Synthesis gas production using oxygen storage materials as oxygen carrier over circulating fluidized bed

A novel process for synthesis gas production over Circulating Fluidized Bed （CFB） using oxygen storage materials as oxygen carder was reported. First, oxygen in the air was chemically fixed and converted to lattice oxygen of oxygen storage materials over regenerator, and then methane was selectively oxidized to synthesis gas with lattice oxygen of oxygen storage materials over riser reactor. The results from simulation reaction of CFB by sequential redox reaction on a fixed bed reactor using lanthanum-based perovskite LaFeO3 and La0.8Sr0.2Fe0.9CO0.1O3 oxides prepared by sol-gel, suggested that the depleted oxygen species could be regenerated, and methane could be oxidized to synthesis gas by lattice oxygen with high selectivity. The partial oxidation of methane to synthesis gas over CFB using lattice oxygen of the oxygen storage materials instead of gaseous oxygen should be possibly applicable.

Dynamic Oxygen Storage Capacity Measurements on Ceria-Based Material

Dynamic oxygen storage and release capability （OSC） measurement apparatus was designed to evaluate the OSC performance of ceria-based oxygen storage material. The optimum measurement condition was at a frequency of 0.1 Hz with the inlet gas-flow sequence CO （5S）→O2（5S）→CO→O2 and a flow rate of 300 ml·min^-1. Under this condition, similar regular square wave in the inlet and outlet of the reactor was obtained to guarantee the reliability of the dynamic OSC results. The dynamic OSC performance of the CeO2 and Ce0.67Zr0.33O2 mixed oxide prepared using the citric sol-gel method was studied at the optimum measurement condition with focus on both quantitative and qualitative analyses, The results reveal distinctly that Ce0.67Zr0.33O2 had better dynamic OSC performance because of its higher oxygen migration rate than CeO2. Under dynamic conditions, two CO2 production peaks occurred corresponding to the CO pulse and the O2 pulse, respectively, during the entire cycle. The intensity and ratio between the two CO2 productions were highly influenced by temperature and frequency indicating complex surface phenomena during the oxygen storage/release process, As a result, this set-up can be applied to the evaluation of ceria-based material on the OSC performance.

Nanostructured energy materials for electrochemical energy conversion and storage: A review

Nanostructured materials have received tremendous interest due to their unique mechanical/electrical properties and overall behavior contributed by the complex synergy of bulk and interfacial properties for efficient and effective energy conversion and storage. The booming development of nanotechnology affords emerging but effective tools in designing advanced energy material. We reviewed the significant progress and dominated nanostructured energy materials in electrochemical energy conversion and storage devices, including lithium ion batteries, lithium-sulfur batteries, lithium-oxygen batteries, lithium metal batteries, and supercapacitors. The use of nanostructured electrocatalyst for effective electrocatalysis in oxygen reduction and oxygen evolution reactions for fuel cells and metal-air batteries was also included. The challenges in the undesirable side reactions between electrolytes and electrode due to high electrode/electrolyte contact area, low volumetric energy density of electrode owing to low tap density, and uniform production of complex energy materials in working devices should be overcome to fully demonstrate the advanced energy nanostructures for electrochemical energy conversion and storage. The energy chemistry at the interfaces of nanostructured electrode/electrolyte is highly expected to guide the rational design and full demonstration of energy materials in a working device. (C) 2016 Science Press and Dalian Institute of Chemical Physics, Chinese Academy of Sciences. Published by Elsevier B.V. and Science Press. All rights reserved.

Phase separation-hydrogen etching-derived Cu-decorated Cu-Mn bimetallic oxides with oxygen vacancies boosting superior sodium-ion storage kinetics

