制备条件对气凝胶粉末粒径的影响

 利用超声波乳化技术，结合溶胶-凝胶反应制备了间苯二酚-甲醛有机气凝胶粉末和碳化气凝胶粉末。通过大量实验，探讨了制备条件对气凝胶粉末粒径的影响。在粉末干燥前以Zeta电位-粒径分布测试仪对乙醇悬浊液进行分析测试，对有机粉末和碳化粉末用TEM方法进行表征。研究了反应液质量分数、反应温度和时间以及分散剂与反应液体积比对产物粒径的影响。实验表明：制备条件对于制备纳米级的气凝胶粉末影响非常大，通过优化实验条件可以制备出分布较好的气凝胶粉末，超声功率较大容易实现体系均匀混合，反应液在反应过程中温度和时间的控制起着关键的作用，低质量分数的反应液所生成的产物比高质量分数的粒径要小,经碳化后粉末粒径进一步降低。     

分散剂对RF凝胶掺钛过程的影响

 以间苯二酚、甲醛和经分散的纳米钛粉为反应前体，利用物理掺杂方法研究了掺钛RF凝胶的制备工艺，并在凝胶过程中以zeta电位 粒径分布测试仪对溶液的粒径分布进行分析测试。实验发现六偏磷酸钠对纳米钛粉的分散性最好，掺杂后凝胶时间明显缩短；分散剂种类和用量对凝胶时间有较大影响，其用量为纳米钛粉量的50~100倍为宜。     

PEG6000溶液超声化学反应机理的初步研究

采用不同电功率的超声波处理了聚乙二醇(PEG6000)溶液。凝胶渗透色谱(GPC)分析超声处理后的PEG溶液发现,当超声电功率超过250W时,PEG分子量随超声波作用强度的增大而减少,随超声波作用时间的延长而增大;在电功率超过250W超声波作用下,傅立叶红外光谱(FT-IR)分析表明,组成PEG的单体没有明显改变,但是,羟基含量分析表明,PEG固体样品中的羟基含量有所减少。结合实验结果,根据高分子化学、有机化学和超声化学中相关理论对PEG超声化学反应机理进行了探讨,认为:当超声波作用于PEG溶液时,同时存在有PEG的缩水聚合反应和自由基降解反应,当频率为20-25kHz、电功率为250-600W的超声作用于PEG6000溶液时,缩水聚合反应占主导地位。     

间苯三酚-乙醛有机气凝胶的制备与表征

 以碳酸钠为催化剂,乙醇为溶剂,间苯三酚 乙醛为反应前躯体,经溶胶 凝胶、交联老化、二氧化碳超临界干燥制备出间苯三酚-乙醛(PA)有机气凝胶。扫描电镜观察和N2吸附测试结果表明：气凝胶具有较高的比表面积,是一种连续nm级３维网络结构的多孔材料,其比表面积为1 210 m²/g,平均孔径为11 nm,与传统有机气凝胶相比,提高了比表面积,一定程度上实现有机气凝胶的扩孔。     

紫外光固化聚丙烯酰/SiO2有机/无机杂化气凝胶制备

 采用自制的甲基丙烯酰多羟基倍半硅氧烷制备了UV固化的有机/无机杂化湿凝胶。湿凝胶经CO₂超临界干燥后即得到相应的杂化气凝胶,气凝胶经场发射扫描电子显微镜,高分辨透射电镜分析表明：构成气凝胶3维珍珠链结构的骨架的颗粒尺寸为20～30 nm,骨架上具有5～10 nm的孔洞结构,骨架颗粒有机、无机组分间没有明显的相界面。气凝胶的比表面积、吸附特性和微观孔结构采用经典的N₂吸附法获得,结果表明气凝胶比表面积为520.9 m²/g,孔洞结构主要由50 nm以下的介孔所构成。     

对苯二酚-甲醛碳气凝胶的制备

 溶胶-凝胶法制备了高HC比（10~40，对苯二酚与催化剂(Na₂CO_{3/sub>)的物质的量之比）的对苯二酚-甲醛有机气凝胶，并经高温碳化处理得到其碳气凝胶。借助有机气凝胶的红外光谱研究了其化学结构，说明其网孔结构形成的可能性；研究了有机气凝胶的扫描电镜图像、比表面积及孔径分布等，并得到碳化前后的一些对比数据：有机气凝胶颗粒大小30~50 nm，碳化后约为10 nm，比表面积从341.77 m²/g增大到452.75 m²/g，密度从0.170 8 g/cm^{3/sup>增大到0.335 6 g/cm3/sup>。}}     

