硫化CoMo/Al2O3-TiO2催化剂上CO催化还原SO2的研究

报导了Al2O3、Al2O3-TiO2和TiO2担载的硫化CoMo催化剂上CO催化还原SO2的规律性,结果表明，反应物分别在350 ℃、350～400 ℃间和400 ℃完全转化为CO2和元素S.在含TiO2的催化剂上,CO-SO2反应可同时按COS中间物机理和Redox机理进行,从而使尾气中COS的含量大为降低,提高了生成元素S的选择性.对反应机理进行了讨论.     

铜系催化剂上甲醇蒸气转化制氢过程的原位红外研究

 用原位红外光谱法跟踪研究了不同条件下铜系催化剂上甲醇蒸气转化制氢反应的初始开车过程．结果表明，反应过程中二氧化碳不是在一氧化碳之后产生的．可以推断，铜系催化剂上的甲醇蒸气转化制氢过程不是先进行甲醇分解为一氧化碳和氢气，然后一氧化碳和水蒸气发生变换反应生成二氧化碳和氢气．甲醇蒸气转化反应的主要过程是甲醇和水直接生成二氧化碳和氢气．     

Promoter effect on the CO2-H2O formation during Fischer-Tropsch synthesis on iron-based catalysts

The effects of Mg, La and Ca promoters on primary and secondary CO_2 and H_2O formation pathways during Fischer-Tropsch synthesis on precipitated Fe/Cu/SiO_2 catalysts are investigated. The chemisorbed oxygen atoms in the primary pathway formed in the CO dissociation steps reacted with co-adsorbed hydrogen or carbon monoxide to produce H_2O and CO_2 , respectively. The secondary pathway was the water-gas shift reaction. The results indicated that the CO_2 production led to an increase in both primary and secondary pathways, and H_2 O production decreased when surface basicity of the catalyst increased in the order Ca >Mg >La.     

Desulfurization of mercaptans to hydrocarbons by carbon monoxide and water in the presence of cobalt carbonyl

Benzylic mercaptans and thiophenols undergo desulfurization when exposed to carbon monoxide and water, with cobalt carbonyl as the catalyst; carbonyl sulfide is evolved in these reactions.     

Al2O3上羰基硫常温催化水解的氧中毒机理

利用原位漫反射傅立叶变换红外光谱、X光衍射、BET、离子色谱(IC)等手段, 对Al2O3常温催化水解羰基硫(OCS)的氧中毒机理进行了研究. 实验表明, 表面—OH在OCS的催化水解反应中起关键作用, 表面HSCO-2物种是OCS催化水解反应的中间体. 有氧条件下, 利用原位红外光谱和离子色谱检测到了催化剂表面SO2-4的生成. SO2-4在催化剂表面积累是Al2O3上OCS常温催化水解氧中毒的主要原因.<     

Promoter effect on the CO_2-H_2O formation during Fischer-Tropsch synthesis on iron-based catalysts

The effects of Mg,La and Ca promoters on primary and secondary CO2 and H2O formation pathways during Fischer-Tropsch synthesis on precipitated Fe/Cu/SiO2 catalysts are investigated.The chemisorbed oxygen atoms in the primary pathway formed in the CO dissociation steps reacted with co-adsorbed hydrogen or carbon monoxide to produce H2O and CO2,respectively.The secondary pathway was the water-gas shift reaction.The results indicated that the CO2 production led to an increase in both primary and secondary pathways,and H2O production decreased when surface basicity of the catalyst increased in the order Ca Mg La.     

Theoretical and Experimental Study on Reaction Coupling： Dehydrogenation of Ethylbenzene in the Presence of Carbon Dioxide

Dehydrogenation of ethylbenzene (EB) to styrene (ST) in the presence of CO2, in which EB dehydrogenation is coupled with the reverse water-gas shift (RWGS), was investigated extensively through both theoretical analysis and experimental characterization. The reaction coupling proved to be superior to the single dehydrogenation in several respects. Thermodynamic analysis suggests that equilibrium conversion of EB can be improved greatly by reaction coupling due to the simultaneous elimination of the hydrogen produced from dehydrogenation. Catalytic tests proved that iron and vanadium supported on activated carbon or Al2O3 with certain promoters are potential catalysts for this coupling process. The catalysts of iron and vanadium are different in the reaction mechanism, although ST yield is always associated with CO2 conversion over various catalysts. The two-step pathway plays an important role in the coupling process over Fe/Al2O3, while the one-step pathway dominates the reaction over V/Al2O3. Coke deposition and deep reduction of active components are the major causes of catalyst deactivation. CO2 can alleviate the catalyst deactivation effectively through preserving the active species at high valence in the coupling process, though it can not suppress the coke deposition.     