Understanding the crystal phase evolution of bimetallic oxide anodes is the main concern to profoundly reveal the conversion reaction kinetics and sodium-ion storage mechanisms.Herein,an integrated selfsupporting anode of the Cu-decorated Cu-Mn bimetallic oxides with oxygen vacancies(Ov-BMO-Cu)are in-situ generated by phase separation and hydrogen etching using nanoporous Cu-Mn alloy as selfsacrificial templates.On this basis,we have elucidated the relationship between the phase evolution,oxygen vacancies and sodium-ion storage mechanisms,further demonstrating the evolution of oxygen vacancies and the inhibition effect of manganese oxides as an“anchor”on grain aggregation of copper oxides.The kinetic analyses confirm that the expanded lattice space and increased oxygen vacancies of cycled Ov-BMO-Cu synergistically guarantee effective sodium-ion diffusion and storage mechanisms.Therefore,the Ov-BMO-Cu electrode exhibits higher reversible capacities of 4.04 mA h cm^(-2)at 0.2 mA cm^(-2)after 100 cycles and 2.20 m A h cm^(-2)at 1.0 mA cm^(-2)after 500 cycles.Besides,the presodiated Ov-BMO-Cu anode delivers a considerable reversible capacity of 0.79 m A h cm^(-2)at 1.0 mA cm^(-2)after 60 cycles in full cells with Na_(3)V_(2)(PO_(4))_(3)cathode,confirming its outstanding practicality.Thus,this work is expected to provide enlightenment for designing high-capacity bimetallic oxide anodes.

Effects of Edible Coatings on Quality and Antioxidant Activity of Zizyphus Jujuba Miller cv. Dongzao During Storage

The development of edible coatings has been lauded with respect to their safety and effectiveness. In this study, we researched the effects of edible coatings (2% CaCl2, 1% chitosan and 1% pullulan) on the nutrient content and antioxidant abilities of jujube (Zizyphus jujuba Miller cv. Dongzao). Using the new analysis technique for order of preference by similarity to ideal solution (TOPSIS), we evaluated the effects of these coatings. Compared with the control fruit group, test results showed that coating treatment significantly delayed fruit senescence. Specifically, CaCl2treatment not only maintained fruit storage quality and antioxidant activity but also restrained the production and accumulation of malondialdehyde in jujube. Chitosan treatment delayed decreases in secondary metabolites and superoxide dismutase and catalase activity. Pullulan coatings performed better in terms of proanthocyanidin and cyclic adenosine monophosphate (cAMP). We also used TOPSIS to evaluate the preservation effect of different film coatings and found 2% CaCl2to be the best treatment for jujube, followed by 1% chitosan and 1% pullulan. Based on the appropriate materials and concentration of the film coatings, edible coatings have the potential to retain the quality and antioxidant capacity of the Chinese jujube cv. Dongzao. © 2016, Tianjin University and Springer-Verlag Berlin Heidelberg.

Metal-organic frameworks for highly efficient oxygen electrocatalysis

Metal‐organic frameworks(MOFs)are a series of highly porous crystalline materials,which are built from inorganic metal nodes and organic linkers through coordination bonds.Their unique porous structural features(such as high porosity,high surface areas,and highly ordered nanoporous structures)and designable structures and compositions have facilitated their use in gas capture,separation,catalysis,and energy storage and conversion.Recently,the design and synthesis of pure MOFs and their derivatives have opened new routes to develop highly efficient electrocatalysts toward oxygen reduction reactions(ORR)and oxygen evolution reactions(OER),which are the core electrode reactions in many energy storage and conversion techniques,such as metal‐air batteries and fuel cells.This review first discusses recent progress in the synthesis and the electrocatalytic applications of pure MOF‐based electrocatalysts toward ORR or OER,including pure MOFs,MOFs decorated with active species,and MOFs incorporated with conductive materials.The following section focuses on the advancements of the design and preparation of various MOF‐derived materials-such as inorganic nano‐(or micro‐)structures/porous carbon composites,pure porous carbons,pure inorganic nano‐(or micro‐)structured materials,and single‐atom electrocatalysts-and their applications in oxygen electrocatalysis.Finally,we present a conclusion and an outlook for some general design strategies and future research directions of MOF‐based oxygen electrocatalysts.

SO_(4)^(2-)-modified La,Y-doped ceria-zirconia with high oxygen storage capacity and its application in Pd-only three-way catalysts

As the oxygen redox ability shows great effects on the catalytic performances of ceria-zirconia based materials,many strategies have been utilized to improve the oxygen storage capacity.Here in this study,we report a simple and facile approach to prepare a SO_(4)^(2-)-modified La,Y-doped ceria-zirconia material(SO/CZLY-f)with high oxygen storage capacity.Due to the additional redox process between SO_(4)^(2-)and S^(2-),oxygen storage capacity of SO/CZLY-f(745.3μmol O_(2)/g)is about 1.6 times higher than that of La,Ydoped ceria-zirconia material without SO_(4)^(2-)modification.Moreover,the catalytic activities and stability of the corresponding Pd-only three-way catalyst were measured.Compared to that of Pd@CZLY-f,the operation window of CO,full conversion temperature of HC and NO over Pd@SO/CZLY-f are obviously widened and lowered,respectively.After aging treatment at 1100℃for 4 h,the superiority of aged Pdloading composite is still maintained.

