微波辅助MgO/SBA-15预处理对玉米秸秆厌氧消化的影响

为探索微波辅助MgO/SBA-15预处理玉米秸秆对其厌氧消化产气的影响,采用Mg O/SBA-15对玉米秸秆进行预处理,并在中温条件下进行厌氧消化产气试验。试验结果表明：微波辅助Mg O/SBA-15预处理玉米秸秆能有效破坏其原始构态,提高纤维素回收率和底物的可生物降解性,为厌氧发酵产沼气奠定良好的基础。在MgO/SBA-15与干基质的质量比分别为0%、10%、20%的条件下,预处理后的玉米秸秆厌氧消化产气能力较未预处理组有较大提高,厌氧消化启动时间有所提前。与对照组相比,经10%和20%MgO/SBA-15预处理的玉米秸秆单位挥发性固体（volatile solid,VS）产气量分别可提高55.28%和41.00%;90%最大产气量厌氧消化时间分别缩短1d和0 d;VS减少率分别提高7.3%和4.1%。综合考察预处理效果、日产气量、累积产气量和厌氧消化启动时间,相比于质量比20%的MgO/SBA-15组,质量比为10%的MgO/SBA-15预处理效果更好。

乙醇制1,3-丁二烯MgO/SBA-15催化剂的制备及其催化性能

以介孔分子筛SBA-15为载体,采用浸渍法制备了新型负载型MgO/SBA-15催化剂,采用低温N_2吸附-脱附、X射线衍射(XRD)、透射电子显微镜(TEM)、^(29)Si核磁共振(^(29)Si NMR)、NH_3程序升温脱附(NH3-TPD)、CO_2程序升温脱附(CO_2-TPD)等表征手段研究了不同MgO负载量(质量分数)对催化剂的结构、物化性能和催化乙醇合成丁二烯反应活性的影响。研究结果表明,MgO负载量为20%时,所制备的催化剂的活性最好,此时MgO高度分散在载体SBA-15的有序孔道中,形成了Mg-O-Si结构,有利于提高目标产物丁二烯的选择性。该催化剂在温度350℃、进料质量空速2. 64 h^(-1)的反应条件下,可获得最佳催化效果,乙醇转化率最高可达55. 8%,丁二烯选择性可达80. 2%。Mg O/SBA-15催化剂在乙醇法生产丁二烯工艺中具有潜在的应用前景。

MgO/SBA-15固体碱介孔材料的研制

结合浸渍和微波辐射技术,分别采用浸渍、浸渍-微波、微波辐射等方法将醋酸镁高分散在SBA-15上而成为MgO改性介孔固体碱材料。结果显示:使用不同负载方法以及含铝SBA-15为载体,均能使MgO均匀分散;负载量达到20%时,XRD法仍未检测到样品上有MgO的晶相。实验表明负载的MgO在载体上形成了多层重叠结构,产生较多的中强碱位,而在介孔分子筛中引入Al原子则有利于碱位的形成。

掺杂镧的固体碱MgO/SBA-15催化大豆油制备生物柴油

采用浸渍法制备了掺杂镧的固体碱MgO/SBA-15催化剂,将其用于大豆油酯交换制备生物柴油的反应。XRD表征结果显示,活性组分在载体SiO2骨架中高度分散。考察了不同镧镁物质的量比、焙烧温度和催化剂用量等因素对催化剂性能的影响,发现镧的引入有利于催化剂与反应物的接触,从而提高催化剂的活性;镧和镁物质的量之比为0.5∶1,催化剂焙烧温度700℃,焙烧时间3h,催化剂质量分数为3%,反应时间3h时,生物柴油的产率达到95%以上。

MgO／SBA-15对芥子气模拟剂2-氯乙基乙基硫醚的吸附与降解

研制高效和环境友好的吸附反应型消毒材料在防化领域有着迫切的需求。笔者采用固相微波法，将不同含量的MgO成功地负载到介孔分子筛SBA-15上。负载型材料MgO／SBA-15在室温条件下可将芥子气模拟剂2-氯乙基乙基硫醚（2-CEES）降解，其中MgO负载量为5％时降解效果最好（经过15h，2-CEES的转化率可以达到90％以上）。此外，MgO／SBA-15对气态2-CEES还具有良好的吸附性能。通过in—situFT-IR和GC-MS分析表明，2-CEES最终被降解为CH3CH2SCH2CH2OH、CH2-CHSCH2CH3、CH3CH2SCH2CH2SCH2CH3等无毒产物。

