WO3-TiO2/SiO2的制备、表征及光催化甲烷和水的反应性能

以表面改性法制备出TiO2／SiO2，进而以浸渍法制备出负载型复合半导体材料WO3-TiO2／SiO3，利用XRD、BET、TPR、UVDRS、IR和TPD等技术对材料的表面性质与构造、光响应性能和化学吸附性能进行了表征，并研究了该材料光催化甲烷和水合成甲醇和氢的反应性能．结果表明：载体有效分散表面物种并使其能隙增大；WO3与TiO2复合所形成的组合活性基元可调变吸光带边并促进对甲烷和水的化学吸附；在100℃以上，光激发WO3-TiO2／SiO2表面产生的光生空穴，促使分子吸附态的甲烷解离并向甲醇转化，形成一定的“光-表面-热”协同作用促使反应顺利进行，对甲醇的选择性达到83％以上．     

温和条件下催化甲烷氧化制甲醇研究进展

甲烷是燃料或化工生产中最丰富的碳基能源之一,将甲烷转化为液体或固体化学原料将成为全球能源供应的转折点.目前,许多催化此类反应的工作已有大量研究和报道.在这些反应中,甲烷选择性氧化制甲醇被认为是天然气就地价值化的一条有前途的途径.这使得甲烷低温选择性氧化制甲醇技术的发展变得非常迫切,本文综述了CH₄的活化和催化转化,指出了针对特定反应的催化剂的发展趋势.讨论了理想条件下甲烷氧化制取甲烷的反应研究以及Au–Pd合金类、ZSM-5类、MOFs类、单原子类等催化剂对甲烷氧化过程的影响及其催化转化机理.最后,对温和条件下催化甲烷氧化制甲醇催化剂未来发展提出了展望和挑战.     

光促甲烷和水合成甲醇和氢催化剂的研究

用表面改性法制备TiO2/SiO2，以等体积浸渍法制备负载型复合半导体催化剂(MoO3,ZnO)-TiO2/SiO2，通过XRD、BET、TPR、IR、UV-Vis DRS和TPD等技术对材料的表面形态结构、吸光特性、化学吸附性能及光催化甲烷和水的反应性能进行了表征和分析。结果表明，MoO3-TiO2/SiO2和ZnO-TiO2/SiO2的表面物种均具有显著的量子尺寸效应，在表面分别形成Mo—O—Ti和Zn—O—Ti复合结构；MoO3和TiO2在载体表面的复合可提高对光能的利用率并可增强对甲烷的化学吸附性能， 结果使得MoO3-TiO2/SiO2的光催化反应性能明显优于ZnO-TiO2/SiO2；在固定床环隙反应器中，150℃MoO3-TiO2/SiO2光催化气相甲烷和水合成了目的产物甲醇和氢，甲醇的选择性达到87.3％。     

天然气和二氧化碳转化制合成气的研究 Ⅴ．甲烷脱氢积炭反应特征

采用ＴＧ、ＸＲＤ、ＳＥＭ、ＥＤＡＸ和脉冲色谱技术，研究了Ｎｉ／Ａｌ２Ｏ３和Ｎｉ／ＡＲＭ催化剂的甲烷脱氢积炭反应特征。结果指出，甲烷脱氢反应的积炭行为与催化剂上镍的分散状态有关。Ｎｉ－２催化剂上Ｎｉ的分散度小，晶粒大，甲烷脱氢形成的炭丝较长，主要以石墨型炭游离存在：而Ｎｉ／ＡＲＭ催化剂上Ｎｉ的分散度大，镍晶粒小，甲烷脱氢形成的炭丝较短，主要覆盖在催化剂活性中心表面。甲烷脱氢主要产生无定型炭和石墨型炭，其中无定型炭可以被ＣＯ２部分消除。在催化剂制备时，通过提高镍在催化剂表面的分散度，减小镍的晶粒大小，不仅可以提高催化剂的活性，而且可以提高ＣＯ２对积炭的消炭性能。     

可逆与不可逆吸附CO在合成甲醇反应中的作用

合成甲醇反应是CO+H_2反应系列中较简单的反应之一,它与同系列的甲烷化反应有着不同的反应条件.从热力学观点来看,甲烷化反应和合成甲醇反应同是体积缩小反应,加压应该有利于两反应的进行,实际上合成甲醇反应需加压,而甲烷化反应却不一定需要加压.最近我们用动态分析技术对烃的临氢转化、乙炔加氢和苯加氢反应研究发现,在实际反应条件下,反应物在催化剂表面上的吸附可分为可逆与不可逆吸附两类,它们在多相催化反应中对活性、选择性和稳定性均有影响,但是它们对操作压力的依赖程度是不一样的.因此研究     

