介质阻挡放电等离子体甲烷/水蒸气重整制氢

采用自制的介质阻挡放电实验系统,进行了甲烷/水蒸气大气压下重整制氢实验研究。考察了水碳比（水蒸气/甲烷物质的量比）、气体总流量、放电电压和放电频率对甲烷转化率及氢气等主要产物产率的影响。结果表明,甲烷转化率和氢气产率随着水碳比和放电电压的增加而增大,随着气体总流量和放电频率的增加呈现先增大后减小的变化规律。在放电电压18.6 kV、放电频率9.8 kHz、水碳比3.4、反应气体总流量79 mL/min时,获最大氢气产率（14.38%）。此外,利用发射光谱对放电过程中的活性基团进行了原位诊断,得到了CH·、OH·、H₂及H_α活性粒子的光谱信号强度随实验参数的变化规律,并结合放电机理推测了氢气的生成路径。     

高频介质阻挡放电烟气脱硫研究

采用高频介质阻挡放电的方式产生低温等离子体,研究在不加入NH₃的情况下流动态SO₂的去除情况.实验表明,在输入电压为12 kV,SO₂浓度为5400 mg/m³,气体流量为0.36 m³/h,相对湿度为55%时,脱硫率可达到70%以上;水气的存在对SO₂的去除有较大的促进作用,升高电压和增加O₂量对脱硫率的促进作用有限.对实验结果进行了解释,并提出了反应机理.     

介质阻挡放电引发氮氧化物等离子体化学反应

在523 K介质阻挡放电条件下,研究了不同气体组分体系中NO的转化.实验表明,在无氧体系(NO/N2)中,转化的NO主要分解为N2和O2.在富氧(NO/O2/N2)条件下,由于NO和NO2的生成, NO的转化率最低.体系中加入C2H4(NO/C2H4/N2)时, NO转化率与NO/N2体系几乎一样,与NO相比,生成的O更易与C2H4作用,几乎没有NO2的生成.当C2H4和O2共存时(NO/O2/C2H4/N2),NO主要被氧化为NO2.当能量密度为125 J•L－1时, 与其它体系相比,NO/O2/C2H4/N2体系中NO转化率和NO2生成量最大,转化每个 NO分子能耗最小(61 eV).体系中C2H4主要被氧化为CO.四个体系中N2O的生成量都较少.讨论了介质阻挡放电条件下上述四个体系可能的反应机制.     

介质阻挡放电离子源质谱分析

敞开式离子化质谱可对表面样品进行直接快速分析而受到关注,成为质谱分析的热点研究方向.介质阻挡放电离子源是一种基于等离子体放电机理的敞开式离子源,近年来得到了较快的发展.本文着重介绍该离子源的基本原理、性能特征以及应用进展,并对其发展趋势进行了展望.     

甲烷二氧化碳介质阻挡放电转化产物分布研究

针对介质阻挡放电甲烷二氧化碳转化实验,分析了反应的产物分布,探讨了进料组成和反应器结构对反应的影响.反应产物包括:高H2/CO摩尔比的合成气、气态烃、高辛烷值的汽油组分、醇和酸等含氧有机物.对所述电极结构,产物的选择性随碳数增加而降低;高的甲烷进料浓度有利于烃的生成,对醇和酸的最佳甲烷进料体积分数范围在67.4％～75.1％;放电间隙越小,原料转化率和烃、酸的选择性越大,大的放电间隙对醇的生成有利.     

介质阻挡放电净化恶臭气体的实验研究

低温等离子体技术是一种新型的污染治理技术,国内外都对其进行了广泛而深入的研究。等离子体是电子,正、负离子,激发态原子、分子,以及自由基混杂的状态,是一种高反应活性的气体,理论上可以引发许多用常规方法难以发生的化学反应,已在废气、废水、固体废物以及放射性废物等方面     

介质阻挡放电等离子体催化天然气偶联制C2烃

在常压、室温的介质阻挡放电连续流动反应器中, 对介质阻挡放电等离子体作用下天然气偶联反应制C₂烃进行了研究. 考察了放电频率、放电的电极结构、放电电压、放电的电极数目、氢气、甲烷进料流量和催化剂等参数对甲烷转化率和产物(碳二烃和碳三烃)的选择性影响规律, 同时探讨了反应过程. 结果表明合适的工艺条件为: 电源频率20 kHz, 电极结构为两个电极上都覆盖绝缘介质的b型, 放电电压20~40 kV, 进料流量20~60 mL·min^-1, H₂/CH₄为1/4; 甲烷的转化率随电压的升高而增大, 随甲烷进料流量的增大而减小, 碳二烃的选择性随电压的升高而减小, 随甲烷进料流量的增大而增大. 甲烷的转化率可达45%, 碳二烃选择性可达76%, 产品(碳二烃和碳三烃)的总选择性接近100%; 连续反应100 h无积碳; 催化剂可改善产品碳二烃的选择性; 碳二烃和碳三烃的生成主要是通过自由基和甲烷分子反应获得的.     