Effect of CeO2 on the catalytic performance of Ni/Al2O3 for autothermal reforming of methane

The effect of promoter Ce on the catalytic performance of Ni/Al2O3 catalyst for autothermal reforming of methane to hydrogen was investigated. The catalysts were characterized by X-ray diffraction （XRD）, temperature-programmed reduction （TPR）, and X-ray photoelectron spectroscopy （XPS）. The results indicated that the catalytic performance of the catalysts was improved with the addition of Ce. Ni/Ce30Al70Oδ showed the highest CH4 conversion in operation temperatures ranging from 650 ℃ to 850 ℃. At the same time, the decrease in H2/CO ratio with increasing reaction temperature was consistent with the fact that water-gas shift reaction was thermodynamically unfavorable at higher temperatures. The XRD result indicated that adding Ce to Ni/Al2O3 catalyst prevented the formation of NiAl2O4 and facilitated the formation of NiO. The formation of NiO increased the number of active sites, resulting in higher activity. Comparing the TPR profiles of Ni/Ce30Al70Oδ with Ni/Al2O3, it could be clearly observed that with the addition of Ce, the total reduction peak areas in the middle and low temperatures increased. It was most probably that the addition of Ce inhibited the stronger interaction between Ni and Al2O3 to form the phase of NiAl2O4, and favored the formation of the strong interaction between NiO species and CeO2. Therefore, the addition of Ce to the Ni/Al2O3 catalyst increased the active surface that promoted the activity of the catalyst.     

硫化态NiW/Al2O3催化剂加氢脱硫活性相的研究Ⅱ.程序升温还原表征

 采用程序升温还原法对一系列具有相同W含量和不同Ni含量的硫化态NiW/Al2O3催化剂进行了表征,以考察催化剂中不同硫物种的数量及还原性能. 结果表明,含有助剂Ni的催化剂TPR谱在673~873 K出现了一个还原峰,归属为催化剂的NiWS混合相被分解生成的硫化镍物的还原. 随着助剂Ni含量的增加,与该还原峰相应的H2S生成量增大,表明形成了更多的NiWS活性相. 另外,Ni/(Ni+W)原子比为0.41的催化剂样品的噻吩加氢脱硫活性随着还原温度的升高而急剧下降,证实了催化剂在还原过程中活性相被逐步分解.     

Kinetics and mechanism of catalytic partial oxidation reactions of alkanes on rhodium surfaces

The kinetics of the partial oxidation of isobutane with molecular oxygen on Rh(111) single-crystal surfaces were studied by using a collimated molecular beam under ultrahigh vacuum conditions. Both hydrogen and water were shown to form as primary products, not after secondary reforming or water-gas shift steps as it has been suggested in the past. The production of carbon monoxide (but not of carbon dioxide) was also detected. Water production reaches its steady-state rate in a slower fashion than the rest of the products, presumably because of the kinetics of formation and consumption of the hydroxo surface intermediate involved.     

Pt/Al2O3整体催化剂上选择性氧化脱除甲醇重整氢源中CO --副反应对CO脱除效果的影响分析

移动甲醇重整制氢是质子交换膜燃料电池（PEMFC）可行的供氢方式之一,包括水蒸气重整、部分氧化重整和自热重整。甲醇重整制氢方法不同,重整气体积组成在H245％～75％,CO215％～25％,CO1％～10％,H2O10％～20％和N20—20％变化。重整气进入PEMFC之前要经过CO水蒸气变换反应（如果采用水蒸气重整,不需要变换过程）,     

