Random telegraph noise in the photoluminescence of individual GaxIn1-xAs quantum dots in GaAs

We have investigated random telegraph noise in the photoluminescence from InGaAs quantum dots in GaAs. Dots switching among two and three levels have been measured. The experiments show that the switching InGaAs dots behave very similarly to switching InP dots in GaInP. but differently from the more commonly investigated colloidal dots. The switching is attributed to defects, and we show that the switching can be used as a monitor of the defect.

Hydrogen sensors based on Pt-AlGaN/GaN back-to-back Schottky diode

In this paper, platinum (Pt) with a thickness of 45 nm was sputtered on the surface of AlGaN/GaN heterostructure to form the Schottky contact and the back-to-back Schottky diodes were characterized for H-2 sensing at room temperature. Both the forward and reverse current of the devices increased with exposure to H-2 gas, which was attributed to Schottky barrier height reduction caused by hydrogen absorption in the catalytic metals. A shift of 0.7 V at 297 K was obtained at a fixed forward current of 0.1 mA after switching from N-2 to 40% H-2 in N-2. The sensor's responses under different concentrations from 2500 ppm H-2 to 40% H-2 in N-2 at 297 K were investigated. Time response of the sensor at a fixed bias of 1 V was given. Finally, the decrease of the Schottky barrier height and the sensitivity of the sensor were calculated. (C) 2008 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Hydrogen sensors based on Pt-AlGN/AIN/GaN Schottky diode - art. no. 68291R

Pt/AlGaN/AlN/GaN Schottky diodes have been fabricated and characterized for H-2 sensing. Platinum (Pt) with a thickness of 20nm was evaporated on the sample to form the Schottky contact. The ohmic contact, formed by evaporated Ti/Al/Ni/Au metals, was subsequently annealed by a rapid thermal treatment at 860 degrees C for 30 s in N-2 ambience. Both the forward and reverse current of the device increased greatly when exposed to H-2 gas. The sensor's responses under different hydrogen concentrations from 500ppm to 10% H-2 in N-2 at 300K were investigated. A shift of 0.45V at 297K is obtained at a fixed forward current for switching from N-2 to 10% H-2 in N-2. Time response of the sensor at a fixed bias of 0.5 V was also measured. The turn-on response of the device was rapid, while the recovery of the sensor at N-2 atmosphere was rather slow. But it recovered quickly when the device was exposed to the air. The decrease in the barrier height of the diode was calculated to be about 160meV upon introduction of 10% H-2 into the ambient. The sensitivity of the sensor is also calculated. Some thermodynamics analyses have been done according to the Langmuir isotherm equation.

Effect of pulse heating parameters on the microscale bubble dynamics at a microheater surface

We study the effects of pulse heating parameters on the micro bubble behavior of a platinum microheater (100 mu m x 20 mu m) immersed in a methanol pool. The experiment covers the heat fluxes of 10-37 MW/m(2) and pulse frequencies of 25-500 Hz. The boiling incipience is initiated at the superheat limit of methanol, corresponding to the homogeneous nucleation. Three types of micro boiling patterns are identified. The first type is named as the bubble explosion and regrowth, consisting of a violent explosive boiling and shrinking, followed by a slower bubble regrowth and subsequent shrinking, occurring at lower heat fluxes. The second type, named as the bubble breakup and attraction, consists of the violent explosive boiling, bubble breakup and emission, bubble attraction and coalescence process, occurring at higher heat fluxes than those of the first type. The third type, named as the bubble size oscillation and large bubble formation, involves the initial explosive boiling, followed by a short periodic bubble growth and shrinking. Then the bubble continues to increase its size, until a constant bubble size is reached which is larger than the microheater length. 

Transient flow patterns and bubble slug lengths in parallel microchannels with oxygen gas bubbles produced by catalytic chemical reactions

Transient flow patterns and bubble slug lengths were investigated with oxygen gas (O-2) bubbles produced by catalytic chemical reactions using a high speed camera bonded with a microscope. The microreactor consists of an inlet liquid plenum, nine parallel rectangular microchannels followed by a micronozzle, using the MEMS fabrication technique. The etched surface was deposited by the thin platinum film, which is acted as the catalyst. Experiments were performed with the inlet mass concentration of the hydrogen peroxide from 50% to 90% and the pressure drop across the silicon chip from 2.5 to 20.0 kPa. The silicon chip is directly exposed in the environment thus the heat released via the catalytic chemical reactions is dissipated into the environment and the experiment was performed at the room temperature level. It is found that the two-phase flow with the catalytic chemical reactions display the cyclic behavior. A full cycle consists of a short fresh liquid refilling stage, a liquid decomposition stage followed by the bubble slug flow stage. At the beginning of the bubble slug flow stage, the liquid slug number reaches maximum, while at the end of the bubble slug flow stage the liquid slugs are quickly flushed out of the microchannels. Two or three large bubbles are observed in the inlet liquid plenum, affecting the two-phase distributions in microchannels. The bubble slug lengths, cycle periods as well as the mass flow rates are analyzed with different mass concentrations of hydrogen peroxide and pressure drops. The bubble slug length is helpful for the selection of the future microreactor length ensuring the complete hydrogen peroxide decomposition. Future studies on the temperature effect on the transient two-phase flow with chemical reactions are recommended.