不对称C―H/C―H交叉脱氢偶联反应研究进展

近年来交叉脱氢偶联(CDC)反应在有机合成化学领域受到广泛关注,该策略在构建碳-碳键的反应中避免了底物的预官能团化,具有很高的原子经济性,符合绿色化学的发展要求。通过不对称CDC反应可以实现立体选择性构建碳-碳键,是目前有机合成中的热点研究领域。本文综述了不对称CDC反应研究进展,并对该领域未来的发展方向进行了展望。     

介质阻挡放电等离子体甲烷部分氧化重整制氢

在自制的介质阻挡放电等离子体重整制氢装置上进行了甲烷部分氧化重整制氢的实验研究. 本文研究了氧碳(O/C)摩尔比, 进气流量, 放电间隙, 放电区间长度, 填充物的直径、形状和材料, 放电电压和放电频率对甲烷转化率、氢产率和产物的选择性(H₂、CO和CO₂)的影响. 实验结果表明: 放电区域的参数对甲烷转化率有较大的影响. 甲烷转化率随着放电区域长度的增大而增大, 当放电区域长度从5 cm增大到20 cm时, 甲烷转化率从6.87%增大到22.26%, 增大率为224%. 同时, 放电区域的填充物对产氢效果有较大的影响. 当反应器填充颗粒时, 甲烷转化率比无填充物时高. 选择适当介电常数的填充物具有巨大的实际工程意义. 另外, 氢产率和氢气的选择性随着放电频率的增大而增大, 当放电频率从1.5 kHz 增大到7.0 kHz 时, 氢产率从1.10%增大到9.49%, 氢气的选择性从21.18%增大到30.06%. 实验结果将对碳氢燃料等离子体重整制氢的车载应用提供实验依据.     

纳秒脉冲介质阻挡放电等离子体合成氨工艺条件优化

氨(NH₃)作为重要的化工原料对农业及国计民生发展有直接影响。工业合成氨需高温高压、能耗高和污染重。低温等离子体技术是一种可持续,有潜力的合成氨途径,已成为国内外研究热点。本工作以氮气和氢气为原料,在低温常压下采用纳秒脉冲介质阻挡放电等离子体合成氨,通过单因素实验系统研究脉冲峰值电压、脉冲重复频率、气体总流量、N₂和H₂体积比(V(N₂)∶V(H₂))等因素对合成氨速率及能量产率的影响规律。进一步通过正交实验评价确定影响合成氨反应速率因素的主次顺序为:脉冲峰值电压>脉冲重复频率>气体体积比>气体总流量。影响合成氨能量产率因素的主次顺序为:脉冲峰值电压>气体体积比>脉冲重复频率>气体总流量。结合两部分实验,最终得到合成氨的优选条件:脉冲峰值电压16 kV、脉冲重复频率6 kHz、脉冲上升沿100 ns、V(N₂)∶V(H₂)=1∶1、气体总流量200 mL/min。此时NH₃合成...     

The impact of a dielectric barrier discharge on the catalytic oxidation of methane over Ni-containing catalyst

Methane oxidation with air was studied over a Ni-containing catalyst in a dielectric barrier discharge (DBD) at temperatures above 625 K. The DBD increases the methane conversion and shifts the process towards partial oxidation. This effect is related to a catalyst heating by the discharge. This revised version was published online in August 2006 with corrections to the Cover Date.     