Two-Dimensional Materials for High-Performance Oxygen Evolution Reaction:Fundamentals,Recent Progress,and Improving Strategies

The oxygen evolution reaction(OER)plays an essential role in many energy storage and conversion technologies,but its high overpotential and sluggish kinetics seriously restrict its energy efficiency.The development of efficient and inexpensive OER electrocatalysts remains a grand challenge.Twodimensional(2D)materials with their unique structure and electronic properties have wide application prospects for OER.In this review,first introducing OER electrocatalytic mechanisms and some crucial parameters for evaluating OER electrocatalysts,the latest progress in the design and construction of 2D materials for OER is systematically discussed,including layered double hydroxides,2D carbon materials,transition metal dichalcogenides,metal oxide and phosphide nanosheets,metal–organic frameworks,covalent-organic frameworks,and MXenes.Obviously,some effective design and optimization strategies to improve the electrocatalytic activity and durability of 2D materials such as OER electrocatalysts have been comprehensively generalized.The advantages and shortcomings of these 2D materials are analyzed in detail,and their practical applications are explained in depth,which is crucial for the rational design of high-performance OER electrocatalysts.Finally,the challenges and future development opportunities for 2D materials in enhanced OER are discussed.Our review is expected to provide clear guidance for the development of new low-cost 2D materials for advanced OER electrocatalysts.

高热稳定性、高比表面积低铈型铈锆钇储氧材料的制备及其性能研究

采用氨水-碳酸铵混合沉淀剂制备了低铈型铈锆钇三组分储氧材料.采用X射线衍射、BET、氧脉冲吸附和H2程序升温还原(H2-TPR)等技术对材料的晶体结构、比表面积、孔结构、储氧性能和还原性能进行了研究.结果表明,该材料经873 K焙烧4 h后比表面积达到116.8 m2/g,孔容达到0.30 cm3/g,经1 273 K老化10 h后,比表面积和孔容仍然保持在68.1 m2/g和0.22 cm3/g.由XRD结果可知,材料的物相组成为四方相的Zr0.84Ce0.16O2,在热处理过程中物相结构稳定.氧脉冲吸附和程序升温还原的结果表明,材料储氧性能保持较好.

沉淀方法对CeO_2-ZrO_2系储氧材料性能的影响

利用不同沉淀方法制备了一系列CeO2-ZrO2系储氧材料,并应用BET、XRD、TPR及其储氧性能测定等方法对储氧材料进行了研究.结果表明,不同的沉淀方法对样品的结构和性能有重要的影响.并流法可得到耐高温,储氧性能好,比表面积高的储氧材料;正滴法所得样品储氧量低但稳定,其比表面积抗老化性能差;反滴法所制备的样品储氧性能好,老化后比表面积较低.三种沉淀方法均可形成CeO2-ZrO2固溶体,材料的还原性能取决于比表面积,但与储氧性能无直接关系.

CeO_2基氧化物储氧材料研究 (Ⅰ)制备、储氧性能研究

用共沉淀法制备了CZO和CZYO复合氧化物,对在750,900,1050℃老化的样品进行XRD,BET和OSC的测试和分析。在高温条件下纯CeO2样品的比表面积和OSC迅速下降,晶粒尺寸快速增大;所制备的CZO复合氧化物由立方相和四方相两种结构的固溶体组成,在高温老化后氧化物晶粒的尺寸增大较快;CZYO复合氧化物中的Y含量增至0.15mol时形成均相的固溶体,且氧化物的晶粒尺寸增长较慢,Y起到了高温条件下稳定氧化物性能的作用;CZYO复合氧化物具有BET表面积大、OSC高等优良的耐高温性能,是适用于开发新一代TWC的储氧材料。

