Synthesizing active and durable cubic ceria catalysts(<6 nm)for fast dehydrogenation of bio-polyols to carboxylic acids coproducing green H_(2)

Dehydrogenation is considered as one of the most important industrial applications for renewable energy.Cubic ceria-based catalysts are known to display promising dehydrogenation performances in this area.Large particle size(>20 nm)and less surface defects,however,hinder further application of ceria materials.Herein,an alternative strategy involving lactic acid(LA)assisted hydrothermal method was developed to synthesize active,selective and durable cubic ceria of<6 nm for dehydrogenation reactions.Detailed studies of growth mechanism revealed that,the carboxyl and hydroxyl groups in LA molecule synergistically manipulate the morphological evolution of ceria precursors.Carboxyl groups determine the cubic shape and particle size,while hydroxyl groups promote compositional transformation of ceria precursors into CeO_(2) phases.Moreover,enhanced oxygen vacancies(Vo)on the surface of CeO_(2) were obtained owing to continuous removal of O species under reductive atmosphere.Cubic CeO_(2) catalysts synthesized by the LA-assisted method,immobilized with bimetallic PtCo clusters,exhibit a record high activity(TOF:29,241 h^(-1))and Vo-dependent synergism for dehydrogenation of bio-derived polyols at 200℃.We also found that quenching Vo defects at air atmosphere causes activity loss of PtCo/CeO_(2) catalysts.To regenerate Vo defects,a simple strategy was developed by irradiating deactivated catalysts using hernia lamp.The outcome of this work will provide new insights into manufacturing durable catalyst materials for aqueous phase dehydrogenation applications.

Synthesis of Neodymium-Doped Yttrium Aluminum Garnet (Nd∶YAG) Nano-Sized Powders by Low Temperature Combustion

The homogeneously dispersed, less agglomerated (Nd0.01Y0.99)3Al5O12 nano-sized powders were synthesized by the low temperature combustion (LCS), using Nd2O3, Y2O3, Al(NO3)3·9H2O, ammonia water and citric acid as starting materials. This method effectively solves the problems caused by solid-state reaction at high temperature and hard agglomerates brought by the chemical precipitation method. The powders were characterized by TG-DTA, XRD, FT-IR, TEM respectively and the photoluminescence (PL) spectra of (Nd0.01Y0.99)3Al5O12 green and sintered ceramic disks were measured. The results show that the forming temperature of YAG crystal phase is 850 ℃ and YAP crystal phase appearing during the calcinations transforms to pure YAG at 1050 ℃. The particle size of the powders synthesized by the LCS is in a range of 20～50 nm depending on the thermal treatment temperatures. The effectively induced cross section (σin) with the value 4.03×10-19 cm2 of (Nd0.01Y0.99)3Al5O12 ceramics is about 44% higher than that of single crystal.

Preparation of Neodymium-Doped Yttrium Aluminum Garnet Transparent Ceramics by Homogeneous Precipitation Method

substitutes tion, high loosely dis Neodymium doped-yttrium aluminum garnet （Nd ： YAG） transparent polycrystalline ceramics already become of single crystals because they are provided with easy fabrication, low cost, large size, highly doped concentraheat conductivity, mass fabrication, multi-layers and multi-filnctions. The Nd：YAG precursor powders with persed , slightly agglomerated, super fine and YAG cubic crystal phase were synthesized at 1100 ℃ by the homogeneous precipitation method, using Nd2O3, Y2O3, Al（NO3）3·9H2O and urea as raw materials, （NH4）2SO4 as electrical stabilizer, TEOS as sintering additive. The Nd：YAG transparent ceramics were prepared after being vacuum sintered at 1700 ℃ for 5 h. The Nd：YAG ceramic materials were characterized by the TG-DTA, XRD, FT-IR, TEM, FEG-ESEM and FT-PL. The results show that the crystallization temperature of YAG is 850 ℃ and the intermediate crystal phase YAP forming during the heat treatment transforms to YAG cubic crystal phase at 1050 ℃. The lasing wavelength of （Nd0.01 Y0.99）3Al5O12 transparent ceramics is 1.065 μm and there exists a slight red-shift compared to the single crystal with the same chemical composition. The optical transmittance is 45 % in the visible light and 58 % in the near infrared light and the optical transmittance descends with the decreasing the wavelength.