SBA-15负载MgO催化大豆油与甲醇酯交换反应制备生物柴油的研究

以介孔分子筛SBA-15为载体,采用原位法合成了MgO负载的SBA-15碱性催化剂.以大豆油为原料,加入甲醇,在醇油质量比为9∶1,催化剂用量为油质量的3%,反应温度65℃,反应时间3 h的条件下,检测了所制备的催化剂在催化酯交换反应中的活性.研究结果表明,原位法合成的30%负载量的MgO-SBA-15具有较高的催化活性,其生物柴油产率达78%.

Mo/Zr-SBA-15介孔分子筛吸附溶液中亚甲基蓝

采用一步水热晶化法将Zr掺杂到SBA-15骨架中制备了Zr-SBA-15,以Zr-SBA-15为载体,Mo为活性组分,制备了Mo/Zr-SBA-15吸附剂,对其进行了表征,并将Mo/Zr-SBA-15用于吸附溶液中的亚甲基蓝(MB),考察了Mo、Zr掺杂的SBA-15对MB的吸附性能。表征结果显示:Mo/Zr-SBA-15具有介孔结构,Zr进入SBA-15分子筛的骨架中,Mo部分负载至SBA-15的孔壁上,部分以MoO_(3)的形式均匀分散在SBA-15表面;随着Mo负载量的增加,Mo/Zr-SBA-15的比表面积与孔体积逐渐减小。实验结果表明:当Mo负载量(w)为10%时,对溶液中MB的吸附性能最佳;在MB质量浓度20 mg/L、Mo/Zr-SBA-15加入量0.2 g/L、初始溶液pH 5.9、温度25℃、吸附时间4 h的条件下,对MB的平衡吸附量达到90.3 mg/g;Freundlich模型能够更好地描述Mo/Zr-SBA-15对MB的吸附等温过程;25℃时,Mo/Zr-SBA-15对MB的饱和吸附量为173.3 mg/g;Mo/Zr-SBA-15经焙烧再生、循环使用4次后,平衡吸附量仅下降了7.6%,表现出良好的可再生性能。

SBA-15分子筛负载对甲苯磺酸催化合成过氧化二异丙苯的性能和反应过程模拟

采用浸渍法制备了SBA-15分子筛负载对甲苯磺酸(TsOH)催化剂TsOH/SBA-15,探究了其催化α-甲基苯乙烯(α-MS)和异丙苯过氧化氢(CHP)反应制备过氧化二异丙苯(DCP)的活性,并对反应过程进行了模拟分析.当进料比n(α-甲基苯乙烯)/n(异丙苯过氧化氢)=2.0, TsOH/SBA-15用量为CHP质量的0.15%,于44℃反应2.5h, DCP的产率为62.1%.模拟计算结果表明,反应过程有异步协同反应和分步反应两种机理,在异步协同反应中α-MS, CHP和TsOH只需要经过一个过渡态即可完成,而分步反应中反应物需要经过两个过渡态以及一个中间体才能完成,两种路径均涉及2次H^(+)的转移.在44℃下,异步协同反应的反应能垒(ΔG)为121.8 kJ/mol,分步反应中两个过渡态对应的反应能垒分别为74.1和78.3 kJ/mol.

