光催化合成金属Ag纳米颗粒的生长机制——晶核密度控制的生长模式转换

利用AgNO3水溶液,通过严格控制TiO2薄膜的化学活性,系统研究了在TiO2表面光催化合成金属Ag纳米颗粒的生长行为。研究发现,光催化合成金属Ag纳米颗粒存在着两个完全不同的生长机制,分别对应着金属Ag纳米颗粒的各向同性和各向异性生长。当溶液浓度较低时,Ostwald熟化(OR)机制主导着金属Ag纳米颗粒的长大过程;当溶液浓度较高时,取向附生(OA)机制决定着金属Ag纳米颗粒长大成纳米片。原位消光光谱分析表明,OR机制和OA机制生长的前期具有相近消光特征,决定金属Ag纳米颗粒生长模式的关键是AgNO3溶液的浓度,更准确地说是金属Ag初级晶核的局域密度。在此基础上提出了有关光催化合成金属Ag纳米颗粒的生长模型。     

基于正电荷和光热协同效应的新型半导体聚合物纳米抗菌材料

由于抗生素的不当使用和细菌多药耐药的出现, 迫切需要开发新的抗菌剂. 本文制备了具有光热转换性能的正电荷半导体高分子材料及具有协同抗菌活性的半导体聚合物纳米粒子(SP-PPh₃ NPs). SP-PPh₃ NPs的光热转化效率为43.8%. 带正电荷的SP-PPh₃ NPs可以附着在细菌上, 有助于将热量有效传递给细菌. 在热和正电荷的协同作用下, SP-PPh₃ NPs对革兰氏阴性大肠杆菌(E. coli)和革兰氏阳性金黄色葡萄球菌(S. aureus)均具有抗菌活性, 其对二者的体外抑菌率分别为99.9%和98.6%. 此外, SP-PPh₃ NPs具有良好的生物相容性, 对小鼠的主要器官几乎无副作用. 对细菌感染的小鼠皮肤伤口用SP-PPh₃ NPs治疗12 d后, 伤口可以很好地愈合.     

基于上转换纳米粒子的低损伤神经界面技术

Optogenetics is a neuromodulation technology that combines light control technology with genetic technology, thus allowing the selective activation and inhibition of the electrical activity in specific types of neurons with millisecond time resolution. Over the past several years, optogenetics has become a powerful tool for understanding the organization and functions of neural circuits, and it holds great promise to treat neurological disorders. To date, the excitation wavelengths of commonly employed opsins in optogenetics are located in the visible spectrum. This poses a serious limitation for neural activity regulation because the intense absorption and scattering of visible light by tissues lead to the loss of excitation light energy and also cause tissue heating. To regulate the activity of neurons in deep brain regions, it is necessary to implant optical fibers or optoelectronic devices into target brain areas, which however can induce severe tissue damage. Non- or minimally-invasive remote control technologies that can manipulate neural activity have been highly desirable in neuroscience research. Upconversion nanoparticles (UCNPs) can emit light with a short wavelength and high frequency upon excitation by light with a long wavelength and low frequency. Therefore, UCNPs can convert low-frequency near-infrared (NIR) light into high-frequency visible light for the activation of light-sensitive proteins, thus indirectly realizing the NIR optogenetic system. Because NIR light has a large tissue penetration depth, UCNP-mediated optogenetics has attracted significant interest for deep-tissue neuromodulation. However, in UCNP-mediated in vivo optogenetic experiments, as the up-conversion efficiency of UCNPs is low, it is generally necessary to apply high-power NIR light to obtain up-converted fluorescence with energy high enough to activate a photosensitive protein. High-power NIR light can cause thermal damage to tissues, which seriously restricts the applications of UCNPs in optogenetic technology. Therefore, the exploration of strategies to increase the up-conversion efficiency, fluorescence intensity, and biocompatibility of UCNPs is of great significance to their wide applications in optogenetic systems. This review summarizes recent developments and challenges in UCNP-mediated optogenetics for deep-brain neuromodulation. We firstly discuss the correspondence between the parameters of UCNPs and employed opsins in optogenetic experiments, which mainly include excitation wavelengths, emission wavelengths, and luminescent lifetimes. Thereafter, we introduce the methods to enhance the conversion efficiency of UCNPs, including optimizing the structure of UCNPs and modifying the organic dyes in UCNPs. In addition, we also discuss the future opportunities in combining UCNP-mediated optogenetics with flexible microelectrode technology for the long-term detection and regulation of neural activity in the case of minimal injury.     