甲基弯菌IMV 3011整细胞催化甲烷氧化合成甲醇的研究

研究了在甲基弯菌（Methylosimus trichosporium)IMV 3011整细胞催化甲烷制甲醇的反应过程中，菌体浓度、阻断剂乙二胺四乙酸（ethylenediamine tetraacetic acid,简称EDTA）浓度、外源性电子给体、混合气组分及压力与甲醇积累的关系。批式反应的实验结果表明，在菌体浓度为7.4mg/mL时，以2mmol/L EDTA作阻断剂效果最好；作为电子给体，甲酸钠（20mmol/L)的效果优于琥珀酸钠（40mmol/L)，使用前者时的甲醇积累量是用后者时的2.8倍左右；当甲烷与空气的体积比为1：1.7时，转化率为6.0%，甲醇积累量最大；压力选用0.16MPa。连续反应中，于培养基中无铜离子培养的细胞与有铜离子的相比，持续时间长，甲醇积累高（最大产量达374μmol),前者是后者的2倍。     

CH4—H2O—CO2转化制取合成甲醇原料气的研究

在变温床中考查了负载型镍催化剂用于ＣＨ４－Ｈ２Ｏ－ＣＯ２转化制取合成气的活性与稳定性，该过程所制得的合成气勿需分离即可直接用于合成甲醇。本文对催化剂活性下降的原因用比表面、孔结构、ＸＲＤ和ＸＰＳ对不同反应时间的催化剂进行了对比分析，发现镍催化剂活性降低的原因是催化剂表面镍的大量流失。     

Mo／La－Co－O催化剂上甲烷选择氧化制甲醇反应

 制备了一系列Mo／La－Co－O催化剂，考察了催化剂对甲烷选择氧化制甲醇反应的催化性能，并用BET，XRD，LRS，H2－TPR和XPS等技术研究了催化剂的结构和性质．结果表明，在n（CH4）∶n（O2）∶n（N2）＝10∶1∶1，SV＝14．4L／（g·h），p＝4．2MPa和θ＝420℃的反应条件下，7％Mo／La－Co－O催化剂表现出较好的催化性能，甲醇选择性为60％，甲醇收率为6．7％．Mo负载于La－Co－O上以后，Mo－O物种以无定形的状态存在于La－Co－O表面，并与La－Co－O发生相互作用．Mo的负载量影响Mo－O物种的结构及催化剂的性质．催化剂的还原性和表面O－／O2－比影响催化剂上甲烷选择氧化制甲醇反应的性能．     

CH_4-H_2O-CO_2转化制取合成甲醇原料气的研究Ⅲ.镍催化剂活性降低原因的探讨

在变温床中考查了负载型镍催化剂用于ＣＨ４Ｈ２ＯＣＯ２转化制取合成气的活性与稳定性，该过程所制得的合成气勿需分离即可直接用于合成甲醇。本文对催化剂活性下降的原因用比表面、孔结构、ＸＲＤ和ＸＰＳ对不同反应时间的催化剂进行了对比分析，发现镍催化剂活性降低的原因是催化剂表面镍的大量流失。     

激光参数对甲醇激光表面反应性能的影响规律

以Ｓｉｏ２和ＰＭｏ１２为表面材料，用可选频脉冲ＴＥＡ－ＣＯ２激光器作光源，考察了激发频率、激光强度、脉冲次数和脉冲间隔等激光参数对甲醇激光分解反应性能的影响规律。结果表明：甲醇的激光表面反应具有频率选择性，激发频率不同，甲醇分解率也不同；不同表面上激发次数影响规律不同，随着激发次数增加，甲醇转化率增加；脉冲间隔的改变只影响转化率，脉冲间隔越小，能量利用率越高，甲醇分解率越高；激光强度的提高可增加甲     

Antifreezes Act as Catalysts for Methane Hydrate Formation from Ice

Contrary to the thermodynamic inhibiting effect of methanol on methane hydrate formation from aqueous phases, hydrate forms quickly at high yield by exposing frozen water–methanol mixtures with methanol concentrations ranging from 0.6–10 wt % to methane gas at pressures from 125 bars at 253 K. Formation rates are some two orders of magnitude greater than those obtained for samples without methanol and conversion of ice is essentially complete. Ammonia has a similar catalytic effect when used in concentrations of 0.3–2.7 wt %. The structure I methane hydrate formed in this manner was characterized by powder X‐ray diffraction and Raman spectroscopy. Steps in the possible mechanism of action of methanol were studied with molecular dynamics simulations of the Ih (0001) basal plane exposed to methanol and methane gas. Simulations show that methanol from a surface aqueous layer slowly migrates into the ice lattice. Methane gas is preferentially adsorbed into the aqueous methanol surface layer. Possible consequences of the catalytic methane hydrate formation on hydrate plug formation in gas pipelines, on large scale energy‐efficient gas hydrate formation, and in planetary science are discussed.     