Application of Fractals on Microstructure of Neodymium-Doped Yttrium Aluminum (Nd∶YAG) Transparent Ceramics

Nd∶YAG precursor powders were synthesized by homogeneous precipitation and Nd∶YAG transparent ceramics were prepared by vacuum sintering at 1700 ℃ for 5 h. The ceramic materials were characterized by light transmittance, field emission gun-environment scanning microscope. Fractal geometry was used to study the quantitative relationships between light transmittance and fractal dimensions of Nd∶YAG transparent ceramics. It was found that the transmittance of Nd∶YAG with 1 mm in thickness was about 45% and 58% in visible and near-infrared region respectively. The microstructures of Nd∶YAG transparent ceramics were obvious fractal characteristic and fractal dimensions depart a little from two-dimension. The light transmittance decreased with increasing of fractal dimension and nonlinear fit curve was y=1350-1185x+269x2 between fractal dimension and light transmittance of Nd∶YAG transparent ceramics.

SDC/YSZ/GDC复合电解质膜燃料电池研究

在钐掺杂的氧化铈(SDC)主电解质层上利用射频磁控溅射法沉积了氧化钇稳定的氧化锆(YSZ)电子阻隔层和钆掺杂的氧化铈(GDC)化学隔层,制备了SDC/YSZ/GDC多层复合电解质膜及电池。对复合电解质膜的固体氧化物燃料电池进行了物相分析、微观结构表征和电化学性能测试。结果表明,复合电解质膜有效提升了电池的开路电位(OCV)和最大输出功率密度,这是因为复合电解质膜具有较高的离子电导率和电子电阻。

金属支撑型固体氧化物电解池的3D建模与性能分析

建立了一种铈基电解质的金属支撑型固体氧化物电解池的三维模型,通过多物理场耦合分析了其电化学工作性能.设计的3层电解质结构为10Sc1CeSZ|GDC|10Sc1CeSZ,以GDC为主电解质.针对连接体、流体域和多层单电池结构建立了三维模型,将质量、动量、能量控制方程与物质输运方程和电化学反应耦合建立多物理场分析模型.研究了设计的金属支撑型固体氧化物电解池的电化学工作性能,详细分析了电池内部的速度场、浓度场和温度场分布.结果表明,设计的金属支撑型固体氧化物电解池在650℃下,电流密度为2.4 A/cm^(2)时,电压损失为0.38 V,欧姆损失和极化损失分别占33.72%和66.28%.采用金属支撑对气体的输运仅有轻微的影响,但是整个电池内部的温度分布均匀性得到明显改善.

Ni-CeO_(2)黑色防护镀层的光助动电位沉积及光热性能

镍镀层作为一种重要的工程材料,已经在金属涂装等领域得到了广泛的应用,而二氧化铈作为一种重要的稀土氧化物也引起了学者们极大的关注。本工作利用光助动电位沉积法制备了Ni-CeO_(2)复合黑色镀层,分别研究了光照条件、沉积电位范围和沉积温度对镀层结构、组成和性能的影响。采用循环伏安法、塔菲尔极化曲线、接触角测量仪、台阶仪、紫外-可见-近红外分光光度计、发射率测量仪、扫描电子显微镜及附属能谱对不同条件下制备的镀层进行了系列表征。结果表明,光照条件下,沉积电位范围为0~-1.5 V、沉积温度为50℃时制备的Ni-CeO_(2)复合黑色镀层具有最佳的综合性能,其腐蚀电流密度为9.642×10^(-6)A·cm^(-2),水接触角达到125.95°,各波段吸收率均在94%以上且具有0.592的发射率。当沉积电位范围为0~-3.5 V时,镀层具有最高的发射率,达0.757;光照条件除了对CeO_(2)的沉积产生影响之外,也显著提升了Ni的沉积速率。该研究为制备具有高吸收率和发射率的黑色复合镀层提供了一个思路,有望在光热转换和光学仪器中得到应用。

