超级电容器碳电极材料制备工艺优化与性能

以碳化后的中间相沥青为前驱体、KOH为活化剂制备了超级电容器用活性炭电极材料,考察了KOH活化温度和碱碳比对所制备的超级电容器用活性炭电极材料的孔隙结构和电化学行为的影响,分析了不同工艺条件下所制备的活性炭电极材料的孔结构和电化学性能的影响因素。结果表明,于800℃活化温度和4∶1碱碳比条件下制备的活性炭电极在1mol/L(C2H5)4NBF4/PC时的最大比电容量可达103.2F/g,活性炭孔结构和比电容量的变化依赖于具体的处理工艺,中孔的含量对活性炭电极的比电容量会产生重要影响。     

煤与KOH共热解制备富氢合成气的研究

以制备富氢合成气为目的,进行了煤与KOH共热解试验。试验在升温速率6％／min,120mL／minN2气氛下进行,采用GC—TCD测定合成气的组成,考察了碱煤比对释氢特性、合成气组成与转化率的影响。结果表明,在不同的碱煤比下,合成气中H2始终占据优势,碱煤比为2：1时,氢气产量与转化效率达到最优。     

烯丙基聚醚合成方法的改进

以烯丙醇和固体KOH为原料制得烯丙醇钾,再在常压下与环氧乙烷反应制得高纯度的烯丙基聚醚,讨论了反应时间、反应温度、原料配比、投料方式等因素对反应的影响。当KOH与烯丙基的摩尔比为1：1.25时,加热回流下可以得到高收率的烯丙醇钾,开环反应依据所需的聚醚分子量调节环氧乙烷的用量,产品收率达到98%以上。     

Catalytic effect of KOH on the reaction of NO with char

Experimental results are presented on the reduction of NO by char particles prepared from a Chinese low-volatile coal. The experiment was conducted in a drop-tube furnace at 1173 to 1323 K. Kinetic parameters of the global reaction of NO with char were determined, and the effects on these kinetic parameters of adding the catalyst KOH to the char particles and also of [O₂] in the flue gas were studied. The results show that KOH can increase the frequency factor and reduce the activation energy of the reduction of NO by char. However, the benefit of increasing the KOH content in char particles decreases when there is more than 1.0 wt % of the catalyst in the char. The activation energy of the global NO-char reaction is shown to be independent of [O₂], but the frequency factor strongly depends on the equivalence ratio under oxygen-lean conditions.     

Brown coloring electrochromic devices based on NiO–TiO2 layers

Brown coloring electrochromic 5×10 cm² windows with the configuration K-glass/NiO–TiO₂/electrolyte/CeO₂–TiO₂/K-glass have been prepared and characterized by optoelectrochemical techniques (cyclic voltammetry, chronoamperometry and galvanostatic measurements). The electrochromic layers have been prepared by the sol–gel technique. As electrolyte either a 1 M aqueous KOH solution or a newly developed starch-based gel impregnated with KOH have been used. The CeO₂–TiO₂ sol–gel layers sintered at 550 °C have been previously characterized in 1 M aqueous KOH electrolyte as a function of the thickness up to 2000 cycles and showed a highly reversible behavior without any corrosion effect. The NiO–TiO₂ sol–gel layers sintered at 300 °C have been extensively characterized in the same electrolyte up to about 7000 cycles. All windows present a deep brown color characteristic of the presence of Ni³⁺ (NiOOH) species, that is fully reversible for several thousands of cycles with a rather-fast kinetics (<30 s). The transmittance of the bleached state however slowly decreases with cycling (permanent coloration). The full-bleached condition can be nevertheless recovered by applying a negative potential for a long duration. Deeper coloration is usually obtained by cycling the windows galvanostatically with a current density of 20 μA/cm². The lifetime of the windows is however limited because of the degradation of the NiO-based layers due to the not fully reversible exchange of OH⁻ that turns the layers mechanically fragile and leads eventually to their complete removal from the substrate. Windows working satisfactorily up to 7000 and 17 000 cycles have been obtained using aqueous KOH electrolyte and starch KOH gel electrolyte, respectively. Memory tests showed that the devices bleach at the open circuit potential from T=39% (colored state) to about T=50% in 60 min.     

