基底温度对NiOx薄膜性质的影响及其电致变色机理研究

采用磁控溅射法在不同基底温度的条件下制备NiOx薄膜。对制备的薄膜采用XRD、SEM、Raman、XPS、可见光分光光度计及循环伏安曲线等测试手段进行对比分析。结果表明,在低温条件下制备的NiOx薄膜比常温沉积的薄膜会提供更多的Ni2+离子参与变色反应,同时薄膜中疏松的孔洞有利于离子进出。SEM图中可以看出液氮流量越大,温度越低则晶粒越小,会造成沉积组织明显疏松,这些孔隙非常有利于H+的拉入抽出。通过Raman测试发现,低温沉积的薄膜可以提供更多的Ni2+空位。XPS测试发现NiOx薄膜在KOH溶液中的变色是由H+引起的,反应机理为:Ni(OH)2 NiOOH+H++e-。循环伏安测试发现173 K条件下制备的NiOx薄膜(η=38.2 cm2/C,λ=550 nm)比室温制备的NiOx薄膜(η=16.3 cm2/C,λ=550 nm)有更高的着色系数,表现出更好的变色效率。

磁控溅射基片低温冷却法制备NiOx纳米微晶薄膜

利用自行设计的基片液氮低温冷却装置,用金属Ni靶在Ar+O2气氛反应条件下,利用磁控溅射制备纳米微晶结构NiOx膜的方法,薄膜的XRD谱和扫描电子显微图像(SEM)表明,该方法实现了在溅射参数完全相同的条件,纳米NiOx薄膜结构连续可控、可调节。

基于WO3/NiOx膜系的固态电致变色器件研究

氧化钨和氧化镍是目前研究最多、应用最广的两种电致变色材料.本文详细地介绍了本实验室射频溅射WO3和NiOx薄膜的制备和性能以及以它们为基的夹层式固态电致变色器件的制作和性能.

Self-assembled interlayer aiming at the stability of NiOx based perovskite solar cells

Inorganic NiO_(x) based inverted structure perovskite solar cells (PSCs) is reported to be more stable than that with the organic hole transport materials.In this work,NiO_(x)/MAPbI_(3) interface chemical reaction induced instability of perovskite is unveiled:Ni^(3+) and I^(-) exhibit redox reactions and deprotonation of MA^(+) happens,which result in interface defects and perovskite lattice deformation.Thus the defective interface accelerates the degradation of perovskite by defect pathways from the bottom interface to the perovskite surface contacting H_(2)O/O_(2).Self-assembled interlayer of NH_(2)^(-)end silane on NiO_(x)separates the reactive NiO_(x)and MAPbI_(3),tunes the interface energy states by–NH_(2) end group.As a result,the PSC based on the silane treated NiO_(x)achieves enhanced PCE of 20.1%with decent stability under environmental and extreme conditions (high temperature,high humidity,light infiltration).Our work highlights the interface chemical problem induced PSC instability and a simple interface modification to achieve the stable PSCs.

Band alignment towards high-efficiency NiOx-based Sn-Pb mixed perovskite solar cells

Narrow-bandgap tin-lead(Sn-Pb)mixed perovskite solar cells(PSCs)play a key role in constructing perovskite tandem solar cells that are potential to overpass Shockley-Queisser limit.A robust,chemically stable and lowtemperature-processed hole transporting layer(HTL)is essential for building high-efficiency Sn-Pb solar cells and perovskite tandem solar cells.Here,we explore a roomtemperature-processed NiOx(L-NiOx)HTL based on nanocrystals(NCs)for Sn-Pb PSCs.In comparison with hightemperature-annealed NiOx(H-NiOx)film,the L-NiOx film shows deeper valence band and lower trap density,which increases the built-in potential and reduces carrier recombination,leading to a power conversion efficiency of 18.77%,the record for NiOx-based narrow-bandgap PSCs.Furthermore,the device maintains about 96%of its original efficiency after 50 days.This work provides a robust and room-temperatureprocessed HTL for highly efficient and stable narrow-bandgap PSCs.

