧离子传导型固体氧化物电解池电解水蒸汽的电流效率在有和无还原气体保护下分别提高了25％和30％．     

Simulating resonance-mediated two-photon absorption enhancement in rare-earth ions by a rectangle phase modulation

Improving the up-conversion luminescence efficiency of rare-earth ions via the multi-photon absorption process is crucial in several related application areas. In this work, we theoretically propose a feasible scheme to enhance the resonance-mediated two-photon absorption in Er~(3+) ions by shaping the femtosecond laser field with a rectangle phase modulation. Our theoretical results show that the resonance-mediated two-photon absorption can be decomposed into the on-resonant and near-resonant parts, and the on-resonant part mainly comes from the contribution of laser central frequency components, while the near-resonant part mainly results from the excitation of low and high laser frequency components.So, the rectangle phase modulation can induce a constructive interference between the two parts by properly designing the modulation depth and width, and finally realizes the resonance-mediated two-photon absorption enhancement. Moreover, our results also show that the enhancement efficiency of resonance-mediated two-photon absorption depends on the laser pulse width(or laser spectral bandwidth), final state transition frequency, and intermediate and final state absorption bandwidths. The enhancement efficiency modulation can be attributed to the relative weight manipulation of on-resonant and near-resonant two-photon absorption in the whole excitation process. This study presents a clear physical insight for the quantum control of resonance-mediated two-photon absorption in the rare-earth ions, and there will be an important significance for improving the up-conversion luminescence efficiency of rare-earthions.     

Experimental study of the dependences of retrieval efficiencies on time delay between magneto-optical-trap being turned off and optical storage

We report an experimental study of electromagnetically induced transparency(EIT)-based light storage in a cloud of cold atoms loaded into a magneto-optical-trap(MOT). After the MOT is turned off, the retrieval efficiencies of rightand left-circularly polarized signal light fields each as a function of storage time are measured for different time delays between MOT off and the storage event, respectively. The results show that in the delay ranging from 0.015 ms to 3.5 ms,the retrieval efficiency for a zero-storage time(0.2 μs) and the storage lifetime can exceed 15% and 1.4 ms, respectively.The measured results will provide important help for optimizing the storage of the polarized entanglement photons in cold atomic ensembles.     

The Interaction of Peregrine Solitons

We theoretically investigate the interaction of two in-phase and out-of-phase Peregrine sofitons in a Kerr nonlinear medium, addressing both the cases of first- and second-order solitons. Upon adjusting the interval between the sofitons, their interactions exhibit different properties. If the interval is sufficiently large, two Peregrine sofitons will propagate individually and will not interact each other. However, if the interval is not very large, the Peregrine solitons will strongly interact and display varying behavior.     

Passively stabilized single-photon interferometer

A single-photon interferometer is a fundamental element in quantum information science. In most previously reported works, single-photon interferometers use an active feedback locking system to stabilize the relative phase between two arms of the interferometer. Here, we use a pair of beam displacers to construct a passively stable single-photon interferometer. The relative phase stabilization between the two arms is achieved by stabilizing the temperature of the beam displacers. A purely polarized single-photon-level pulse is directed into the interferometer input port. By analyzing and measuring the polarization states of the single-photon pulse at the output port, the achieved polarization fidelity of the interferometer is about 99.1 ±0.1%. Our passively stabilized single-photon interferometer provides a key element for generating high-fidelity entanglement between a photon and atomic memory.