Characterization of 4H semi-insulating silicon carbide single crystals using electron beam induced current

In this work we demonstrate the electron beam induced current (EBIC) contrast of dislocations in semi-insulating (SI) bulk SiC single crystals. Our investigations revealed that the screw dislocations produce dark EBIC contrast indicating high leakage current in the defective regions. This type of screw dislocations are harmful for high resolution radiation detectors and should be eliminated by improving the crystal qualities. Chemical etching in molten KOH was used for dislocation mapping in the test structures and to correlate EBIC contrast with dislocations. The EBIC contrast found in our study in SI SiC is discussed.     

KOH活化法制备椰壳活性炭研究

以椰壳炭化料为原料,采用KOH活化法制备活性炭,研究了KOH/炭化料的质量比、升温速率、活化温度和活化时间对活性性能的影响。实验结果表明,KOH/炭化料的质量比是该方法制备活性炭的最主要影响因素,较优的工艺参数为:KOH/炭化料的质量比为4∶1、升温速率为5℃/min、活化温度为800℃、活化时间为1 h。同时制备得到了比表面积达到2413 m2/g、微孔容积达到1.02 cm3/g,且以0.9 nm以下微孔为主的椰壳活性炭。     

Stability of 3CaO · Al2O3 · 6H2O in KOH + K2CO3 + H2O system for chromate production

In the novel clean chromate production process, the alkali liquor recycled to decompose the chromite ore mainly consists of KOH and K₂CO₃ which accumulates aluminium impurity and affects the quality of the product greatly. Aluminium impurity can be removed by adding CaO to precipitate as 3CaO · Al₂O₃ · 6H₂O (C₃AH₆). A study of the effects of various parameters, such as KOH concentration, K₂CO₃ concentration and temperature on the behaviour of C₃AH₆ show that C₃AH₆ is decomposed to 3CaO · Al₂O₃ · CaCO₃ · 11H₂O and CaCO₃ below 150 g L^− 1 KOH, and decomposed to Ca(OH)₂ above 150 g L^− 1 KOH. With K₂CO₃ concentration increasing, C₃AH₆ decomposes significantly, which results in more CaCO₃ or 3CaO · Al₂O₃ · CaCO₃ · 11H₂O produced. Temperature has a large positive effect on the decomposition of C₃AH₆ at 45 g L^− 1 KOH but has no significant effect at 150 g L^− 1 KOH. The optimal condition for removing aluminium impurity in the KOH + K₂CO₃ + H₂O system is 150 g L^− 1 KOH, 50 g L^− 1 K₂CO₃ and 80 °C.     

Parametric study of biodiesel production from used soybean oil

Biodiesel, an alternative diesel fuel derived from vegetable oil, animal fat, or waste vegetable oil (WVO), is obtained by reacting the oil or fat with an alcohol (transesterification) in the presence of a basic catalyst to produce the corresponding mono‐alkyl esters. In this work, the effect of the catalyst KOH‐to‐WVO ratio, ethanol concentration, and time of reaction on the biodiesel yield were investigated. The transesterification reaction was performed at a constant temperature (35 °C) in order to minimize the cost of heating and ethanol evaporation. A 2³ complete factorial design on biodiesel yield (Y) was performed using low and high levels of operating variables: KOH concentration (9–14 g/L), ethanol concentration (30–40 vol‐%) and time (30–40 min). The complete factorial model that can be used to fit the data was determined. The model shows that interactions exist among the parameters and that the parameters, or factors, do not operate independently on the response (biodiesel yield). The highest yield was obtained in the first 30 min of reaction time. The results indicate that the highest yield was 78.5 vol‐% using a KOH‐to‐WVO ratio of 12 g/L and 30 vol‐% ethanol. The ASTM tests indicate that the biodiesel properties are within the biodiesel standard limits.     

一维碳纳米结构的有效合成及其在锂离子电池负极材料中的应用(英文)

采用热解处理已合成的聚吡咯纳米线实现一维碳纳米纤维的有效合成。在KOH的活化作用下,原始的纤维结构发生变化,获得带状碳纳米结构。对所合成的碳纳米线及碳纳米带进行形貌及结构表征。测试这两种一维碳纳米材料应于于锂离子电池中负极材料的电化学性能。结果表明,一维碳纳米线及一维碳纳米带均表现出较优的循环性能及良好的倍率性能。碳纳米线材料在循环50次后仍保持530 mA·h/g的可逆容量。在前23次充放电循环中,碳纳米带的可逆容量均高于850 mA·h/g,充放电循环到第23次的容量保持率为86%。