Study of Methanol Conversion over Fe-Zn-Zr Catalyst

The methanol conversion over Fe-Zn-Zr catalyst was studied at 0.1 MPa and 280-360℃. The experimental results indicate that the main products of methanol conversion are methane and butane, and that other hydrocarbons are scarcely produced.All results show that propylene is most probably the olefin formed first in methanol conversion rather than ethene over Fe-Zn-Zr catalyst.Methane is formed from methoxy group,and C_4 is possibly yielded on the surface from propylene through binding with a methoxy group.     

室温光驱动甲烷活化

如何在较温和的条件下将甲烷转化为其它更有价值的有机衍生物,如醇、芳烃、长链烷烃和烯烃等,长期以来是催化、化学及化工领域的热点课题和难点课题之一。为了提高甲烷的转化效率,过去几十年里,研究人员不断开发新的催化剂和新的反应路径。与传统高温热催化方法相比,如果能利用自然界中丰富的太阳能驱动甲烷转化,将同时满足能源和环保两方面的要求,是各种新型非常规策略中比较令人期待的一种。本文从光催化材料的组成、结构及催化路线、催化机制等方面进行总结,对当前室温光活化甲烷分子的研究现状加以论述。     

含钒杂多酸催化发烟硫酸中甲烷液相部分氧化反应

 以H5PV2Mo10O40 为催化剂,在发烟硫酸中进行了甲烷液相部分氧化,考察了催化剂用量、反应温度、反应时间和发烟硫酸浓度等工艺条件对反应收率的影响. 甲烷在反应中首先转化为硫酸甲酯,硫酸甲酯随后水解为甲醇. 对于甲烷液相部分氧化反应,发烟硫酸中游离的SO3是非常重要的影响因素. 在工艺条件为催化剂用量7.0 mmol, 反应温度473 K, 反应压力3.5 MPa, 反应时间3 h和发烟硫酸中SO3含量50%时,甲烷转化率可达48.5%, 目的产物甲醇收率为41.5%.     

甲烷/甲醇光催化转化研究进展

在能源需求不断上涨及石油供应日益紧张的背景下,开展对煤、天然气或生物质等非油基资源(CO、CO_2、CH_3OH、CH_4等)的高效利用显得尤为重要。C_1小分子(CO、CO_2、CH_3OH、CH_4等)经催化转化可得到燃料及多种化学品,一直受到学术界及工业界的广泛关注。甲烷/甲醇作为重要的C_1平台分子,其催化转化在C_1化学中占据重要地位。为了提高目标产物的选择性,需要有效地控制甲烷/甲醇中C―H键的活化。传统热催化作为甲烷/甲醇最常见的转化方法发展已久,但仍然面临着反应条件苛刻、能耗大、产率和选择性低等问题。光催化反应通过引入光能弥补反应中吉布斯自由能的上升,同时具有反应条件温和、操作简单、能耗低等特点,从而为甲烷/甲醇转化提供了新的途径。通过调节光的波长、强度以及催化剂的氧化能力可以实现甲烷/甲醇的选择性转化,减少副产物的生成。此外,光催化能够选择性活化甲醇的C―H键而非O―H键,从而实现甲醇的C―C偶联反应。本文主要围绕甲烷/甲醇的重整、氧化和偶联反应,总结近年来的光催化转化进展,并对进一步提高光催化性能做了展望。     

Biosynthesis of methanol from methane by <Emphasis Type="Italic">Methylosinus trichosporium</Emphasis> OB3b

Methanol has recently attracted significant interest in the energetic field. Current technology for the conversion of methane to methanol is based on energy intensive endothermic steam reforming followed by catalytic conversion into methanol. The one-step method performed at very low temperatures (35°C) is methane oxidation to methanol via bacteria. The aim of this work was to examine the role of copper in the one-step methane oxidation to methanol by utilizing whole cells of Methylosinus trichosporium OB3b bacteria. From the results obtained it was found that copper concentration in the medium influences the rate of bacterial biomass growth or methanol production during the process of methane oxidation to methanol. The presented results indicate that the process of methane oxidation to methanol by Methylosinus trichosporium OB3b bacteria is most efficient when the mineral medium contains 1.0 × 10⁻⁶ mol dm⁻³ of copper. Under these conditions, a satisfactory growth of biomass was also achieved. Presented at the 35th International Conference of the Slovak Society of Chemical Engineering, Tatranské Matliare, 26–30 May 2008.     