Unique Cd1-xZnxS@WO3-x and Cd1-xZnxS@WO3-x/CoOx/NiOx Z-scheme photocatalysts for efficient visible-light-induced H2 evolution

Artificial Z-scheme photocatalytic systems have received considerable attention in recent years because they can achieve wide light-absorption, high charge-separation efficiency, and strong redox ability simultaneously. Nevertheless, it is still challenging to exploit low-cost and stable Zscheme photocatalysts with highly-efficient H2 evolution from solar water-splitting so far. Herein, we report a novel all-solidstate Z-scheme photocatalyst Cd1-xZnxS@WO3-x consisting of Cd1-xZnxS nanorods coated with oxygen-deficient WO3-x amorphous layers. The Cd1-xZnxS@WO3-x exhibits an outstanding H2 evolution reaction(HER) activity as compared with Pt-loaded Cd1-xZnxS and most WO3- and Cd S-based photocatalysts, due to the generation of stronger reducing electrons through the appropriate Zn-doping in Cd1-xZnxS and the enhanced charge transfer by introducing oxygen vacancies(W^5+/OVs) into the ultrathin WO3-x amorphous coatings. The optimal HER rate of Cd1-xZnxS@WO3- xis determined to be 21.68 mmol h^-1 g^-1, which is further raised up to 28.25 mmol h^-1 g^-1(about 12 times more than that of Pt/Cd1-xZnxS) when Cd1-xZnxS@WO3-x is hybridized by Co Ox and Ni Oxdual cocatalysts(Cd1-xZnxS@WO3-x/CoOx/NiOx)through in-situ photo-deposition. Moreover, the corresponding apparent quantum yield(AQY) at 420 nm is significantly increased from 34.6% for Cd1-xZnxS@WO3-x to 60.8% for Cd1-xZnxS@WO3-x/CoOx/NiOx. In addition, both Cd1-xZnxS@WO3-x and Cd1-xZnxS@WO3-x/CoOx/NiOx demonstrate good stability towards HER. The results displayed in this work will inspire the rational design and synthesis of high-performance nanostructures for photocatalytic applications.

Absence of superconductivity in Nd0.8Sr0.2NiOx thin films without chemical reduction

The recently reported 9-15 K superconductivity in Nd0.8Sr0.2NiO2/SrTi03 heterostructures that were fabricated by a soft-chemical topotactic reduction approach based on precursor Nd0.8Sr0.2NiO3 thin films deposited on SrTiO3 substrates,has excited an immediate surge of research interest.To explore an alternative physical path instead of chemical reduction to realizing superconductivity in this compound,using pulsed laser deposition,we systematically fabricated 63 Nd0.8Sr0.2NiOx(NSNO)thin films at a wide range of oxygen partial pressures on various oxide substrates.Transport measurements did not find any signature of superconductivity in all the 63 thin-film samples.With the oxygen content reducing in the NSNO films by lowering the deposition oxygen pressure,the NSNO films are getting more resistive and finally become insulating.Furthermore,we tried to cap a 20-nm-thick amorphous LaAlO3 layer on a Nd0.8Sr0.2NiO3 thin film deposited at a high oxygen pressure of 20 Pa to create oxygen vacancies on its surface and did not succeed in obtaining higher conductivity either.Our experimental results together with the recent report on the absence of superconductivity in synthesized bulk Nd0.8Sr0.2NiO2 crystals suggest that the chemical reduction approach could be unique for yielding superconductivity in NSNO/SrTiO3 heterostructures.However,SrTiO3 substrates could be reduced to generate oxygen vacancies during the chemical reduction process as well,which may thus partially contribute to conductivity.

一种新型电化学分析仪BA200用于气道炎症临床检测的可行性分析

目的验证一种新型便携式电化学分析仪BA200(国产)临床应用于气道炎症标志物——呼出气一氧化氮(fractional exhaled nitric oxide,FeNO)检测的可行性。方法分别使用BA200和NIOX VERO两种仪器对137例气道疾病患者进行FeNO测定,用Bland-Altman方法对检测进行一致性分析;测定另外50例气道疾病患者的FeNO,结果采用组内相关系数法(intraclass correlation coefficient,ICC)进行重复性分析;对137例患者中80例哮喘患者的FeNO结果进行ROC曲线分析,比较两种分析仪在不同临界值的灵敏度和特异度。结果一致性研究中,低、中、高3组[<25×10^(-9)、(25~50)×10^(-9)、>50×10^(-9))]和总体样本的Bland-Altman分析显示两种方法测量差值的95%一致性界限(limit of agreement,LoA)分别为(-3.2392~6.7244)×10^(-9)、(-6.8290~7.9234)×10^(-9)、(-14.3101~17.4859)×10^(-9)和(-7.9220~10.7044)×10^(-9)。绝大部分差值位于两者差值均值的95%LoA内。重复性研究中,BA200和NIOX VERO的ICC值分别为0.9953和0.9968,均大于0.75(P<0.001)。ROC曲线分析发现,把49.9×10^(-9)作为cut-off值时,两者的特异度相等,BA200的敏感度高于NIOX VERO。结论与经典电化学分析仪NIOX VERO相比,BA200测量FeNO的结果具有很好的一致性和重复性,可以成为NIOX VERO的临床替代产品,具有临床应用价值。