介质阻挡放电等离子体法制备优异光催化合成过氧化氢性能的氮空穴掺杂石墨相氮化碳（英文）

过氧化氢(H_2O_2)是一种绿色氧化剂,广泛应用于纺织、印染、造纸和医药等行业.目前,工业上采用蒽醌法制备H_2O_2,它由于需要多步加氢和氧化处理,因此能耗非常大.研究发现,采用贵金属催化剂可以将氢气和氧气直接合成H2O2,但催化剂价格过高,且反应本身存在爆炸风险.近年来,半导体光催化合成H_2O_2受到广泛关注.研究发现,在水存在下,光电子可以将氧气还原得到H_2O_2.介质阻挡放电(DBD)等离子体广泛应用于材料合成、挥发性有机物处理、汽车尾气净化和材料表面处理等.石墨相氮化碳(g-C_3N_4)是新型非金属光催化剂,以其性质稳定、能带适中和制备方便等优点而广受青睐.然而g-C_3N_4的比表面积和电荷分离效率较低,大大限制了其应用.本文采用DBD等离子体法在氢气气氛下制备了N空穴掺杂的石墨相氮化碳,采用XRD,N_2吸附,UV-Vis,SEM,TEM,XPS,EIS,EPR,O_2-TPD及PL等方法对催化剂进行了表征,并考察了N空穴对催化剂结构性质、光学性质及光催化合成H_2O_2性能的影响.结果显示,当DBD等离子体处理时间小于30 min时,所制催化剂颗粒尺寸显著小于焙烧法得到的,因而其比表面积显著提高.N空穴的引入降低了催化剂的能带,提高了可见光区的吸收.此外,N空穴作为反应活性位,既能吸附反应物氧气分子,又能捕获光电子并促进光电子从催化剂向氧气分子转移,进而发生后续还原反应.等离子体处理30 min得到的催化剂光催化合成H_2O_2性能最佳,是纯g-C_3N_4的11倍.本文为g-C_3N_4基催化剂的制备提供了一个新方法.     

Evaluation of a hydride generation-atomic fluorescence system for the determination of arsenic using a dielectric barrier discharge atomizer

A new atomizer based on atmospheric pressure dielectric barrier discharge (DBD) plasma was specially designed for atomic fluorescence spectrometry (AFS) in order to be applied to the measurement of arsenic. The characteristics of the DBD atomizer and the effects of different parameters (power, discharge gas, gas flow rate, and KBH₄ concentration) were discussed in the paper. The DBD atomizer shows the following features: (1) low operation temperature (between 44 and 70 °C, depending on the operation conditions); (2) low power consumption; (3) operation at atmospheric pressure. The detection limit of As(III) using hydride generation (HG) with the proposed DBD-AFS was 0.04 μg L⁻¹. The analytical results obtained by the present method for total arsenic in reference materials, orchard leaves (SRM 1571) and water samples GBW(E) 080390, agree well with the certified values. The present HG-DBD-AFS is more sensitive and reliable for the determination of arsenic. It is a very promising technique allowing for field arsenic analysis based on atomic spectrometry.     

Removal of SO2 and the simultaneous removal of SO2 and NO from simulated flue gas streams using dielectric barrier discharge plasmas

A gas-phase oxidation method using dielectric barrier discharges (DBDs) has been developed to remove SO₂ and to simultaneously remove SO₂ and NO from gas streams that are similar to gas streams generated by the combustion of fossil fuels. SO₂ and NO removal efficiencies are evaluated as a function of applied voltage, temperature, and concentrations of SO₂, NO, H₂O_(g), and NH3. With constant H₂O_(g) concentration, both SO₂ and NO removal efficiencies increase with increasing temperature from 100 to 160°C. At 160°C with 15% by volume H₂0_(g), more than 95% of the NO and 32% of the S0₂ are simultaneously removed from the gas stream. Injection of NH₃ into the gas stream caused an increase in S0₂ removal efficiency to essentially 100%. These results indicate that DBD plasmas have the potential to simultaneously remove SO₂ and NO from gas streams generated by large-scale fossil fuel combustors.     

Determination of bismuth in solid samples by hydride generation atomic fluorescence spectrometry with a dielectric barrier discharge atomizer

An atmospheric pressure dielectric barrier discharge (DBD) atomizer was investigated for bismuth (Bi) determination with hydride generation (HG) atomic fluorescence spectrometry (AFS). The characteristics of the atomizer and the effects of experimental parameters, including observation height, discharge power, flow rate of discharge gas and AFS carrier gas were optimized. The linear range of present method for Bi determination is 0.5-300.0 μg L⁻¹ with a detection limit of 0.07 μg L⁻¹ (3σ). The method was validated by the analysis of reference materials (GBW08517 and GSB-14) and the results agreed well with the reference values. The established method was applied to the determination of Bi in ore, soil and ash samples.     