纳米多孔碳气凝胶的储氢性能

 以间苯二酚和甲醛为原料,采用溶胶-凝胶工艺,结合高温碳化和溶剂替换常压干燥技术,制备了碳气凝胶。通过改变间苯二酚与碳酸钠的物质的量比和反应物间苯二酚与甲醛的质量分数,实现对碳气凝胶孔洞结构的控制。制备了钯掺杂碳气凝胶。以透射电镜、X射线衍射谱证实了钯元素以纳米单质颗粒形式存在于碳气凝胶的骨架结构中。对掺杂碳气凝胶进行了活化工艺的后处理,成功提高了比表面积有2倍之多,获得了比表面积为1 273 m²/g的钯掺杂碳气凝胶。氢吸附性能研究结果表明：最优活化工艺所得的碳气凝胶样品（3 212 m²/g）在92 K,3.5 MPa条件下的饱和储氢质量分数为3%,此样品在303 K,3.2 MPa时的储氢质量分数为0.84%。对钯掺杂碳气凝胶的常温（303 K）氢吸附测试表明,掺杂后碳气凝胶的总储氢质量分数下降了,但单位比表面积的储氢质量分数提高了。     

常压干燥法制备碳气凝胶及其电极性能研究北大核心CSCD

以间苯二酚-甲醛为前驱体,通过加入P123以增强有机气骨架的方法,采用常压干燥技术制备碳气凝胶电极材料,有机凝胶在干燥过程中收缩率极大降低。通过二氧化碳活化法对常压干燥获得的碳气凝胶孔结构进行了调控。研究了不同温度对其结构的影响,获得了最高比表面积达3544m2/g的碳气凝胶。6mol/L的KOH电解液中测试表明,常压干燥碳气凝胶具有稳定的充放电性能,随着活化温度的升高,比容量逐渐增加,最高比电容可达261F/g。常压干燥技术制备的碳气凝胶电极材料在降低生产成本的同时,仍具有理想的电化学性能。     

高氢容量硼氢化锂/碳气凝胶复合材料的制备与性质北大核心CSCD

采用"纳米装填"技术和"熔化渗透"工艺成功制备了氢容量在硼氢化锂质量分数80%以上的硼氢化锂/碳气凝胶复合材料。并用扫描电镜、透射电镜、傅里叶红外透射光谱等手段表征了复合材料的结构与性能。发现硼氢化锂填充了碳气凝胶骨架孔隙的90%以上,形成均匀的复合材料。研究了复合材料的形成机制,发现硼氢化锂先进入碳气凝胶骨架的小孔,再逐渐填充大孔。这有利于材料晶粒的细化,提高吸放氢性能,减少结构缺陷。经放氢动力学测试表明,LiBH4/CRF复合材料的放氢速率是文献中LiBH4与活性炭的球磨样品的5倍。     

纳米TiO2光催化剂防团聚的光谱研究

本文用溶胶 凝胶过程超临界CO2 萃取制备纳米二氧化钛气凝胶 ,用FT Raman ,FTIR ,FS分别对初生态气凝胶粒子、在常态下以气凝胶形式保存了 36 0天的TiO2 纳米粒子及以初生态气凝胶的粉体保存了36 0天的TiO2 粒子进行表征 ,以光催化降解甲基橙为模型反应 ,结果表明 ,在常态下以气凝胶形式保存纳米TiO2 粒子能有效地防止由纳米TiO2 表面超亲水性引起粒子间的团聚 ,保持了初生态粒子的光催化活性。     

间苯二酚-甲醛气凝胶空心微球制备技术

 采用微流体注射成型技术,以邻苯二甲酸二丁酯为内外油相,间苯二酚/甲醛(RF)溶液为水相,经过溶胶-凝胶、溶剂交换、超临界干燥等过程制备出了RF气凝胶空心微球。分别采用红外光谱、光学显微镜、X光显微分析、透射电镜(TEM)、N­₂吸附-脱附,对RF空心微球成分、形貌、孔径、直径分布等进行表征。结果表明：RF为单层空心微球,具有典型的气凝胶多孔结构,由粒径为10 nm左右、且粒度分布较为均匀的纳米粒子构成,平均孔径为20 nm左右,球形度和同心度大于95%,微球直径分布在550～750 mm,最大可达到800 mm,达到了快点火靶的基本要求。     