核壳质量比对β@SBA-15复合分子筛加氢裂化性能的影响

制备一系列不同核壳质量比(以下简称核壳比)的β@SBA-15复合分子筛,并对复合分子筛壳层材料进行酸性位的构建,以构建酸性位后的β@AlSBA-15复合分子筛为主要裂化组分制备催化剂,考察复合分子筛核壳比对催化剂加氢裂化性能的影响,并在200 mL固定床反应装置上对催化剂进行性能评价。结果表明:β@SBA-15复合分子筛的最佳核壳比为6∶4,高核壳比合成的复合分子筛核壳结构不完整,低核壳比会导致合成的复合分子筛分相严重。以中东减压蜡油为原料,在相近转化率条件下,当核壳比为6∶4时,催化剂的加氢裂化性能最优,中间馏分油选择性最高(84.9%),航空煤油馏分冰点和柴油馏分凝点最低,分别为-61,-5℃。

甲基硅烷化改性显著促进乙烯在Pt/SBA-15上的低温催化氧化

以介孔分子筛SBA-15为载体,采用浸渍法制备Pt基催化剂,通过三甲基氯硅烷(TMCS)对催化剂进行表面改性以提高其疏水性.表征结果表明甲基硅烷化显著促进了催化剂的表面疏水性.乙烯的低温催化氧化结果显示,随着TMCS接枝量的增加,催化剂的反应活性呈现火山型变化规律.Pt/SBA-15-TMCS(1:6)的催化活性最高,能够保持约1 h对痕量乙烯100%的催化氧化效果,3 h后仍有29%的乙烯转化率,相比于Pt/SBA-15有显著提升.适量TMCS的改性带来的催化剂疏水性的改善能够有效抑制反应过程中水分子吸附对催化剂的不利影响,而过量TMCS的修饰则易团聚形成大颗粒堵塞介孔孔道,减少乙烯分子与活性位点的接触,降低催化效果.

SBA-15/纤维素复合隔膜的制备及对锂离子电池性能的影响

以高纯度的纤维素为原料,利用纤维素膜对电解质良好的润湿性,共混引入SBA-15纳米粒子,制备了SBA-15/纤维素复合隔膜,通过场发射扫描电子显微镜对其形貌进行了表征,并研究了其热收缩性能、润湿性能及电化学性能。结果表明,SBA-15纳米粒子的加入不仅有助于提高隔膜的热稳定性,而且可以促进液体电解质的吸收,从而允许均匀分配锂离子通量;与聚丙烯(PP)隔膜电池相比,SBA-15/纤维素复合隔膜电池在0.5 C下循环100次后仍能保持143.6 mAh·g^(-1)的放电比容量。该研究为制备高安全的锂离子电池提供了借鉴。

Pd/SBA-15-NH_(2)制备及其催化甲酸分解制氢

制备了介孔分子筛SBA-15,对其进行氨基功能化得到SBA-15-NH_(2)载体,采用液相还原法制备了负载超细Pd纳米催化剂,利用X射线衍射仪(XRD)和透射电镜(TEM)对催化剂的结构和形貌进行了分析,并将制备的催化剂用于甲酸脱氢反应。结果表明,氨基的引入使得Pd纳米颗粒在载体上均匀分布,平均粒径仅为2.43 nm。在反应温度为313 K、甲酸/甲酸钠物质的量比为5∶3、甲酸浓度为5 mol·L^(-1)的条件下,甲酸脱氢反应的表观TOF值可达5610 h^(-1),氢气选择性接近100%。

Effect of MgO promoter on Ni-based SBA-15 catalysts for combined steam and carbon dioxide reforming of methane

A series of Ni/SBA-15 catalysts with Ni contents ranging from 5 wt% to 15 wt%, as well as another series of 10%Ni/MgO/SBA-15 catalysts, in which the range of the MgO content was from 1 wt% to 7 wt%, were prepared, and their catalytic performances for the reaction of combined steam and carbon dioxide reforming of methane were investigated in a continuous flow microreactor. The structures of the catalysts were characterized using the XRD, H2-TPR and CO2-TPD techniques. The results indicated that the CO selectivity for this reaction was very close to 100%, and the H2/CO ratio of the product gas could be controlled by changing the H2O/CO2 molar ratio of the feed gas. The simultaneous and plentiful existing of steam and CO2 had a significant influence on the catalytic performance of the 10%Ni/SBA-15 catalyst without modification. After reacting at 850 °C for 120 h over this catalyst, the CH4 conversion dropped from 98% to 85%, and the CO2 conversion decreased from 86% to 53%. However, the 10%Ni/3%MgO/SBA-15 catalyst exhibited a much better catalytic performance, and after reacting for 620 h, the CO2 conversion over this catalyst dropped from 92% to around 77%, while the CH4 conversion was not decreased. Oxidation of the Ni0 species as well as carbon deposition during the reaction were the main reasons for the deactivation of the catalyst without modification. On the other hand, modification by the MgO promoter improved the dispersion of the Ni0 species, and enhanced the CO2 adsorption affinity which in turn depressed the occurring of carbon deposition, and thus retarded the deactivation process.