新型稀土储氧材料的性能及在三效催化剂中的应用

采用共沉淀法制备了铈锆复合氧化物CeO2-ZrO2-Y2O3(CZ-Y)和CeO2-ZrO2(CZ),对其进行了BET、TPD和储氧量(OSC)的表征,并考察了这两种铈锆复合氧化物对Pt-Rh型三效催化剂性能的影响。结果表明,含CZ-Y的催化剂具有较好的低温活性和抗老化性能。

添加剂对CeO_2-ZrO_2-Al_2O_3复合氧化物结构及性能的影响

分别以柠檬酸(CA)、聚乙二醇(PEG)和淀粉(ST)为添加剂,采用共沉淀法制备CeO_2-ZrO_2-Al2O3(CZA)复合氧化物储氧材料,利用XRD、TG/DSC、SEM、N_2吸附-脱附、氧脉冲吸附和程序升温还原等检测方法对材料性能进行表征。XRD结果表明:ST添加剂的样品经1000℃煅烧后产物主要为CeO_2和γ-Al_2O_3,添加CA与PEG的样品为CeO_2-ZrO_2相,并夹带少量γ-Al_2_O3相;经1100℃煅烧后,3种添加剂样品都主要为CeO2-ZrO2晶相。SEM结果表明:CA、ST和PEG添加剂样品经1000℃高温处理后,分别为颗粒状、蜂窝状和多孔网状结构。N_2吸附-脱附结果表明:经600℃热处理后,ST添加剂样品具有最大的比表面积234.95 m~ 2/g和孔容1.589 cm^3/g;经1000℃热处理后,添加PEG样品获得最大的比表面积、孔容和孔径,其值分别为92.50 m^2/g、0.702 cm3/g和29.84 nm,且有最佳的孔分布和吸附-脱附能力。储氧性能OSC和H2-TPR结果表明:PEG添加剂制备的材料具有最好的储氧能力(OSC)和还原性能;1100℃高温下,ST添加剂样品的结构特性与PEG的接近;而CA添加剂样品的吸附能力、储氧性能都相对较低。

整体式Pt/γ-Al_2O_03/Ce_(0.5-x)Zr_(0.5-x)Mn_(2x)O_2催化剂低温催化燃烧饮食油烟(英文)

采用固定床反应器评价了整体式催化剂Pt/γ-Al2O3/Ce0.5-xZr0.5-xMn2xO2去除饮食油烟的催化性能.制备了一系列不同Mn含量的Ce0.5-xZr0.5-xMn2xO2储氧材料,并考察了其作为载体对Pt/γ-Al2O3/Ce0.5-xZr0.5-xMn2xO2催化剂活性的影响.应用X射线衍射(XRD)、N2物理吸附和H2程序升温还原(H2-TPR)等手段对催化剂进行了表征.XRD结果表明,贵金属Pt很好地分散在载体γ-Al2O3和Ce0.5-xZr0.5-xMn2xO2上.N2物理吸附和H2-TPR研究结果与催化剂活性测试能很好吻合.催化剂的活性顺序为x=0.10>x=0.15>x=0.05>x=0>x=0.20,Pt/γ-Al2O3/Ce0.4Zr0.4Mn0.2O2催化剂活性最好,油烟完全转化温度仅为495K.

整体式Pt基催化剂上CH_4选择性催化还原NO的研究

以La-Al2O3(La稳定的!-Al2O3)、Ce0.63Zr0.37O2(OSM1)及Ce0.5Zr0.3Mn0.2O2(OSM2)为载体,Pt为活性组分,制备了Pt质量分数为1%的整体式催化剂.研究了不同载体负载的催化剂对CH4选择催化还原NO反应的性能,并利用XRD、H2-TPR和XPS对催化剂进行了表征.结果表明,Pt/OSM1和Pt/OSM2催化剂在氧含量为0.8%时对CH4催化还原NO具有优异的净化性能,Pt/OSM1催化剂上500℃时,CH4和NO均达到100%转化;Pt/OSM2催化剂上500℃时,CH4和NO的转化率分别达到73%和100%;而Pt/La-Al2O3催化剂只在O2含量较低时(0.4%以下)具有较好活性,500℃以上才可使CH4和NO完全转化.H2-TPR结果表明,Pt与OSM1和OSM2存在的相互作用导致低温还原物相生成.Pt与OSM的相互作用及OSM的储氧性能使催化剂在过量氧存在下对CH4催化还原NO具有优异性能.

