Visible light-responsive carbon-decorated p-type semiconductor CaFe_2O_4 nanorod photocatalyst for efficient remediation of organic pollutants

We report the fabrication and photocatalytic property of a composite of C/CaFe2O4nanorods(NRs)in an effort to reveal the influence of carbon modification.It is demonstrated that the photocatalytic degradation activity is dependent on the mass ratio of C to CaFe2O4.The optimal carbon content is determined to be58wt%to yield a methylene blue(MB)degradation rate of0.0058min.1,which is4.8times higher than that of the pristine CaFe2O4NRs.The decoration of carbon on the surface of CaFe2O4NRs improves its adsorption capacity of the MB dye,which is specifically adsorbed on the surface as a monolayer according to the adsorption isotherm analysis.The trapping experiments of the reactive species indicate that superoxide radicals(.O2)are the main active species responsible for the removal of MB under visible‐light irradiation.Overall,the unique feature of carbon coating enables the efficient separation and transfer of photogenerated electrons and holes,strengthens the adsorption capacity of MB,and improves the light harvesting capability,hence enhancing the overall photocatalytic degradation of MB.

A Novel Sr_2CuInO_3S p-type semiconductor photocatalyst for hydrogen production under visible light irradiation

A novel Sr2CulnO3S oxysulfide p-type semiconductor photocatalyst has been prepared by solid state reaction method and it exhibits intriguing visible light absorption properties with a bandgap of 2.3 eV. The p-type semiconductor character of the synthesized Sr2CuInO3 S was confirmed by Hall efficient measurement and Mott-Schottky plot analysis. First-principles density functional theory calculations （DFT） and electrochem ical measurements were performed to elucidate the electronic structure and the energy band locations. It was found that the as-synthesized Sr2CuInO3S photocatalyst has appreciate conduction and valence band positions for hydrogen and oxygen evolution, respectively. Photocat alytic hydrogen production experiments under a visible light irradiation （A〉420 nm） were carried out by loading different metal and metal-like cocatalysts on Sr2CuInO3S and Rh was found to be the best one among the tested ones.

p-Type CaFe_2O_4 semiconductor nanorods controllably synthesized by molten salt method

Pure phase, regular shape and well crystallized nanorods of p-type semiconductor CaFeOhave been fabricated for the first time by a facile molten salt assisted method, as confirmed by XRD, TEM, SEM and HRTEM. UV-vis diffuse reflectance spectra and Mott–Schottky plots show that the band structure of the CaFeOnanorods is narrower than that of the CaFeOnanoparticles synthesized by conventional method. The enhancement of the visible-light absorption is due to narrowness of the band gap in CaFeOnanorods. The appropriate ratio between the molten salt and the CaFeOprecursors plays an important role in inhibiting the growth of the crystals along the(201) plane to give the desired nanorod morphology. This work not only demonstrates that highly pure p-type CaFeOsemiconductor with tunable band structure and morphology could be obtained using the molten salt strategy, but also affirms that the bandgap of a semiconductor may be tunable by monitoring the growth of a particular crystal plane.Furthermore, the facile eutectic molten salt method developed in this work may be further extended to fabricate some other semiconductor nanomaterials with a diversity of morphologies.

Anti-Fowler Temperature Regime in Photoemission from <i>n</i>-Type Semiconductors with Surface Accumulation Layer

According to the Fowler theory and numerous experiments the quantum efficiency for photoemission from conductors increases with temperature. Here we show that an opposite temperature dependence is also possible, when the photoemission is from quasi-metallic surface accumulation layers of n-type semiconductors. This is due to the temperature dependence of the Fermi level energy in semiconductors. The Fermi level energy increases with decreasing temperature;this leads to a decrease of the semiconductor work function and consequently an increase of the quantum efficiency photoemission at constant value of absorbed light quanta of energy. We have calculated this effect for electron accumulation layer in n-GaN, induced by adsorption of positively charged cesium or barium ions. It is found that at low temperatures near liquid nitrogen, the quantum efficiency for photoemission increases to near 55%, which is comparable to the largest values, reported for any known photo-ca-thodes. This phenomenon may prove useful for efficient photo-cathodes operating at low temperatures.