铈及铈基材料在口腔疾病领域中的应用

背景:铈(cerium,Ce)是含量最丰富的镧系元素,主要以氧化铈的形式存在。Ce^(3+)和Ce^(4+)两种价态之间快速转化使铈兼具氧化剂和还原剂的作用,具有抗菌、抗炎、促进组织再生和抗肿瘤等多种生物学活性,在口腔医学领域具有广泛的应用。目的:概述铈在抗菌、抗炎、促进组织再生及抗肿瘤中的作用和机制,综述近年来铈和铈基材料在口腔材料改性和口腔疾病诊疗中的研究现状和应用前景。方法:以“cerium,ceria,prosthodontics,prosthesis,restorative dentistry,denture,dental implant,caries,endodontics,pulpitis,periodontitis,periodontal diseases,oral cancer”为英文检索词,以“铈,氧化铈,修复,种植,龋齿,龋病,牙髓,牙周炎,牙周疾病,口腔癌”为中文检索词,分别在Web of Science、PubMed、中国知网及万方数据库进行文献检索,检索时限为各数据库建库至2023年。通过分析和阅读文献进行筛选,按照排除筛选标准纳入文献,最终纳入73篇文献进行综述。结果与结论:①铈主要通过直接接触细菌、氧化应激和破坏细菌生物膜发挥抗菌作用,同时依赖氧化还原酶模拟活性清除活性氧而发挥抗炎功能,铈的成骨和成血管活性涉及ERK和Wnt等一系列信号通路。②铈的抗菌、抗炎、成骨和成血管活性使其在治疗口腔感染性疾病和促进口腔软硬组织再生中具有广阔的应用前景,但铈的抗肿瘤特性在口腔领域的应用仍存在一定空白。③作为口腔陶瓷材料,氧化铈稳定的氧化锆具有优异的机械物理性能,但透光性较低,适用于制作基底瓷、义齿支架和种植体。④依托铈的生物学活性,铈基材料能够有效促进种植体骨和软组织整合,抑制牙齿脱矿和致龋菌生长,促进牙本质牙髓复合体再生,减轻牙周炎炎症反应并促进牙周组织再生,在种植体表面改性、龋病预防、牙髓炎、牙周疾病和口腔癌的诊疗中均有较大的应用潜力。⑤铈在高浓度和长时间给药的情况下存在潜在的毒性,为进一步扩大铈在口腔临床实际中的应用,铈的生物安全性以及铈基材料适应口腔环境的优化在未来仍需更详尽的研究。

氧化纳米铈清除活性氧改善DSS诱导的小鼠结肠炎疾病活动度的研究

目的·探究氧化纳米铈-聚乙二醇(ceria nanoparticles-polyethylene glycol,CeNP-PEG)清除活性氧(reactive oxygen species,ROS)、改善葡聚糖硫酸钠(dextran sulphate sodium,DSS)诱导的小鼠结肠炎疾病活动度的效果。方法·首先应用醋酸铈的水合物、油胺与二甲苯等合成氧化纳米铈,经聚乙二醇-二硬脂酰磷脂酰乙醇胺(mPEG-DPSE)修饰并提纯后得到纯化的CeNP-PEG。应用透射电子显微镜(transmission electron microscopy,TEM)和动态光散射(dynamic light scattering,DLS)观察测定CeNP-PEG粒径和zeta电位等。体外培养小鼠巨噬细胞(Raw264.7)并诱导成为促炎表型(M1表型)。采用0.5μg/mL和1.0μg/mL CeNP-PEG分别处理M1表型巨噬细胞后应用Western blotting检测核因子-κB(nuclear factors-κB,NF-κB)信号通路相关蛋白表达的变化。构建DSS诱导的小鼠结肠炎模型并在造模期间予以尾静脉注射CeNP-PEG(1.0 mg/mL)3次,同时监测正常对照组(Normal组)、模型组(DSS组)和CeNP-PEG治疗组小鼠体质量、粪便性状与便血次数等,计算肠道炎症的疾病活动指数(disease activity index,DAI)。应用二氢乙啶(dihydroethidine,DHE)染色法检测小鼠肠道组织的ROS水平并通过实时荧光定量PCR(real-time quantitative PCR,RTqPCR)检测肠道组织炎症细胞因子γ干扰素(interferon-γ,Ifn-γ)、白细胞介素-6(interleukin-6,Il-6)、Il-1β和肿瘤坏死因子-α(tumor necrosis factor-α,Tnf-α)等基因的表达水平。结果·TEM和DLS结果显示合成的CeNP-PEG水合粒径为(6.96±0.27)nm,平均zeta电位为(−6.02±1.31)mV。Western blotting结果显示促炎表型巨噬细胞较对照组细胞p-P65表达增多,核因子-κB抑制蛋白α(NF-κB inhibitor-α,IκB-α)表达减少,经不同浓度CeNP-PEG干预后p-P65和IκB-α表达又趋于恢复。在小鼠结肠炎模型中,CeNP-PEG治疗组小鼠较DSS组体质量减轻更少(P=0.000),DAI评分更低(P=0.000)。肠道组织RT-qPCR结果显示,DSS组小鼠的Ifn-γ、Il-1β、Il-6和Tnf-α的mRNA水平较Normal组显著上调(均P=0.000),CeNP-PEG治疗后均显著回落。DHE染色结果显示,DSS组肠道组织的荧光强度较Normal组显著增强,CeNP-PEG治疗后荧光强度减弱。结论·CeNP-PEG可抑制肠道炎症因子的表达及促炎巨噬细胞NF-κB炎症通路的活化,消除肠道ROS,改善肠道炎症微环境并缓解DSS诱导的小鼠结肠炎的疾病活动度。

