LaCoO_(3)钙钛矿型催化剂的制备及其光催化降解盐酸四环素的研究

以硝酸钴、硝酸镧及柠檬酸为原料,采用水热合成法制备4种不同物质的量的比的钙钛矿型催化剂LaCoO_(3)。利用XRD、SEM、TEM、FT-IR、XPS、H_(2)-TPR等表征手段对合成的钙钛矿型催化剂LaCoO_(3)进行物化性质表征,并以盐酸四环素(TCHC)为目标降解物,在可见光照射下进行光催化降解反应,并分析光催化降解机理。结果表明,4种催化剂对TCHC的降解率均达到80%以上,在20℃下可见光照射1 h后,n[La(NO_(3))_(3)]∶n[Co(NO_(3))_(2)]∶n(柠檬酸)=1∶1∶6的LaCoO_(3)催化剂对TCHC的降解效果最好,降解率达到89.29%。

A robust fluorine-containing ceramic cathode for direct CO_(2) electrolysis in solid oxide electrolysis cells

Stro ntium-doped lanthanum ferrite(LSF)is a potential ceramic cathode for direct CO_(2) electrolysis in solid oxide electrolysis cells(SOECs),but its application is limited by insufficient catalytic activity and stability in CO_(2)-containing atmospheres.Herein,a novel strategy is proposed to enhance the electrolytic performance as well as chemical stability,achieved by doping F into the O-site of the perovskite LSF.Doping F does not change the phase structure but reduces the cell volume and improves the chemical stability in a CO_(2)-rich atmosphere.Importantly,F doping favors oxygen vacancy formation,increases oxygen vacancy concentration,and enhances the CO_(2) adsorption capability.Meanwhile,doping with F greatly improves the kinetics of the CO_(2) reduction reaction.For example,kchem increases by 78%from3.49×10^(-4) cm s^(-1) to 6.24×10^(-4) cm s^(-1),and Dchem doubles from 4.68×10^(-5) cm^(2) s^(-1) to 9.45×10^(-5)cm^(2) s^(-1).Consequently,doping F significantly increases the electrochemical performance,such as reducing R_(p) by 52.2%from 0.226Ωcm^(2) to 0.108Ωcm^(2) at 800℃.As a result,the single cell with the Fcontaining cathode exhibits an extremely high current density of 2.58 A cm^(-2) at 800℃and 1.5 V,as well as excellent durability over 200 h for direct CO_(2) electrolysis in SOECs.

微波固相反应合成La_(1-x)Sr_xCoO_3阴极材料的研究

以碳酸盐或氧化物为原料,采用微波固相反应合成技术成功地合成了纯钙钛矿结构的La1-xSrCoO3(LSC,x=0.10～0.50)粉体。研究表明:La2O3和SICO3是2.45 GHz微波透明材料,而Co3O4则具有很强的微波偶合吸收能力;La2O3,SrCO3,Co3O4混合料中SrCO3含量对混合物的微波吸收行为以及LSC的合成条件有很大影响。与传统的固相反应合成法相比,微波固相反应合成法的反应合成时间大大缩短,在输出功率700～800 W条件下,反应时间≤25 min,这归因于反应物与微波的直接偶合和反应物对微波能量的高效率吸收。

钙钛矿型LaCoO3电化学储锂的形貌调制效应

采用不同方法制备了块状(Bulk)、纳米球状(NPs)及三维有序多孔(3DPF)钙钛矿型LaCoO3电极材料,并考察了材料的形貌、结构与电化学储锂之间的相关性.结果表明,不同形貌的电极材料均呈钙钛矿型晶体结构,但电化学储锂性能却表现出巨大差异:在500 mA/g的电流密度下,块状、纳米球状及三维有序多孔LaCoO3电极经350次循环后放电比容量分别为157,579和648 mA·h/g.电化学性能的迥异主要归因于所制备的纳米及多孔结构使活性材料与电解液之间的接触面积增大,反应活性位点明显增多,传质电阻降低,从而使电子传输和Li离子的嵌入/脱嵌过程得到显著改善.

多级孔La_(1-x)Sr_xCoO_3制备及其催化氧化甲烷性能

采用溶胶凝胶+水热法制备多级孔La_(1-x)Sr_xCoO_3(x=0,0.1,0.2,0.3)催化剂,通过XRD、BET和SEM手段表征催化剂结构,采用固定床测试其催化氧化甲烷的活性。结果表明,溶胶凝胶+水热法制备的La_(0.9)Sr_(0.1)CoO_3大介孔含量明显增加,N_2吸附量显著提高,出现清楚的多级孔结构,催化甲烷氧化活性最好,与未水热LaCoO_3和水热LaCoO_3和未水热La_(0.9)Sr_(0.1)CoO_3催化剂相比,T_(50)分别降低115.4℃、18.6℃和35.3℃。

钐锶钴阴极/镧锶镓镁电解质界面的元素扩散

采用X射线衍射、扫描电镜及电化学方法考察了固体氧化物燃料电池钐锶钴(Sm0.5Sr0.5CoO3-δ,SSC)阴极烧结温度和时间对镧锶镓镁(La0.9Sr0.1Ga0.8Mg0.2O3-δ,LSGM)电解质的导电行为和电解质/阴极界面电化学性质的影响.结果表明,当SSC阴极的烧结温度由1173K升高到1323K时,LSGM/SSC界面形成了LaSrGaO4和LaSrGa3O7杂相;当烧结温度升高到1373K时,还形成了高电子电导率的La-Sr-Co-O复合化合物.Co元素的扩散导致LSGM电解质电子电导率升高,氧离子迁移数和电池开路电压降低.延长SSC阴极烧结时间,LSGM电解质的欧姆电阻增大,电解质氧离子迁移数和电池的开路电压降低,这是由于延长SSC烧结时间加剧了LSGM/SSC界面上高阻抗相LaSrGaO4和LaSrGa3O7的生成.阴极中大量Co元素的扩散改变了LSGM电解质内部组成与结构.