Effects of gate-buffer combined with a p-type spacer structure on silicon carbide metal semiconductor field-effect transistors

An improved structure of silicon carbide metal-semiconductor field-effect transistors （MESFET） is proposed for high power microwave applications. Numerical models for the physical and electrical mechanisms of the device are presented, and the static and dynamic electrical performances are analysed. By comparison with the conventional structure, the proposed structure exhibits a superior frequency response while possessing better DC characteristics. A p-type spacer layer, inserted between the oxide and the channel, is shown to suppress the surface trap effect and improve the distribution of the electric field at the gate edge. Meanwhile, a lightly doped n-type buffer layer under the gate reduces depletion in the channel, resulting in an increase in the output current and a reduction in the gate-capacitance. The structural parameter dependences of the device performance are discussed, and an optimized design is obtained. The results show that the maximum saturation current density of 325 mA/mm is yielded, compared with 182 mA/mm for conventional MESFETs under the condition that the breakdown voltage of the proposed MESFET is larger than that of the conventional MESFET, leading to an increase of 79% in the output power density. In addition, improvements of 27% cut-off frequency and 28% maximum oscillation frequency are achieved compared with a conventional MESFET, respectively.

氢气传感器在电解制氧系统中的应用研究

针对电解制氧系统中氢气浓度测量受环境因素影响大、测量准确性低等问题,选取了半导体型、催化燃烧型、热导型三类不同原理的氢气传感器,对其在电解制氧系统中的应用进行了试验验证,并对试验结果进行了讨论,分析了各类氢气传感器的使用局限性。

基于CuO-ZnO的低温固体氧化物燃料电池性能

制备具有优异离子导电性和低温高化学性能的电解质是固体氧化物燃料电池实际应用的重要发展方向.基于p型CuO和n型ZnO构建p-n半导体异质结材料,并将其作为电解质应用于低温固体氧化物燃料电池.制备了不同质量比例CuO-ZnO的电解质材料,并组装Ni_(0.8) Co_(0.15)Al_(0.05)LiO_(2-δ)/CuO-ZnO/Ni_(0.8)Co_(0.15)Al_(0.05)LiO_(2-δ)单电池进行性能测试.结果表明,基于纯ZnO电解质材料的燃料电池性能最低(在550℃开路电压为为0.8 V,最大功率密度为187.5mW/cm^(2)),复合质量比例为1∶9的燃料电池性能最为优异(在550℃开路电压为1.065V,瞬时最大功率密度为555mW/cm^(2)).通过对CuO-ZnO异质结复合材料的电化学阻抗分析,发现构建的p-n半导体异质结为离子传输提供了通道,提高了离子电导率.研究表明p-n型电解质复合材料在低温固体氧化物燃料电池的应用中具有很大潜力.

基于磁控溅射法生长hBN薄膜的MSM型真空紫外探测器(特邀)

针对目前大面积高质量六方氮化硼(hBN)薄膜的制备与转移存在均匀性、晶粒控制、无损转移等问题,采用射频磁控溅射技术成功在2英寸硅和蓝宝石介电衬底上沉积了hBN薄膜,拉曼光谱、X射线光电子能谱表征证实了薄膜具有明显的hBN特征。制备了hBN基金属-半导体-金属型光电探测器,并探究了电极材料、薄膜厚度以及叉指电极宽度和间距对探测性能的影响。优选出的Ni电极探测器具有极低的暗电流(<3 pA@100 V),对185 nm波长光具有明显光响应,响应度和比探测率分别为2.769 mA/W和2.969×10^(9)Jones。

钙钛矿型CeTaN_(2)O的高压制备及其磁性和电学性质

最近研究发现,AB(N,O)_(3)型钙钛矿氧氮化物具有优异的介电、铁电、光催化等性能,在光电子、能源存储和通信等领域展现出广阔的应用前景.但是,目前该类型材料的制备工艺耗时较长且产物纯度较低.本文以氧化物为前驱体、以氨基钠为氮源,利用六面顶压机设备所提供的高温高压环境成功制备了高纯度的钙钛矿型氧氮化物CeTaN_(2)O块体材料,并将制备时间缩短至1 h,实现了快速合成.并对其晶体结构以及物理性质进行了系统的研究.X射线粉末衍射实验和Rietveld精修结果表明,所制备的样品属于正交晶系,空间群为Pnma.X射线吸收谱测试确定了样品的电荷组态以及阴离子组合为Ce^(3+)Ta^(5+)N_(2)O.磁性和比热测试表明,样品属于反铁磁物质,磁相变温度低于2 K.电学输运性能测试表明,样品的电阻率呈现出典型的半导体行为,且符合三维变程跳跃模型.