铈掺杂量对钛基锡锰铈氧化物涂层电极表面形貌及电化学性能的影响

[目的]电沉积用钛基二氧化锰电极的电化学性能有待提高。[方法]采用热分解法在450℃下制备了以SnO_(2)为中间层,稀土铈掺杂量不同的钛基MnO_(2)电极(Ti/SnO_(2)/MnO_(2)+CeO_(2)),通过场发射扫描电子显微镜与循环伏安测量、电化学阻抗谱、析氧极化曲线测试、加速寿命试验等电化学方法对电极的活性层形貌及电化学行为进行分析。[结果]铈掺杂可以明显改变活性层形貌,使其形成由大量圆形晶粒组成,均匀且致密的表面结构。当铈掺杂量为4%时,电极具有最平整的活性表层,其伏安电荷容量约为未掺杂铈时的6倍,加速寿命约为未掺杂铈时的1.8倍。[结论]适量掺杂铈可以提高钛基二氧化锰涂层电极的电催化活性及延长其使用寿命。

氧化铈负载贵金属催化剂上糠醛加氢性能研究

采用湿法浸渍在自制的氧化铈载体上制备了负载的贵金属催化剂5%Pt/CeO_(2)、5%Pd/CeO_(2)和5%Rh/CeO_(2),采用分步浸渍法制备了双金属催化剂5%Pt-0.5%Pd/CeO_(2)、5%Pt-0.5%Rh/CeO_(2)、5%Pt-0.5%Fe/CeO_(2)、5%Pt-0.5%Co/CeO_(2)和5%Pt-0.5%Ni/CeO_(2),考察它们在糠醛选择性加氢反应中的催化性能。

Promotional effect of H_3PO_4 on ceria catalyst for selective catalytic reduction of NO by NH_3

A series of H3PO4-modified CeO2 samples were prepared by impregnation of CeO2 with H3PO4solution,and evaluated for the selective catalytic reduction of NOx by NH3.The samples were characterized by X-ray diffraction,N2 adsorption-desorption,infrared spectroscopy,Raman spectroscopy,X-ray photoelectron spectroscopy,temperature-programmed desorption of NH3,and temperature-programmed reduction of H2.The results showed that more than 80%NO conversion was achieved in the temperature range 250-550℃ over the H3PO4-CeO2 catalyst.The enhanced catalytic performance could be ascribed to the increase in acidic strength,especially Bronsted acidity,and reduction in redox properties of the CeO2 after H3PO4 modification.