稀土氧硫化物上的羰基硫水解反应

研究了一种新型的羰基硫水解催化剂--稀土氧硫化物.考察了稀土系列氧化物硫化后的水解活性,发现其活性顺序为La≈Pr≈Nd≈Sm>Eu>Ce>Gd≈Ho>Dy>Er.XRD物相分析表明,各种稀土氧化物经水合及硫化后呈现出不同的物相变化特性,稀土氧硫化物是COS水解的活性物质.在氧硫化镧和氧硫化钕催化剂上研究了O₂和SO₂对羰基硫水解反应的影响,与传统的氧化铝基和氧化钛基水解催化剂相比,稀土氧硫化物显示出良好的抗氧化性能,而SO₂对催化活性的影响是可逆的.     

Production of Bio-hydrogen Using Bio-oil as a Potential Biomass-derived Renewable Feedstock

The bio-oil derived from pyrolysis of straw can be selectively converted into high-purity hydrogen by coupling three steps:(i)steam refonning(SR)of di tierent bio-oils,(ii)water-gas shift(WGS),and(iii)the removal of CO2.the catalytic SR reaction over the NiLaTiAl catalyst,coupled with a low-temperature WGS reaction with the CuZnAl catalyst,promoted the conversion of various oxygen-contaming organic compounds in the bio-oil into hydrogen and carbon dioxide.Under the optimized condition,light bio-oil achieved the highest conversion(99.8%,molar fraction),with a high hydrogen yield of 16.4%(mass traction)and a H2 purity of 99.94%(volume fraction).The carbon deposition on the NiLaTiAl catalyst was the main factor caused catalyst deactivation.Production of hydrogen from different bio-oil model compounds was also investigated in detail.     

Cobalt carbonyl catalyzed reactions of disulfides: Carbonylation to thioesters and desulfurization to sulfides

aromatic and benzylic disulfides react with carbon monoxide and a catalytic amount of cobalt carbonyl to give thioesters and carbonyl sulfide, while the presence of t-butyl peroxide results in the formation of sulfides in high yields.     

硫化态三组元NiMoP/γ-Al2O3催化剂的TPR表征及噻吩HDS活性的研究

A series of sulfided tertiary NiMoP/γ-Al2O3 catalysts with different contents of MoO3 were prepared by using molybdophosphoric acid of Keggin structure(H3PMo12O40) and nickel nitrate as origins of active phase components of molybdenum, phosphorus and nickel, and characterized by TPR technique, with their HDS activity being investigated with thiophene as a model substrate. For the sulfided Mo-0 catalyst containing no nickel as promoter, the only hydrogen sulfide evolution peak Ⅰ　is observed at 462 K and attributed to the hydrogenation of the so-called edge sulfur atoms chemisorbed on coordinatively unsaturated(cus) Mox+ sites on the MoS2 phase(MoS2 slab). With the introduction of nickel into the active phase of the sulfided Mo-0 catalyst and with the increase of the molybdenum loading, a new hydrogen sulfide evolution peak Ⅱ gradually develops at the low temperature side of the peak Ⅰ, at the same time accompanied by both the increase of the area ratio of the peak Ⅱ to the peak Ⅰ and the shift of the hydrogen sulfide evolution maximum rate to lower temperatures, which may imply the existence of two kinds of active centers related to molybdenum and nickel respectively and the synergic action between the two centers above. It should be noted that for the sulfided NiMoP/γ-Al2O3 catalysts, the thiophene HDS rate and the quantity of hydrogen sulfide evolved during TPR process increase monotonously with the atomic ratio of molybdenum to nickel in the form of ［n(Ni)+n(Mo)］/n(Ni). On the basis of the results here, the conclusion may be reached that the two kinds of vacancies can be formed on the edge of Ni-Mo-S slab due to the loss of S during TPR process and vacancies or sites related to the H2S evolution peak II should be regarded as the mainly active reaction centers of thiophene HDS.     