Contribution of UV light to the decomposition of toluene in dielectric barrier discharge plasma/photocatalysis system

The contribution of UV light from plasma and an external UV lamp to the decomposition of toluene in a dielectric barrier discharge (DBD) plasma/UV system, as well as in a plasma/photocatalysis system was investigated. It was found that UV light from the DBD reactor was very weak. Its contribution to the removal of toluene in the plasma/photocatalysis system could be ignored. Whereas, the introduction of external UV light to the plasma significantly improves the removal efficiency of toluene by 20%. The removal efficiency of toluene in the plasma/photocatalysis system increased about 22% and 16% when compared with a plasma only system and plasma driven photocatalyst system, respectively. The increased toluene removal efficiency was mostly attributed to the contribution of the synergy between plasma and UV light, but not to the synergy between plasma and photocatalysis. The synergetic effect between plasma and photocatalysis was not significant.     

Catalytic effect of iron wires on the syntheses of ammonia and hydrazine in a radio-frequency discharge

The catalytic effect of iron wires on plasma syntheses of ammonia and hydrazine has been studied in the nitrogen-hydrogen plasma prepared using rf discharge at a pressure of 650 Pa (5 Torr). The product was mainly ammonia including a small amount of hydrazine. When iron wires were placed in the plasma downstream of the gas flow, the yields of both products increased, about two times in ammonia and two orders of magnitude in hydrazine. The yields increased with increasing number of wires (the surface area of the catalyst). The dissociative adsorption of nitrogen molecules and/or molecular ions on the iron surface and the formation of NH_x by the reaction with hydrogen in the plasma followed by the formation of NH₃ or N₂H₄ are considered as a reaction scheme. This is supported by the identification of NH₃ with XPS of the surface of iron wires.Partly presented at the 10th International Symposium on Plasma Chemistry, August 4–9, 1991, Bochum, Germany.     

Determination of ethylene glycol dinitrate in dynamites using HPLC: application to the plastic explosive Goma-2 ECO

In this study, a sequential extraction method using water and methanol to recover ethylene glycol dinitrate or nitroglycol (EGDN) contained in Goma-2 ECO dynamite was developed. After, an HPLC method was used for the determination of EGDN in the two extracted phases. The analytical method was validated by evaluating its selectivity, sensitivity, linearity, and linear working concentration range, limit of detection and quantitation, precision (as repeatability and intermediate precision), accuracy, and robustness, providing appropriate values (i.e. RSD values for precision about 6% and accuracy about 100%). Finally, the EGDN content of a sample of the Goma-2-ECO dynamite was determined obtaining a concentration of 30.29%, which is in accordance with the manufacturer's specifications for this dynamite (25.7-31.4%).     

Effects of ethanol on the in situ synthesized Cu/SiO_2 catalyst:Texture,structure,and the catalytic performance in hydrogenation dimethyl oxalate to ethylene glycol

The Cu/SiO₂ catalysts were in situ synthesized by the hydrolysis of tetraethyl orthosilicate（TEOS） in one phase solution using ethanol as co-solvent or TEOS/H₂O two phases solution,followed by the precipitation of copper on SiO₂ by ammonia evaporation. In the hydrogenation of dimethyl oxalate,the catalyst prepared by one phase hydrolysis exhibited higher activity and ethylene glycol（EG） selectivity at lower temperature than that of two phases due to its larger BET surface area and multimodal pore distribution.At 488-503 K,the catalyst prepared in one phase solution with water/ethanol（W/E） volume ratio of 3:1 exhibited 90- 95%EG selectivity,while catalyst prepared by two phase hydrolysis reached 90%EG selectivity only at 498-503 K.     

Methane hydrate phase equilibrium in the presence of salt (NaCl, KCl, or CaCl2) + ethylene glycol or salt (NaCl, KCl, or CaCl2) + methanol aqueous solution: Experimental determination of dissociation condition

In this communication, we report dissociation conditions of methane hydrates in the presence of salt (NaCl, KCl, or CaCl₂) + ethylene glycol or salt (NaCl, KCl, or CaCl₂) + methanol aqueous solutions at different temperatures. The equilibrium data were generated using an isochoric pressure-search method. These data are compared with some selected experimental data from the literature on dissociation conditions of methane hydrates in the presence of pure water to show the inhibition effects of the above mentioned aqueous solutions.