Enhanced catalytic activities and selectivities in preferential oxidation of CO over ceria-promoted Au/Al_2O_3 catalysts

The preferential oxidation of CO （CO‐PROX） is a hot topic because of its importance in pro‐ton‐exchange membrane fuel cells （PEMFCs）. Au catalysts are highly active in CO oxidation. Howev‐er, their activities still need to be improved at the PEMFC operating temperatures of 80–120 ＆#176;C. In the present study, Au nanoparticles of average size 2.6 nm supported on ceria‐modified Al2O3 were synthesized and characterized using powder X‐ray diffraction, nitrogen physisorption, transmission electron and scanning transmission electron microscopies, temperature‐programmed hydrogen reduction （H2‐TPR）, Raman spectroscopy, and in situ diffuse‐reflectance infrared Fourier‐transform spectroscopy. Highly dispersed Au nanoparticles and strong structures formed by Au–support in‐teractions were the main active species on the ceria surface. The Raman and H2‐TPR results show that the improved catalytic performance of the Au catalysts can be attributed to enhanced strong metal–support interactions and the reducibility caused by ceria doping. The formation of oxygen vacancies on the catalysts increased their activities in CO‐PROX. The synthesized Au catalysts gave excellent catalytic performances with high CO conversions （＆gt;97%） and CO2 selectivities （＆gt;50%） in the temperature range 80–150 ＆#176;C.

Preparation and CO conversion activity of ceria nanotubes by carbon nanotubes templating method

Ceria nanotubes with high CO conversion activity by means of carbon nanotubes as removable templates in the simple liquid phase process were fabricated under moderate conditions. The pristine CNTs were first pretreated by refluxing in a 30% nitric acid solution at 140 ℃ for 24 h, then dispersed in an ethanolic Ce（NO3）3.6H2O solution with ultrasonic radiation at room temperature for 1 h. Under vigorous stirring, NaOH solution was added drop by drop into the above ethanolic solution until the pH value was 10. The product was collected and repeatedly washed with ethanol and on drying at 60 ℃, the CeO2/CNT composites were obtained. Then, the as-prepared composites were heated at 450 ℃ in an air atmosphere for 30 min to remove CNTs. The ceria nanotubes were characterized by X-Ray Diffraction （XRD）, Transmission Electron Microscopy （TEM）, and X-Ray Photoelectron Spectrum （XPS）. The results showed that the ceria nanotubes were polycrystalline face-centered cubic phase and were composed of lots of dense cefia nanoparficles. The diameter of cefia nanotubes was about 40-50 nm. Catalytic activity of the product for CO oxidation was carded out at the region of 30-300 ℃ in a U-shaped quartz reactor with feeding about 0.15 g of the catalyst, which was loaded on Al2O3 carder. The inlet gas composition was 1.0% CO and 28% O2 with N2 as balance, and the rate of flow was kept at 40 ml/min. The catalytic products were analyzed by gas chromatography. The as-repared CeO2 nanotubes showed higher CO oxidation activity, which indicated that the morphology of ceria products affected the catalytic performance. The ceria nanotubes supported on Al2O3 demonstrated that conversion temperature for CO oxidation to CO2 was lower than that for bulk catalysts.

Effect of samarium doped ceria nanoparticles impregnation on the performance of anode supported SOFC with(Pr_(0.7)Ca_(0.3))_(0.9)MnO_(3-δ) cathode

Solid oxide fuel cell(SOFC) electrodes,after a high temperature sintering,may be impregnated to deposit nanoparticles within their pores to enhance the catalytic function.Samarium doped CeO2(SDC) nanoparticles were infiltrated into(Pr0.7Ca0.3)0.9MnO3-δ(PCM) cathode of anode supported SOFC cells.The cell with 2.6 mg/cm2 SDC impregnated in cathode showed the maximum power density of 580 mW/cm2 compared with 310 mW/cm2 of the cell without impregnation at 850 °C.The cells were also characterized with the impeda...

Ceria modified three-dimensionally ordered macro-porous Pt/TiO_2 catalysts for water-gas shift reaction

Three-dimensionally ordered macro-porous （3DOM） TiO2 and ceria-modified 3DOM TiO2 supported platinum catalysts were prepared with template and impregnation methods, and the resultant samples were characterized by scanning electron microscopy（SEM）, X-ray diffractometer（XRD）, high-resolution transmission electron microscopy（HRTEM） and temperature programmed reducfion（TPR） techniques. The catalytic performances over the platinum-based catalysts were investigated for water-gas shift （WGS） reaction in a wide temperature range （180-360 ℃）. The results showed that 3DOM Pt/TiO2 catalyst exhibited obviously better catalytic performance than the corresponding non macro-porous catalyst, owing to the macro-porous structure favoring mass transfer. Addition of celia into 3DOM Pt/TiO2 led to improvement of catalytic activity. TPR and HRTEM results showed that the interaction existed between ceria and titanium oxide and addition of ceria promoted the reducibility of platinum oxide and TiO2 on the interface of platinum and TiO2 particles, which contributed to high activity of the celia modified catalysts. The results indicated that ceria-modified 3DOM Pt/TiO2 was a promising candidate of fuel cell oriented WGS catalyst.