Pt/γ-Al2O3/CexZr1-xO2催化剂低温催化燃烧去除饮食油烟(英文)

以CexZr1-xO2固溶体做载体,制备了系列Pt/γ-Al2O3/CexZr1-xO2催化剂(x=1,0.75,0.5,0.25,0).应用Brunauer-Emmet-Teller(BET)比表面积分析、X射线衍射(XRD)和H2程序升温还原(H2-TPR)等手段对催化剂进行相关表征,并系统研究了催化剂在饮食油烟催化燃烧中的催化活性.BET结果表明催化剂的比表面积随Ce/Zr摩尔比的减小而减小.XRD结果表明贵金属Pt很好地分散在氧化铝和CexZr1-xO2固溶体上.H2-TPR结果发现催化剂Pt/γ-Al2O3/Ce0.5Zr0.5O2的还原峰面积最大且氧离子的流动性最好.催化活性研究结果表明Pt负载在CexZr1-xO2固溶体上有利于油烟的催化燃烧,降低了反应温度.随着CexZr1-xO2固溶体中Ce/Zr摩尔比的变化,催化剂的活性顺序为Pt/γ-Al2O3/Ce0.5Zr0.5O2>Pt/γ-Al2O3/Ce0.25Zr0.75O2>Pt/γ-Al2O3/Ce0.75Zr0.25O2>Pt/γ-Al2O3/CeO2>Pt/γ-Al2O3/ZrO2.

高分子凝胶法合成纳米铈锆氧化物固溶体及其热稳定性研究

采用改进的高分子凝胶法在较低温度下合成了铈锆氧化物固溶体Ce1-xZrxO2.当0≤x≤0.6时,固溶体为立方相结构;当0.7≤x≤0.9时,固溶体具有四方相结构;当x=1.0时,产物由四方相和单斜相组成.透射电镜分析结果显示,产物的粒径在10～20nm之间;粉末X射线衍射(XRD)实验与计算结果表明,晶胞体积随x的增大呈线性减小;差示扫描量热法(DSC)和XRD测试结果说明,在0≤x≤0.9,温度为323～1273K的范围时,产物的相结构保持不变.

铈锆摩尔比对Ce_(0.3+x)Zr_(0.6-x)Y_(0.1)O_(1.95)系列储氧材料性能的影响

A series of materials Ce0.3+xZr0.6-xY0.1O1.95 were prepared by co-precipitation routine and the property of these materials was studied by means of oxygen storage capacity, temperature programming reduction, X-ray diffraction, transmission electronic microscope, and X-ray photoelectron spectroscopy. The results indicate that the materials with a low Ce/Zr molar ratio possess higher cerium atom utilization ratio, reducibility and thermal stability than the materials with a high Ce/Zr ratio, and Ce0.35Zr0.55Y0.1O1.95 possesses the best properties.

一种具有低SO_2氧化活性并满足欧V排放标准的柴油车氧化型催化剂

制备了具有高性能的稀土储氧材料Ce0.75Zr0.25O2-Al2O3,Ti0.9Zr0.1O2复合材料和Cr改性的β分子筛(Cr-β分子筛),并以此制备了单Pt型柴油车尾气净化氧化型催化剂.低温N2吸附-脱附、储氧量测试结果表明,Ce0.75Zr0.25O2-Al2O3样品具有较大的比表面积和优异的储氧性能,Ti0.9Zr0.1O2复合材料也具有优越的织构性能.催化剂对HC和CO具有较高的催化活性,可使SOF在140oC开始转化,且具有较低的SO2氧化活性.在YC4F国Ⅳ柴油机的测试结果表明,经该催化剂处理后的尾气排放能够满足欧Ⅴ排放标准对HC和CO排放要求.

满足欧V排放标准的汽油车中偶催化剂

制备了具有高性能的稀土储氧材料Ce0.65Zr0.25Y0.07La0.03O1.95和镧稳定的氧化铝(La-Al2O3),并以此为基础制备了Pt-Pd-Rh型中偶汽油车尾气净化催化剂.老化前后的性能检测表明,稀土储氧材料具有较大的比表面积和优异的储氧性能,La-Al2O3也具有优越的织构性能和高的热稳定性.催化剂对模拟尾气具有较高的催化活性和稳定性,在捷达-MT型汽油车上的测试结果表明,经该催化剂处理后的尾气排放能够满足欧Ⅴ排放标准.