MgO–SBA-15 Supported Pd–Pb Catalysts for Oxidative Esterification of Methacrolein with Methanol to Methyl Methacrylate

Novel Mg O–SBA-15 supported catalysts were prepared for oxidative esterification of methacrolein(MAL) with methanol to methyl methacrylate(MMA). The Mg O–SBA-15 supports were synthesized with different magnesia loadings from different magnesium precursors and hydrochloric acid molar concentrations. The Mg O–SBA-15 supports and Pd–Pb/Mg O–SBA-15 catalysts were characterized by several analysis methods. The results revealed that the addition of Mg O improved the ordered structure of SBA-15 supports and provided surface alkalinity of SBA-15 supports. The average size of the Pd3 Pb particles on magnesia-modified Pd–Pb/Mg O–SBA-15 catalysts was smaller than that on the pure silica-based Pd–Pb/SBA-15 catalysts. The experiments on catalyst performance showed that the magnesia-modified Pd–Pb/Mg O–SBA-15 catalysts had higher activity than pure silica-based Pd–Pb/SBA-15 catalysts, showing the strong dependence of catalytic activity on the average size of active particles. The difference of activity between Pd–Pb/SBA-15 catalysts and Pd–Pb/Mg O–SBA-15 catalysts was due to the discrepant structural properties and surface alkalinity provided by Mg O, which led to the different Pd3 Pb particle sizes and then resulted in the different number of active sites. Besides magnesia loadings, other factors, such as hydrochloric acid molar concentration and magnesium precursors, had considerable influences on the catalytic activity.

Ag/SBA-15材料的制备及其CO催化氧化性能研究

采用2种不同方法将金属Ag浸渍在SBA-15上制备Ag/SBA-15复合材料,通过SEM、UV-Vis、XRD对Ag/SBA-15复合材料进行表征,并对Ag/SBA-15进行CO气体催化氧化实验,评价Ag/SBA-15复合材料的催化性能。结果表明,去除模板剂后浸渍合成的Ag/SBA-15的催化性能较好,其中金属负载量为1%的产品催化性能最好,催化所需的温度最低,CO转化率最高。

SBA-15负载磷钼钒酸构筑高效室温光热氧化脱硫催化剂

采用等体积浸渍法在介孔SBA-15负载SBA-15的质量分数X%(X=10,20,30,40,50)Keggin型杂多酸H_(4)PMo_(11)VO_(40)(PMoV),制备系列催化剂X%PMoV,用于室温条件下可见光光热氧化脱硫。通过比表面积分析(BET)、傅里叶变换红外光谱仪(FT-IR)、X射线衍射仪(XRD)、透射电子显微镜(TEM)、X射线电子能谱分析仪(XPS)和紫外可见分光光度计(UV-Vis)对催化剂进行了表征。催化剂在乙腈溶剂中的表现出了光热转换能力,且光热转化效果随活性组分负载量增加而变强。以H2O2为氧化剂,二苯并噻吩(DBT)为例的模型油中,对催化剂光热氧化脱除硫进行了研究。研究表明,催化剂对DBT具有光催化和光驱动热催化的协同氧化脱硫能力。得益于活性组分PMoV在载体SBA-15孔道内的有效负载,当负载量为30%时,催化剂具有较好的循环稳定性和底物氧化产物选择性。催化剂的光热催化脱硫策略也适用于其它噻吩类衍生物以及硫醚类化合物。此研究为利用可见光吸收活性组分负载于分子筛,用于光驱动光催化和热催化脱硫应用提供了一种新的思路。