氧化镍基柔性钙钛矿太阳电池的研究进展

基于柔性衬底材料制备的柔性钙钛矿太阳电池(F-PSC)具有高效率、轻量化等优点,为航空航天、光伏-建筑一体化等领域的发展提供了新的可能性。近年来,以p型氧化镍(NiO_(x))作为空穴传输层(HTL)的单结倒置F-PSC的最佳光电转换效率(PCE)为21.3%,串联的PCE甚至达到了24.7%,显示了其良好的商业化前景。这主要是由于NiO_(x)具有较好的导电性,可忽略的J-V滞后效应和良好的稳定性。介绍了近年来有关基于柔性衬底的NiO_(x)的制备方法,掺杂对NiO_(x)空穴传输层结构、电学和光学性能的影响,以及NiO_(x)与钙钛矿之间的界面钝化方面的研究进展,并对基于NiO_(x)的F-PSC进行了总结和展望。

通过pH值精细调控氧化镍纳米颗粒粒度提升反式钙钛矿太阳能电池性能

氧化镍作为一种低成本、高稳定性的空穴传输材料,在近些年被广泛地应用在反式钙钛矿太阳能电池中.制备氧化镍空穴传输层最常用的方法是旋涂氧化镍纳米颗粒分散液,因此对氧化镍颗粒粒度以及溶液加工性能提出了很高的要求.本文通过精确控制合成过程中体系pH值,实现了对氧化镍纳米颗粒粒度的调控,进而制备了高质量的氧化镍空穴传输层.实验表明合成体系pH值为9.5—9.8时,可以制得平均粒径为5—10 nm的氧化镍纳米颗粒,并且纳米颗粒具有良好的分散稳定性.此外,通过对氧化镍纳米颗粒进行结构成分分析,发现由pH值调控的粒径变化并不会引起颗粒物质结构和成分的改变.通过表面形貌分析,由pH值调控获得的颗粒可制成致密且具有较小的粗糙度的薄膜,该薄膜展现出良好的空穴抽取能力.基于该薄膜的钙钛矿太阳能电池(MAPbI_(3))获得了17.39%的光电转化效率,并且几乎没有迟滞现象.本文的实验结果表明,通过pH值精细调控氧化镍纳米颗粒粒度可以有效提升钙钛矿太阳能电池的性能.本文的研究有望促进基于高性能氧化镍空穴传输层的钙钛矿太阳能电池研究.

LiClO_4有机高分子电解质的电致变色效应

研究了聚甲基丙烯酸甲酯为基的PC+LiClO_4有机高分子电解质薄膜的制备、特性及其在电致变色器件中的应用．采用溶胶—凝胶法制备有机高分子电解质,当LiClO_4的浓度为1．5 mol/L时,电解质的电导率达到最大值2．0 mS/cm．将此样品作为离子传输层与NiO_x电致变色薄膜构成全固态电致变色器件,在紫外光辐照区域,光密度差大于1．66,在350～850 nm光区范围内,光密度差为0．83～1．66,在可见光区和近红外区都具有优良的变色性能．

中频磁控溅射NiO_x电致变色薄膜(英文)

采用中频孪生非平衡磁控溅射技术,制备了纳米晶结构NiOx电致变色薄膜。利用原子力显微镜、掠射X射线衍射、电化学设备、紫外分光光度计等测试手段分析薄膜结构及电致变色特性。结果表明:室温沉积获得表面质地均匀的NiOx薄膜;在±3V致色电压下,薄膜电致变色性能优异,对可见光透过率调制范围达30%以上,但薄膜寿命低。获得的薄膜为结构疏松的纳米晶结构,易于离子的注入和抽取,变色性能优异,但易发生Li+不可逆注入,薄膜寿命低。

直流反应溅射制备NiO_x薄膜及其电致变色机理研究

采用直流反应溅射在ITO导电玻璃上沉积了NiOx薄膜,研究了O2流量对其光学和电致变色性能的影响,利用XRD、SEM和XPS对薄膜的微结构和成分进行了表征。通过循环伏安特性曲线和可见光透射谱对样品的电化学和电致变色性能进行了研究,并且讨论了NiOx薄膜成分与电致变色性能之间的关系。研究发现反应溅射制备的NiOx薄膜是Ni2+和Ni3+混合价态,颜色为淡棕色,随着薄膜中Ni3+成分增加,薄膜颜色变深,调色范围有减小的趋势。NiOx薄膜表现出阳极电致变色特征,作者认为其电致变色的行为是由于Li+和OH-在薄膜中的注入和拉出引起的Ni2+和Ni3+发生转化所致。