Effective ultrasound electrochemical degradation of methylene blue wastewater using a nanocoated electrode

A novel sonoelectrochemical catalytic oxidation-driven process using a nanocoated electrode to treat methylene blue (MB) wastewater was developed. The nano-scale (nanocoated) electrode generated more hydroxyl radicals than non-nano-scale (non-nanocoated) electrodes did. However, hydroxyl radicals were easily adsorbed by the nanomaterial and thus were not able to enter the solution. Supersonic waves were found to enhance the mass-transfer effect on the nanocoated electrode surface, resulting in rapid diffusion of the generated hydroxyl radicals into the solution. In solution, the hydroxyl radicals then reacted with organic pollutants in the presence of ultrasonic waves. The effect of the nanocoated electrode on the MB wastewater treatment process was enhanced by ultrasound when compared to the non-nanocoated electrode used under the same conditions. The synergy of the nanocoated electrode and ultrasonic waves towards MB degradation was then studied. The optimum operating conditions resulted in a 92% removal efficiency for TOC and consisted of a current of 600 mA, an ultrasound frequency of 45 kHz, and a supersonic power of 250 W. The mechanism of ultrasound enhancement of the nanocoated electrode activity with respect to MB treatment is discussed. The reaction intermediates of the sonoelectrochemical catalytic oxidation process were monitored, and degradation pathways were proposed. The sonoelectrochemical catalytic oxidation-driven process using nanocoated electrodes was found to be a very efficient method for the treatment of non-biodegradable wastewater.     

超音速分离管在天然气制冷液化领域中的研究进展

超音速分离管是一种新型、高效的天然气制冷设备。该装置因具有节能、结构简单、性能可靠等优点,在天然气脱水脱烃中己经获得了成功的应用,并在小型天然气液化装置中有良好的应用前景。文中介绍了超音速分离管的工作原理以及在天然气制冷液化领域中的研究进展,并对该装置中分离管的设计方法及影响制冷、分离效果的因素进行了分析。     

超声速后台阶流动/射流相互作用的数值模拟

采用高精度格式求解二维Navier-Stokes方程研究超声速射流与同向超声速后台阶流动相互作用的流场基本结构及规律,分别应用5阶WENO格式、6阶中心差分格式离散对流项和黏性项,时间推进采用3阶Runge-Kutta格式,并应用消息传递接口（message passing interface,MPI）非阻塞式通信实现并行化.分别研究了超声速后台阶流动、超声速射流的基本结构特征,以此讨论和分析超声速后台阶流动/射流相互作用的特征,以及不同来流条件对波系结构、涡结构、剪切层、膨胀扇等的影响,尤其是来流剪切层和射流剪切层的相互作用,形成复杂的波系结构及相互干扰的流动现象.      

Supersonic CO2 laser excited by RF discharge in closed cycle

A supersonic gas flow having a Mach number of 2 has been realized in a closed-cycle radio-frequency (RF)-discharge-excited supersonic CO₂ laser system. Stable RF discharge at a high CO₂ gas concentration has become possible using supersonic gas flow and RF discharge generated between dielectric electrodes. As a result, high RF input power density has been obtained. In addition, a high small-signal gain has been obtained in the supersonic section through decreases in gas pressure and gas temperature due to supersonic gas flow.This revised version was published online in August 2005 with a corrected cover date.     

间苯二酚-甲醛凝胶自发成膜技术研究

 以间苯二酚和甲醛为原料，对水相溶胶-凝胶聚合自发成膜技术获得间苯二酚-甲醛(RF)凝胶薄膜进行了研究。主要研究了溶胶-凝胶过程中冰醋酸（HAC）含量和反应温度对凝胶过程的影响，分析了RF有机凝胶自发成膜的形成机理。IR和SEM分析表明，所得到的凝胶膜具有典型的RF有机气凝胶结构，薄膜厚度大约为50 μm，膜由直径10 μm左右的粒子组成，没有观察到明显的孔洞结构。分析认为，在间苯二酚和甲醛占总溶液的质量分数为67％左右及控制pH值在一定的酸性范围，RF凝胶自发成膜过程和机理可以用RF凝胶的收缩机理加以解释，RF自发膜的表面形貌及形成机理与均匀泡沫的连续相分离机理类似。     