多尺度Ag/CuO复合光热材料的制备及在海水淡化中的应用

采用原位化学反应和热处理相结合的策略,在泡沫铜表面形成丝线状与花瓣状的立体无机物阵列,然后在其表面蒸镀Ag纳米颗粒(NPs),成功制备了基于泡沫铜的Ag/CuO复合光热材料。该复合材料因表面三维立体阵列结构以及Ag NPs而具备较高的太阳光吸收率。故而,Ag/CuO复合光热材料结合三聚氰胺泡沫组成的蒸发器件实现了高效的海水淡化。本研究除了探索光陷阱深度和金属掺杂对吸收体光热转换效率增强之外,还搭建了太阳能驱动界面蒸汽生成测试系统,测试了样品的光热蒸发性能。在1倍太阳(1 kW·m~(-2))辐照下,该器件整体蒸发速率高达1.097 6 kg·m~(-2)·h~(-1),即其蒸发效率可达78.38%。     

惯性/天文组合导航中的时空坐标转换及其误差分析

针对惯性/天文组合导航中将天文传感器测量信息从天球坐标系到地球坐标系转换的问题,研究了其转换过程中涉及到的时间系统和坐标转换关系,前者包括世界时、地球时、太阳系质心力学时、原子时和协调世界时等时间概念,后者包括岁差、章动、视恒星时和极移等旋转变换。对坐标转换过程中小于0.1″的因素进行了忽略和近似简化,误差分析表明,除地球自转角的计算需要比较精确的UT1时间外,其他天文参数计算中的时间输入均可直接使用UTC时间代替。仿真结果显示,所提简化算法的转换精度达到了0.2″,满足角秒级的天文传感器测姿精度需求。     

五阶势MKdV方程的一个不变性

§1Introduction Asweknow,Backlundtransformation[1-3]isaverypowerfulwayforfindingnonline evolutionequations.Inrecentdecades,Painlevéanalysis[4]hasbecomeaverypopu methodtoobtainBacklundtransformation.Inreference[5],fordevelopingthetheory Painlevéanalysis,AndrewPickeringintroduceanewexpansionvariableZwhichsatisf thefollowingRicattiSystem:Zx=1-AZ-BZ2,Zt=-C+(AC+Cx)Z-(D-BC)Z2.(1.Astheapplicationofthenewexpansionvaraible,thepotentialfifth-orderMKd equation(PMKdV5)-vxt+(vxxxxx-10k2v2…     

逆极限空间上渐近伪轨跟踪性质

The connection between APOTP （asymptotic pseudo orbit tracing property） for a continuous map on a compact metric space and that for the shift map on the inverse limit space is investigated. As an application, it is showed that the shift map on Henderson pseudoarc has APOTP.     

上转换发光免疫试纸条扫描检测系统研究

研制了一种以上转换发光材料作为标记物的扫描检测系统,有别于传统的测量方法,可做出定量和多重分析.扫描检测系统以扫描方式逐点测量经生物反应而结合上去的UCP颗粒的含量,记录整个免疫试纸条的信息,计算出被测样品中特定生物分子的浓度.实验结果表明,该系统对兔抗鼠疫免疫球蛋白（IgG）标准样品的检测灵敏度达到百ng/mL量级,且具有变异系数小于6%的重复性,符合生物免疫测定的要求.     

火焰位置可转换的气体燃烧演示器的制作和使用——介绍纯净氢气在氧气或氯气燃烧反应中的有趣实验

通常人们一提起气体的燃烧就自然会想到纯净的氢气、一氧化碳、甲烷、乙烯、乙炔等在空气或氧气中的燃烧。笔者为此设计了一套简易装置,则可用于演示“助燃性”气体在“可燃性”气体中燃烧的实验,它拓展了学生视野,培养了学习兴趣,对帮助学生正确认识“燃烧”起到了较好的作用。     

组分阶梯InGaN势垒对绿光激光二极管光电性能的影响

为探究不同铟(In)组分In_xGa_1-xN势垒对绿光激光二极管光电性能的影响,本文采用SiLENSe(simulator of light emitters based on nitride semiconductors)仿真软件对一系列具有不同In组分In_xGa_1-xN势垒的激光二极管进行研究,结果发现In_xGa_1-xN势垒中In组分最佳值为3%,此时结构的斜率效率最高,内部光学损耗最低,光学限制因子最大,性能最优。在具有In_0.03Ga_0.97N势垒的多量子阱结构基础上,设计了一种组分阶梯(composition step-graded, CSG)InGaN势垒多量子阱结构,提高了激光二极管的斜率效率和电光转换效率,增加了光场限制能力。仿真结果表明,当注入电流为120 mA时,具有CSG InGaN势垒的多量子阱结构,电光转换效率从17.7%提高至19.9%,斜率效率从1.09 mW/mA增加到1.14 mW...