Efficient activation of the Co/SBA-15catalyst by high-frequency AC-DBD plasma thermal effects for toluene removal

Dielectric barrier discharge(DBD)plasma excited by a high-frequency alternating-current(AC)power supply is widely employed for the degradation of volatile organic compounds(VOCs).However,the thermal effect generated during the discharge process leads to energy waste and low energy utilization efficiency.In this work,an innovative DBD thermally-conducted catalysis(DBD-TCC)system,integrating high-frequency AC-DBD plasma and its generated thermal effects to activate the Co/SBA-15 catalyst,was employed for toluene removal.Specifically,Co/SBA-15 catalysts are closely positioned to the ground electrode of the plasma zone and can be heated and activated by the thermal effect when the voltage exceeds 10 k V.At12.4 k V,the temperature in the catalyst zone reached 261℃ in the DBD-TCC system,resulting in an increase in toluene degradation efficiency of 17%,CO_(2)selectivity of 21.2%,and energy efficiency of 27%,respectively,compared to the DBD system alone.In contrast,the DBD thermally-unconducted catalysis(DBD-TUC)system fails to enhance toluene degradation due to insufficient heat absorption and catalytic activation,highlighting the crucial role of AC-DBD generated heat in the activation of the catalyst.Furthermore,the degradation pathway and mechanism of toluene in the DBD-TCC system were hypothesized.This work is expected to provide an energy-efficient approach for high-frequency AC-DBD plasma removal of VOCs.

Fe-Al_(2)O_(3)/SBA-15催化臭氧氧化水中布洛芬

以嵌段共聚物为模板剂,在酸性条件下水热合成SBA-15.将铁、铝负载于SBA-15表面制备Fe-Al_(2)O_(3)/SBA-15介孔分子筛催化剂,并将其用于催化臭氧氧化水中布洛芬(IBU).透射电子显微镜、X射线衍射、氮气吸附-脱附表征结果表明,铁、铝均匀负载于SBA-15表面,保持SBA-15有序的介孔结构,具有较大的比表面积.不同催化剂活性评价结果表明,铁、铝的负载显著提高SBA-15催化臭氧氧化水中布洛芬的活性,反应60 min后,Fe-Al_(2)O_(3)/SBA-15的TOC去除率为90%,而Al_(2)O_(3)/SBA-15、Fe/SBA-15和SBA-15的TOC去除率分别为65%、50%和36%,单独臭氧氧化仅为26%.实验结果表明,铁、铝的协同作用有利于臭氧分解为羟基自由基、超氧自由基和活性原子氧,布洛芬和小分子有机酸吸附于催化剂表面从而有利于有机物的矿化.催化剂重复利用6次后仍保持较高的催化活性和稳定性.

MgO-CaO/SBA-15催化大豆油酯交换制备生物柴油

以SBA-15为载体,通过浸渍法制备了MgO-CaO/SBA-15固体碱催化剂。优化的的催化剂制备条件是:镁钙物质的量比为0.4,焙烧时间为2 h,焙烧温度为700℃。在应温度为65℃,醇油物质的量比为12∶1,催化剂用量为大豆油质量的3%,可得生物柴油产率为85.5%。

表面含磺酸基的介孔分子筛催化剂SBA-15-SO_3H的制备及其催化性能

采用直接和后合成两种方法制备出含磺酸基的介孔分子筛 SBA-1 5 -SO3 H,用 XRD和红外光谱分析制备过程中催化剂结构和组成的变化 .结果表明 ,两种方法制备出的含磺酸基的催化剂都保持了 SBA-1 5分子筛的完整晶体结构 ,并含有质子酸中心— SO3 H;固体核磁共振表征结果证明 ,两种方法都使 MPTMS存在于分子筛的表面 ;用 N2 吸附 -脱附测定了它们的比表面积、孔径和孔容 ;TGA分析认为 ,MPTMS在分子筛表面的热稳定性大于 30 0℃ ,酸碱滴定结果说明 ,直接法获得的催化剂的酸中心多于后合成法 .酯化反应结果表明 ,直接法合成的催化剂比后合成法具有更高的稳定性 ,且简便、快捷、高效 .