Co-K-Mo/γ-Al2O3催化剂的合成低碳醇性能及其结构研究

氧化态Ｋ－ＭｏＯ３／γ－Ａｌ２Ｏ３催化剂中添加Ｃｏ（ＮＯ３）２后在空气中四个不同温度下焙烧再硫化,制得Ｃｏ－Ｋ－ＭｏＯ３／γＡｌ２Ｏ３催化剂,对其ＣＯ加氢合成低碳醇的催化反应性能进行了评价,运用ＸＲＤ,ＬＲＳ及ＥＸＡＦＳ等手段对催化剂及其氧化态前躯体的结构进行了表征,活性测试结果表明加Ｃｏ后于５００－６５０℃焙烧制得的催化剂活性较高,且使Ｃ２＋醇比例增加,结构分析结果显示加Ｃｏ后３５０℃焙烧时,Ｃ     

Carbonyl Sulfide (COS) Donor Induced Protein Persulfidation Protects against Oxidative Stress

The emergence of hydrogen sulfide (H₂S) as an important signalling molecule in redox biology with therapeutic potential has triggered interest in generating this molecule within cells. One strategy that has been proposed is to use carbonyl sulfide (COS) as a surrogate for hydrogen sulfide. Small molecules that generate COS have been shown to produce hydrogen sulfide in the presence of carbonic anhydrase, a widely prevalent enzyme. However, other studies have indicated that COS may have biological effects which are distinct from H₂S. Thus, it would be useful to develop tools to compare (and contrast) effects of COS and H₂S. Here we report enzyme‐activated COS donors that are capable of inducing protein persulfidation, which is symptomatic of generation of hydrogen sulfide. The COS donors are also capable of mitigating stress induced by elevated reactive oxygen species. Together, our data suggests that the effects of COS parallel that of hydrogen sulfide, laying the foundation for further development of these donors as possible therapeutic agents.     

Selective synthesis of acetic acid from hydrogen and carbon monoxide by homogeneous bimetallic catalysts

Alcohols which are the main products of the reaction of hydrogen and carbon monoxide in onium halide promoted ruthenium systems, are changed to acetic acid with the addition of cobalt carbonyl as the second catalyst component. Among Group VIa-VIIIa transition metal complexes, cobalt carbonyl is the only compound which promoted acetic acid formation when combined with ruthenium carbonyl under the conditions studied. The selectivity to acetic acid varied appreciably with the combinations of solvents and promoters, and exceeded 80% with optimal catalyst composition. The effects of solvents and promoters were investigated together with ¹³C tracer experiments from which the roles of halide anions of onium salts were determined.     

硫化NiW/Al2O3催化剂上H2同时催化还原SO2和NOⅠ.NO的分解与还原

 考察了NO在硫化NiW/Al2O3催化剂上分解和还原的规律. 结果表明,在350 ℃以上,NO完全分解,但同时催化剂的晶格硫因氧化而以SO2的形式大量流失,最终导致催化剂完全失活. 在NO分解反应体系中,按化学计量比引入的H2与晶格硫竞争消耗NO分解所生成的Oad,使晶格硫的氧化在一定程度上得到抑制; 氧化的部分晶格硫能通过一系列氧化还原过程重新进入催化剂晶格,导致晶格硫的流失速度和程度得到缓和,催化剂可在较长的时间内保持较高的NO转化活性. 但是,催化剂的活性最终仍会因为大部分晶格硫逐渐流失而大幅度下降.     

铜对Mn/Al_2O_3氨还原SO_2到单质硫催化性能的影响

ＳＯ2 是危害最为严重的大气污染物之一 ,也是造成酸雨的元凶。将ＳＯ2 选择性还原为单质硫 ,既能消除ＳＯ2 对环境的污染 ,又能回收单质硫 ,具有特别重要的意义。根据所用的还原剂的不同 ,催化还原ＳＯ2 到单质硫可分为Ｈ2 、炭、烃类 (主要是ＣＨ4 )、ＣＯ和ＮＨ3还原法[1] 。氨还原法是基于氨的催化分解生成Ｎ2 和Ｈ2 混合气 ,其中的Ｈ2 再还原ＳＯ2 到硫和Ｈ2 Ｓ ,然后进行高温Ｃｌａｕｓ反应生成单质硫。Ｐａｉｋ[2 ] 等以第四周期过渡金属硫化物载于Ａｌ2 Ｏ3 作为催化剂 ,研究了Ｈ2 还原ＳＯ2 为单质硫的反应 ,认为过渡金属硫化物是…