胶体体系的固化及分离过程的计算机模拟

胶体体系是自然界很重要的组成部分，广泛应用于工业生产和日常生活中。胶体体系在固化的过程中，会形成有序的晶体结构或无序的玻璃态结构。对胶体的结晶和玻璃化的认识对研究相变理论，纳米材料以及自组装有着重要的意义。事实上，在这一领域存在着许多悬而未决的问题。另一方面，胶体的分离也是胶体科学研究中不可或缺的步骤。特别是近年来微流器件技术的进步为流体动力学色谱分离方法带来了进一步发展的机会，这为胶体的分离提供了非常有效的实验手段。然而，由于实际应用过程的复杂性，理论方法还不足以深入探讨胶体粒子体系固化和分离的本质。作为一种可以直接反映物理过程的研究方法，计算机模拟成为一种有效的研究胶体粒子固化和分离的手段。 硬球模型是一种最简单的胶体粒子体系，能够很好地描述具有体积排斥作用的胶体粒子的行为，因此，对于胶体粒子体系固化问题，我们采用分子动力学方法研究了硬球粒子体系的固化过程。此外，对于胶体和高分子体系的分离过程，我们主要采用耗散分子动力学（dissipative particle dynamics DPD）进行研究。论文的主要内容包括： 1)采用硬球分子动力学模型，研究了胶体颗粒在不同的压缩速率下得到的堆积态的结构异质性。我们应用Lubachevsky-Stillinger方法，在不同的压缩速率下得到了一系列的结构受限的硬球堆积状态。这些体系的有序度随着压缩速率的减小而增加，而体系的密度则是先增加后减小又增加，在中间压缩速率时出现最小值。通过测量体系中的局域序参量分布，粒子位置的均方根涨落分布和直接观察受限粒子的位置，发现这些状态中包含有无规区域和结晶区域，存在显著的结构异质性。特别的是低密度状态中许多小的有序区域互相连接成贯穿体系的逾渗网络，说明晶区之间的结构不匹配是生成这些状态的重要机理。 2)用DPD方法模拟了线性高分子链和星形高分子链在穿越纳米孔道的输运过程。对复合管道中小管的半径分别为2.5 和2.0 的两种情况进行了研究。在各种情况下我们都发现了存在一个临界流量Jc，只有当流量大于Jc的时候高分子才能进入纳米孔洞。对于线性高分子，长链的高分子进入同样粗细的小管所需要的临界流量比短链大。线性链和星形链在半径是2.0小管子中的临界流量比通过半径2.5的管子的临界流量大，或者近似相同。在半径2.5的小管中，星形高分子的临界流量要大于同等尺寸的线性高分子。此外，我们没有观察到不同接枝数的星形高分子的临界流量之间的差异。出现这种情况的原因可能是DPD模型中粒子间的相互作用势能很软，所以不能很好地体现出不同接枝数的星形高分子在位阻上的差异。 3）我们利用DPD方法模拟了圆柱形管道中线性高分子链的输运过程。比较了模拟得到的高分子保留时间和DG理论预测值之间的差异。发现分子量越大的高分子对DG理论的偏离越显著。计算了高分子链在流动过程中伸长的情况，发现了链的伸长率S与Weissenberg number 有着明确的标度关系。与狭缝中的情况类似，对于圆柱型管道中流动的线性高分子，如果采用修饰过的Peclet number，则能够更好地满足Aris-Taylor分散的标度关系。 4)我们建立了纳米粒子在DPD模拟的动力学模型，研究了在本体溶液中纳米粒子的自扩散系数和速度关联函数对与胶体粒子的半径定性关系。发现纳米粒子的扩散系数随粒子半径的增加而减小。纳米粒子的半径越大，其速度关联函数的衰减越慢，同样大小纳米粒子的质量越大，其速度关联函数衰减得越慢。我们进一步模拟了在狭缝中纳米粒子的输运过程。通过观察流体受限方向的流速曲线，我们发现由于与器壁之间的体积排斥作用，使得纳米粒子远离流体的边界。对Aris-Taylor分散的研究结果表明，在λ不大的时候，应用不同的Peclet numbers 对分散方程结果的影响不大。