Preparation of Fine Spherical Particle Sized Ceria by Precipitation Method with Ammonium Bicarbonate

Fine spherical particle sized ceria (CeO_2) was prepared by homogeneous precipitation method with ammonium bicarbonate as precipitant. The prepared CeO_2 has the primary particle size of 10～50 nm when calcined between 400～700 ℃ analyzed by XRD and the aggregated particle size is about 300 nm measured by LASER particle sizer. SEM, TG-DTA and Zeta-potential analyzer were employed individually to study the morphology and the formation of CeO_2 product. It was found that excess NH_4NO_3 can serve as an sphericallization agent to prepare spherical CeO_2 powder by precipitation method.

Influence of Nanometric Ceria Coating on Oxidation Behavior of Chromium at 900 ℃

Isothermal and cyclic oxidation behaviors of chromium samples with and without nanometric CeO2 coating were studied at 900℃ in air. Scanning electron microscopy （SEM）, transmission electron microscopy （TEM）, and high-resolution electron microscopy （HREM） were used to examine the morphology and microstructure of the oxide film. It was found that ceria coating greatly improved the oxidation resistance of Cr both in isothermal and cyclic oxidizing experiments. Acoustic emission （AE） technique was used in situ to monitor the cracking and spalling of oxide film, and AE signals were analyzed in time-domain and number-domain according to related oxide fracture model. Laser Raman spectrometer was also used to study the stress of oxide film formed on Cr with and without ceria. The improvement in oxidation resistance of chromium is believed mainly due to that ceria greatly reduced the growth speed and grain size of Cr2O3. This fine grained Cr2O3 oxide film might have better high temperature plasticity and could relieve parts of the compressive stress by means of creeping and maintained ridge character and relatively lower level of internal stress. Meanwhile, ceria application reduced the size and number of interfacial defects, remarkably enhanced the adhesive property of Cr2O3 oxide scale formed on Cr substrate.

Research on Calcium Doped Ceria Used in Intermediate-Temperature SOFCs Anodes

As a mixed ion-electronic conductor, doped ceria, especially rare earth doped ceria, were used as anodes or components of anodes in SOFCs. In this work, calcium doped ceria （CCO） was synthesized to be used in intermediate-temperature SOFCs （IT-SOFCs） anodes in order to reduce the cost of anode-supported SOFCs. Electrical conductivity of 20% calcium doped ceria （20CCO） reached 0.209 S·cm^-1 in hydrogen at 850 ℃, and 0.041 S·cm^-1 in air at 800℃, which is about 0.04 S·cm^-1 lower than that of conventional samaria-doped ceria （0.079 S·cm^-1）. Electrochemical performance of Ni-20CCO cermet as anode was investigated using a fuel cell with 35μm-thick SDC electrolyte and Sm0.5Sr0.5 Co-SDC cathode. Maximum power density was 623 mW·cm^-2 under humidified （3% H2O） hydrogen at 650 ℃, inferring high catalytic activity of the Ni-20CCO anode.

Redox behavior of gold supported on ceria and ceria-zirconia based catalysts

A series of gold-based catalysts were prepared by deposition precipitation or incipient wetness impregnation on CexZ1-xO2 solid solutions （0.28≤x≤1.00）. The morphological and structural characterization of these catalysts were carried out with X-ray diffraction, trans- mission electron microscopy （TEM） analysis and physical adsorption technique, and their redox properties were studied by temperature programmed reduction using both H2 and CO as probe molecules. Two cycles of oxidation/reduction were carried out in order to evaluate the effects of redox aging and gold sintering on the oxygen exchange capability. As observed with other noble metals, gold enhanced and promoted the ceria reduction at lower temperatures. Reduction by CO was shown to be dependent on the fine dispersion of gold and to be nega- tively affected by the ageing process more than reduction with hydrogen. This might have implications in reactions like water gas shift and CO-PROX which involve CO as a main reactant.