SnO晶体的可控水热合成与剥离

利用简单的水热合成法,成功合成高质量的SnO晶体。并通过控制溶液的pH实现对SnO晶体形貌和结构的调控。通过X射线衍射和扫描电子显微镜对其结构和形貌进行测试表征,测试结果表明,当溶液pH=11时,水热合成得到的SnO晶粒结构完整,形貌和横向尺寸最佳。之后通过透明胶带机械剥离制备2D SnO纳米片,电子力显微镜测试结果表明,2D SnO纳米片仍保持SnO块体P型导电的特性。

β-Ga_(2)O_(3)的p型掺杂研究进展

β-Ga_(2)O_(3)具有超宽禁带宽度、高击穿场强、较高的巴利加优值等优点使其成为一种新兴半导体材料,在高功率电子器件、气体传感器、日盲紫外探测器等方面有着极大的应用潜力,但p型掺杂难的问题成为了β-Ga_(2)O_(3)发展的巨大障碍。本文首先简要概述了β-Ga_(2)O_(3)的优点,并介绍了其晶体结构和基本性质。其次,说明了β-Ga_(2)O_(3)的本征缺陷,尤其是氧空位对导电性能的影响。然后,详细讨论了β-Ga_(2)O_(3) p型掺杂的研究现状,包括p型掺杂困难的原因和N掺杂、Mg掺杂、Zn掺杂、其他受主元素掺杂、两种元素共掺杂以及其他方法。最后,总结并对β-Ga_(2)O_(3)未来的发展进行了展望。

基于n型柔性半导体的有机晶体管及其电子-离子双响应特性

为了研究n型有机混合离子电子导体电子-离子双响应特性及分子量对载流子迁移率的影响,采用具有平面刚性的梯形分子链结构的高分子量聚苯并二咪唑苯并菲绕啉二酮制备高性能有机电化学晶体管,并对晶体管紫外可见吸收光谱和晶体管器件电气性能进行表征。结果表明,利用高分子量聚苯并二咪唑苯并菲绕啉二酮制备的n型有机电化学晶体管表现出极高的响应速度(0.034 s)、高载流子迁移率(4.72×10^(-3) cm^(2)/(V·s)),以及在水系电解液中优异的稳定性(稳定运行超过120次脉冲循环)。

氧化镍空穴材料在Ⅱ-Ⅵ族量子点电致发光器件中的应用进展

鉴于高效发光的Ⅱ-Ⅵ族量子点(Ⅱ-ⅥQD)电致发光(EL)器件已达到基本的商用需求,器件长期性能(寿命)受到了更多的重视。Ⅱ-ⅥQD EL器件中PEDOT:PSS材料易吸湿、易腐蚀ITO电极,这对器件寿命及商业应用潜力存在负面影响。采用高稳定性的NiO代替PEDOT:PSS可避免材料对器件稳定性产生影响。本文系统综述了NiO空穴材料在Ⅱ-ⅥQD EL器件中的研究进展,重点归纳了NiO薄膜的不同制备方法、掺杂和界面特性对器件性能的影响,最后对基于金属氧化物空穴功能层的Ⅱ-ⅥQD EL器件的研究趋势进行了展望,以期为制备在材料与器件层面稳定、高效的电致发光器件提供借鉴。

Structural stability at high pressure, electronic, and magnetic properties of BaFZnAs：A new candidate of host material of diluted magnetic semiconductors

The layered semiconductor BaFZnAs with the tetragonal ZrCuSiAs-type structure has been successfully synthesized.Both the in-situ high-pressure synchrotron x-ray diffraction and the high-pressure Raman scattering measurements demonstrate that the structure of BaFZnAs is stable under pressure up to 17.5 GPa at room temperature. The resistivity and the magnetic susceptibility data show that BaFZnAs is a non-magnetic semiconductor. BaFZnAs is recommended as a candidate of the host material of diluted magnetic semiconductor.