Photoluminescence of ZnS clusters in zeolite-Y

Two obvious emissions are observed from the ZnS clusters encapsulated in zeolite-Y. The emission around 355 nm is sharp and weak, locating at the onset of the absorption edge. The band around 535 nm is broad, strong and Stokes-shifted. Both the two emissions shift to blue and their intensities firstly increase then decrease as the loading of ZnS in zeolite-Y or clusters size decreases. Through investigation, the former is attributed to the excitonic fluorescence, and the latter to the trapped luminescence from surface states. The cluster size-dependence of the luminescence may be explained qualitatively by considering both the carrier recombination and the nonradiative recombination rates. Four peaks appearing in the excitation spectra are assigned to the transitions of 1S-1S, 1S-1P, 1S-1D and surface state, respectively. The excitation spectra of the clusters do not coincide with their absorption spectra. The states splitted by quantum-size confinement are detected in the excitation spectra, but could not be differentiated in the optical absorption spectra due to inhomogeneous broadening. The size-dependence of the excitation spectra is similar to that of the absorption spectra. Both the excitation spectra of excitonic and of trapped emissions are similar, but change in relative intensity and shift in position are observed.

Wettability designing by ZnO periodical surface textures

A facile and effective aqueous chemical synthesis approach towards well control of periodical ZnO textures in large-scale areas is reported, by which considerable adjusting of surface wettability can be realized. With the assistance of polystyrene spheres monolayer template and morphology control agent, we succeeded in preparing a series of ordered ZnO microbowls with different sag height. It was found that the contact angle could be well adjusted by changing geometry of microbowl. Such novel, ordered arrays are expected to exploit the great potentiality in waterproof or self-cleaning micro/nanodevices, and even microfluidic devices. (C) 2010 Elsevier Inc. All rights reserved.

Evaluation of the Uncertainties Caused by the Forward Scattering in Turbidity Measurement of the Coagulation Rate

The forward scattering light (FSL) received by the detector can cause uncertainties in turbidity measurement of the coagulation rate of colloidal dispersion, and this effect becomes more significant for large particles. In this study, the effect of FSL is investigated on the basis of calculations using the T-matrix method, an exact technique for the computation of nonspherical scattering. The theoretical formulation and relevant numerical implementation for predicting the contribution of FSL in the turbidity measurement is presented. To quantitatively estimate the degree of the influence of FSL, an influence ratio comparing the contribution of FSL to the pure transmitted light in the turbidity measurement is introduced. The influence ratios evaluated under various parametric conditions and the relevant analyses provide a guideline for properly choosing particle size, measuring wavelength to minimize the effect of FSL in turbidity measurement of coagulation rate.

流体力学半径对估算胶体微球聚集速率常数的影响

胶体粒子聚集速率常数实验值远低于理论值一直是被普遍关注的问题.聚集速率常数的理论推导是基于粒子的几何半径来考虑的,但决定粒子扩散速率及聚集速率的应该是粒子的流体力学半径(大于几何半径),因而它是使聚集速率常数实验值低于理论值的因素之一.影响流体力学半径的因素很多,其中,带电粒子在溶液中因表面存在双电层,会明显增大流体力学半径,造成聚集速率减慢.而双电层的厚度又随溶液中离子强度的不同而改变.本工作在聚集速率的公式中引入了修正因子,即几何半径与其流体力学半径之比,以修正由于用几何半径代替流体力学半径带来的误差.其中几何半径和流体力学半径可以分别用扫描电镜(SEM)和动态光散射(DLS)来测定.以两种粒径的聚苯乙烯带电微球为例,考察了在不同离子强度下,该误差的大小.结果发现,对于半径为30 nm的微球,用流体力学半径计算的慢聚集速率常数比理论值偏低约8%.该误差随离子强度增加而减少.对于快聚集情况,流体力学半径对聚集速率基本没有影响.

细铂丝表面池沸腾临界热流尺度效应研究

本文实验研究了地面重力环境中过冷度和加热铂丝直径对FC-72和丙酮池沸腾传热临界热流现象的影响. 实验结果表明,临界热流具有明显的尺度效应,其特征随Bond数范围的不同而不同,但具体的分区准则依赖于工质的物性. 在中等和大的Bond数区域,过冷度对临界热流的影响与铂丝直径无关;而在小Bond数区域,过冷度效应与尺度明显相关