基于磁控溅射制备纳米微晶NiO_x薄膜的方法

使用一种配套于磁控溅射设备的基片液氮冷却装置制备了小颗粒度纳米微晶NiO_x电致变色薄膜.当溅射参数完全相同时,借助于对基片的冷却可有效控制并降低NiO_x薄膜的晶粒尺度.冷却基片所制备的NiO_x薄膜的电致变色性能明显优于室温时制备的薄膜,且该薄膜的O/Ni比率也明显高于室温时制备的NiO_x薄膜的O/Ni比率.

金属氧化物基电致变色器件的光透特性及其变色机理

在ITO导电玻璃基底上沉积得到WO3薄膜和NiOx薄膜,采用PMMA-LiClO4-PC胶质电解质作为离子电导层,制备得到了三明治式的电致变色（EC）器件。在300-1 000 nm波段的辐照光驱分别测试了器件在互补着色和同时着色时的光透性能。通过分析器件在互补着色和同时着色时的电色反应,给出了不同阶段的电致变色过程的电化学反应机理。特别考虑了实际应用中由于潮解和极化等因素引起的不利化学反应对器件性能的影响,对电致变色器件的实用化具有一定的指导意义。

氧分压对NiO_x薄膜微结构和电阻开关特性的影响

利用磁控溅射方法在镀Pt的Si(100)衬底上沉积制备NiO_x薄膜,研究了氧分压对薄膜微结构和电阻开关特性的影响.微结构观测分析结果表明:在20%氧分压下,可获得沿[200]晶向择优生长的NiO_x多晶薄膜,薄膜表面平整致密,晶粒平均直径约为13.8nm,垂直衬底生长形成柱状晶粒结构.磁性测试结果显示薄膜具有典型的铁磁性磁化曲线,但薄膜饱和磁矩随着氧分压增加急剧降低.电学测试结果表明20%氧分压氛围下沉积制备薄膜样品的电流-电压曲线呈现出典型的双极性电阻开关特性:在-0.6V读取电压下,可获得大于10的高/低电阻态阻值比.指数定律拟合电流-电压实验曲线表明:薄膜低电阻态漏电流为欧姆接触电导;而薄膜处于高电阻态时,低电压下的漏电流仍以欧姆接触电导为主,高电压下则以缺陷主导的空间电荷限制电流为主.

Fe:NiO_x阳极催化膜电极过程动力学研究

利用射频反应磁控溅射制备Fe:NiOx阳极催化膜,对其在电解液中的电极过程进行分析,明确整个电极过程的控制步骤———电化学步骤。根据实验结果及塔菲尔方程求出电化学步骤的重要动力学参数(塔菲尔斜率b,交换电流密度i0),并通过XPS和SEM分析影响过电势的因素。

纳米晶结构NiO_x薄膜Li^+致色性能研究

采用中频孪生非平衡磁控溅射方法制备了纳米晶结构NiOx电致变色薄膜。原子力显微镜(AFM)、掠入射X射线衍射(GID)、X射线反射(XRR)分析薄膜结构、形貌及薄膜厚度;利用电化学设备、紫外分光光度计等手段测试薄膜循环伏安及光谱特性。结果表明:沉积获得NiOx薄膜质地均匀,晶粒尺寸约为4.5 nm,薄膜表面粗糙度Ra=1.659 nm;以Li+离子为致色粒子,厚度60nm的NiOx薄膜在±3 V的高驱动电压下薄膜对可见光透过率调制范围达30%以上,电致变色性能较好。

磁控溅射参数对NiO_x薄膜光学常数的影响(英文)

采用反应性磁控溅射法制备了NiOx薄膜,并结合椭圆偏振仪、XRD和XPS研究了溅射参量对其光学常量的影响.NiOx薄膜的光学常量随着O2/Ar流量比的增大而减小;热退火后,折射率增大而消光系数下降了50%;溅射功率越大折射率也越大,而工作气压越大折射率反而越小.这些变化分别与薄膜中存在间隙O和Ni空位、NiOx分解以及NiOx薄膜的致密度有关.

含氧量对NiO_x薄膜光电特性的影响

采用直流溅射方法制备了厚度小于0.1μm的NiOx薄膜，研究薄膜的加热氧化及其光电特性。