Methane Photooxidation with Nearly 100 % Selectivity Towards Oxygenates: Proton Rebound Ensures the Regeneration of Methanol

Restrained by uncontrollable dehydrogenation process, the target products of methane direct conversion would suffer from an inevitable overoxidation, which is deemed as one of the most challenging issues in catalysis. Herein, based on the concept of a hydrogen bonding trap, we proposed a novel concept to modulate the methane conversion pathway to hinder the overoxidation of target products. Taking boron nitride as a proof-of-concept model, for the first time it is found that the designed N−H bonds can work as a hydrogen bonding trap to attract electrons. Benefitting from this property, the N−H bonds on the BN surface rather than C−H bonds in formaldehyde prefer to cleave, greatly suppressing the continuous dehydrogenation process. More importantly, formaldehyde will combine with the released protons, which leads to a proton rebound process to regenerate methanol. As a result, BN shows a high methane conversion rate (8.5 %) and nearly 100 % product selectivity to oxygenates under atmospheric pressure.     

非晶态Fe0.5Al0.5PO4表面上激光促进甲烷直接氧化合成甲醇的研究

用溶胶—凝胶法合成了非晶态Fe0.5Al0.5PO4。用XRD和TPR表征了其结构和晶格氧的活性;用IR和TPD表征了CH4在其表面上的吸附行为;用LSSR方法考察了CH4直接氧化合成CH3OH的反应规律。结果表明,Fe0.5Al0.5PO4具有非晶态的结构,FePO4和AlPO4的微区被均匀地相互隔离,导致固体本身不具有长程有序性。非晶态的Fe0.5Al0.5PO4与晶态的Fe0.5Al0.5PO4相比,其晶格氧的活性大且活性氧的含量高。CH4以分子态吸附于固体表面P=O键上,非晶态Fe0.5Al0.5PO4表面上CH4的吸附强度和吸附量都较晶态Fe0.5Al0.5PO4上大。用1073 cm-1的激光激发固体表面P=O键,在100℃以上CH4的直接氧化反应顺利进行,CH3OH保持高选择性。在相同的反应条件下,非晶态Fe0.5Al0.5PO4能更有效地促进反应的进行,表明在激发相同表面化学键的情况下,固体表面材料的其它性质如粒度、比表面积和晶格氧的活性对反应也有一定程度的影响。     

Recent Progress in Direct Partial Oxidation of Methane to Methanol

The direct conversion of methane to methanol has attracted a great deal of attention for nearly a century since it was first found possible in 1902, and it is still a challenging task. This review article describes recent advancements in the direct partial oxidation of methane to methanol. The history of direct oxidation of methane and the difficulties encountered in the partial oxidation of methane to methanol are briefly summarized. Recently reported developments in gas-phase homogeneous oxidation, heterogeneous catalytic oxidation and liquid phase homogeneous catalytic oxidation of methane axe reviewed.     

Density functional theory calculations of structure, FT-IR and Raman spectra of S-phenyl thioacetate

A catalyst composed of a Pd(5)Cu mixed oxide supported over Al(2)O(3)-CeO(2) with general formula Pd(5)CuO(x)/Al(2)O(3)-CeO(2) (Al/Ce atomic ratio=1/1) has been prepared by a wet impregnation method and tested in the methanol conversion. The structural and morphological characterization of the catalyst evidences that it is a mesoporous material thermally stable up to 873 K. At that temperature the specific surface area value is 170 m(2)/g, and a CeO(2) cubic phase is identified together with ill-defined diffraction peaks tentatively assigned to Cu-Pd clusters, suggesting that the active phase is well dispersed over the support. Infrared studies prove that methanol conversion takes place over the catalyst to a high extent yielding syngas as main product in the range 473-723 K and methane at higher temperatures. Oxygenated intermediates containing methoxy, carbonile or formiate species are not detected, which evidences that methanol conversion to methane very probably takes place according to a via-carbide mechanism.