Novel concept of electric discharge oxygen-iodine laser

A novel concept of discharge oxygen-iodine laser (DOIL) is presented. The supersonic DOIL includes a discharge singlet oxygen generator (DSOG) and discharge atomic iodine generator (DAIG). The operation of DSOG is based on a fast mixing of hybrid argon plasma jet of DC electric arc and RF discharge with a neutral molecular oxygen stream. The goal of our effort is achievement of DOIL oscillations by this new discharge technique, which should provide the singlet oxygen yields exceeding 30% at the total pressures higher than 10 torr. The DAIG operation is based on a cw/pulse RF discharge dissociation of iodine donors directly inside a laser iodine injector. This method substitutes the classic dissociation of molecular iodine by energy of singlet oxygen, which saves its energy for laser generation and so can increase the laser efficiency. The laser power could be thus enhanced by up to 25% if this method is employed in a chemical oxygen-iodine laser (COIL) operation, and even 3 times in DOIL without increase in the iodine laser pumping by singlet oxygen.     

Theoretical and Experimental Investigations of the Flow Field for Asymmetric Dual-Flow Interrupter Nozzles

Experimental investigations have indicated that electrode vapor can have a significant negative effect in thermal interruption speed for the gas-blast circuit breakers. This electrode vapor contamination can be minimized by the use of asymmetric dual-flow nozzle configuration. A computer program was developed to design the nozzle and electrode geometries of the asymmetric dual-flow interrupter and to calculate both the subsonic and supersonic cold flow fields. The Variational Principle of the finite element method, together with a Newton-Raphson iterative scheme, was used to solve the continuity equation for compressible flow. The supersonic flow field in the conical nozzle was calculated by the one-dimensional flow relationship. Two asymmetric dual-flow nozzle models were constructed to investigate the effects of orifice opening and nozzle divergent angle. The cold flow experiments were conducted in the Rensselaer Polytechnic Institute (RPI) Transonic and Supersonic Wind Tunnel Laboratory. Various upstream-to-downstream nozzle pressure ratios were used to obtain the subsonic and supersonic experimental flow-field data. The experimental flow measurements were correlated with the calculated values to validate the computer program.     

Initial heating mechanism of fluids after photoexcitation of molecules in various phases

Heating rates after photoexcitation of several organic molecules have been studied by the transient grating spectroscopy with sub-picosecond laser pulses in solution and supercritical fluids. The rise time of the acoustic signal produced by the energy dissipation process of the hot ground state molecule was monitored. The acoustic signal was analyzed by an equation including the acoustic damping. The solvent temperature rise times in various media have been determined. The temperature rise times in solutions were longer than the vibrational energy relaxation times of the solutes determined by the transient absorption measurements. The difference was discussed in terms of the contribution of vibrational states in the energy transfer pathways from the solute to the solvent. It was found that the hydrogen-bonding between the solute and solvent play important roles in determining the energy transfer pathway from the solute to the solvent.     

Vortex dynamics in different combustion regions of a cavity-based scramjet

A hybrid RANS/LES study of a cavity-based scramjet was performed and reasonable agreements were found between simulation results and experimental measurements. In the current case, the flame was stabilized by the subsonic cavity shear layer and propagated downstream into the supersonic flow. The vortex dynamic in the flow, mixing, and combustion regions was comparatively investigated. The averaged vorticity in the combustion regions was lower by 55% compared to the mixing region, primarily due to dilatation as a result of the heat release. Furthermore, the combustion zone was decomposed into four regions based on premixed/diffusion flame and subsonic/supersonic combustion. Then the vorticity and its transport in the four regions were compared. The averaged vorticity in the premixed combustion regions was only slightly larger than that in the diffusion combustion regions. However, the averaged heat release rate was nearly 3 times larger in the premixed regions, leading to higher contributions of dilatation and baroclinic torque in the premixed regions, with an overall weak positive impact on the vorticity generation. In the subsonic combustion regions, the vorticity was three times larger than that in the supersonic combustion regions, despite similar heat release rates on average. It could be explained by the relatively large magnitude of dilatation and baroclinic torque in the supersonic flow. Vortex stretching and dilatation were comparable in the supersonic flame but the former became two times larger than the latter in the subsonic flame. Moreover, the baroclinic torque had larger contributions than diffusion in the supersonic flame whereas the opposite trend was found in the subsonic flame. The results highlight that the subsonic combustion regions in the cavity shear layer and near the walls significantly contribute to the vortex dynamics and mixing process, in addition to flame stabilization.