Synthesis and characterization of p-type boron-doped IIb diamond large single crystals

High-quality p-type boron-doped IIb diamond large single crystals are successfully synthesized by the temperature gradient method in a china-type cubic anvil high-pressure apparatus at about 5.5 GPa and 1600 K. The morphologies and surface textures of the synthetic diamond crystals with different boron additive quantities are characterized by using an optical microscope and a scanning electron microscope respectively. The impurities of nitrogen and boron in diamonds are detected by micro Fourier transform infrared technique. The electrical properties including resistivities, Hall coefficients, Hall mobilities and carrier densities of the synthesized samples are measured by a four-point probe and the Hall effect method. The results show that large p-type boron-doped diamond single crystals with few nitrogen impurities have been synthesized. With the increase of quantity of additive boron, some high-index crystal faces such as {113} gradually disappear, and some stripes and triangle pits occur on the crystal surface. This work is helpful for the further research and application of boron-doped semiconductor diamond.

氢气传感器研究型实验教学设计

依托科研项目及清华大学实验室创新基金,开展了关于钯-银合金氢气传感器的制备及性能研究的实验教学。围绕钯-银合金薄膜的制备、微结构、表面形貌和电学性能表征,介绍了半导体薄膜研究型实验教学的内容和实施方法,激发了学生的科学研究兴趣,探讨了研究型实验教学对培养学生创新思维和科研能力所起的作用。

Control over hysteresis curves and thresholds of optical bistability in different semiconductor double quantum wells

The effects of optical field on the phenomenon of optical bistability(OB) are investigated in a K-type semiconductor double quantum well(SDQW) under various parametric conditions. It is shown that the OB threshold can be manipulated by increasing the intensity of coupling field. The dependence of the shift of OB hysteresis curve on probe wavelength detuning is then explored. In order to demonstrate controllability of the OB in this SDQW, we compare the OB features of three different configurations which could arise in this SDQW scheme, i.e., K-type, Y-type, and inverted Y-type systems. The controllability of this semiconductor nanostructure medium makes the presented OB scheme more valuable for applications in all-optical switches, information storage, and logic circuits of all optical information processing.

Impulse Spatial-Temporal Domains in Semiconductor Laser with Feedback

An initial value boundary problem for system of diffusion equations with delay arguments and dynamic nonlinear boundary conditions is considered. The problem describes evolution of the carrier density and the radiation density in the semiconductor laser or laser diodes with “memory” and with feedback. It is shown that the boundary problem can be reduced to a system of difference equations with continuous time. For large times, solutions of these equations tend to piecewise constant asymptotic periodic wave functions which represent chain of shock waves with finite or infinite points of discontinuities on a period. Applications to the optical systems with linear media and nonlinear surface optical properties with feedback have been done. The results are compared with the experiment.

Te和Y共掺杂提高n-Mg_(3.2)Sb_(1.5)Bi_(0.5)热电性能的研究

Mg_(3)Sb_(2)材料是优秀的中温区热电材料,具有极低的热导率,然而其载流子浓度偏低。通过机械合金化法结合放电等离子烧结(SPS)技术制备n型Mg_(3.2)Y_(0.05)Sb_(1.5)Bi_(0.5)Teδ样品,并研究了其热电传输性能。结果表明阴离子位掺杂元素Te可以进一步提高阳离子位掺杂的Mg_(3.2)Y_(0.05)Sb_(1.5)Bi_(0.5)材料的载流子浓度。载流子浓度从5.02×10^(19)cm-3增加到9.76×10^(19)cm-3,接近理论预测的最佳值,同时功率因子也从10.89μW·K^(-2)·cm^(-1)提高到15μW·K^(-2)·cm^(-1).此外,Te元素进入晶格后,材料的晶格热导率也有大幅的降低,从0.92 W·m^(-1)·K^(-1)降低到0.68 W·m^(-1)·K^(-1).载流子浓度最高的样品在750 K时zT峰值可达1.6,在300~750 K温度范围内的平均zT值可达1.0.本工作证明阳离子和阴离子位共同掺杂对Mg_(3)Sb_(1.5)Bi_(0.5)载流子浓度提高的效果优于单阳离子或单阴离子位掺杂,该掺杂方法有望应用到其它的热电材料性能的优化中。