Electrochemical performance and stability of Sr-doped LaMnO_(3)-infiltrated yttria stabilized zirconia oxygen electrode for reversible solid oxide fuel cells

Porous Sr-doped lanthanum manganite–yttria stabilized zirconia(LSM–YSZ)oxygen electrode is prepared by an infiltration process for a reversible solid oxide fuel cell(RSOFC).X-ray diffraction and SEM analysis display that perovskite phase LSM submicro particles are evenly distributed in the porous YSZ matrix.Polarization curves and electrochemical impedance spectra are conducted for the RSOFC at 800 and 850C under both SOFC and SOEC modes.At 850℃,the single cell has the maximum power density of~726 mW/cm^(2)under SOFC mode,and electrolysis voltage of 1.35 V at 1 A/cm^(2)under SOEC mode.Fuel cell/water electrolysis cycle shows the cell has good performance stability during 6 cycles,which exhibits the LSM–YSZ oxygen electrode has high electrochemical performance and good stability.The results suggest that netw ork-like LSM–YSZ electrode made by infiltration process could be a promising oxygen electrode for high temperature RSOFCs.

载铂钴酸镧的制备与电化学性能

采用乙二醇还原法在钴酸镧表面上沉积铂,制备了载铂20%的载铂钴酸镧复合材料Pt-LCO/C。采用X射线粉末衍射、透射电子显微镜研究了载铂钴酸镧的结构与形貌,发现铂在钴酸镧中的分散性好,获得的铂金属颗粒仅2nm,且颗粒大小均匀。采用循环伏安法研究了载铂钴酸镧复合材料的电化学性能和对甲醇的电化学氧化行为。研究表明,载铂钴酸镧复合材料具有很好的扩散性能,具有优良的电催化氧化甲醇的性能。

纳米级钙钛矿型钴酸镧的微波合成

采用微波辅助加热法合成了纳米级钙钛矿型钴酸镧,用热分析、X粉末衍射、能谱分析、扫描电镜分析和比表面分析等对样品进行性能表征。分析结果表明:500℃能使有机物充分分解和相转变完全;经过500℃焙烧后所有的样品均含有钙钛矿相,但杂相含量较高;当氢氧化钠过量(溶液中OH-的浓度达到约2 mol·L-1)时,可获得较纯的钙钛矿型钴酸镧粉体;能谱分析表明钴的价态是以+3价为主;钴酸镧粉体粒度为18 nm,比表面积31.0 m2·g-1。

Electric properties of La_(0.8)Sr_(0.2)CoO_3 nanoceramics

The electric measurements were carried out for La0.8Sr0.2CoO3 nanoceramics by using impedance spectroscopy methods. The resistance of sample was practically independent of frequency in measurement range. Its dependence on reciprocal temperature showed quite complicated mechanism of conduction. The most striking property of investigated sample was its resistance decreasing with increasing applied polarization.

La_(0.6)Sr_(0.4)Co_(0.2)Fe_(0.8)O_(3–δ)–Sm_(0.2)Ce_(0.8)O_(1.9)复合阴极的制备及性能表征

分别采用凝胶浇注法和甘氨酸–硝酸盐法制备La0.6Sr0.4Co0.2Fe0.8O3–δ(LSCF)粉体与Sm0.2Ce0.8O1.9(SDC)粉体,随后制备出不同比例的LSCF–SDC复合阴极。用X射线衍射分析粉体的化学稳定性,用扫描电子显微镜观察复合阴极的微观结构,在500～800℃范围内测量其热膨胀系数和电导率。采用丝网印刷法将LSCF–SDC涂覆在SDC电解质片上,在1100℃烧结4h。用交流阻抗法在600～800℃范围内测量不同成分的LSCF–SDC复合阴极和SDC电解质的交流阻抗谱。结果表明:LSCF和SDC粉体具有良好的化学相容性,烧结体具有多孔结构,LSCF–SDC复合阴极与SDC电解质可形成良好的接触界面。SDC的加入在降低阴极材料的热膨胀系数的同时还保持了其本身较高的电导率,在中温范围内,电导率达到500S/cm以上。复合阴极的极化电阻随着SDC的含量增加而减小,当SDC含量为30%时,复合阴极的极化电阻最小,在700℃空气中测试得到的界面电阻为0.32Ω·cm2。

La_(0.8–x)Ba_xSr_(0.2)Co_(0.8)Fe_(0.2)O_(3–δ)阴极材料的结构与性能

采用溶胶–凝胶法制备了La0.8–xBaxSr0.2Co0.8Fe0.2O3–δ（LBSCF）阴极粉体。对LBSCF的晶体结构、材料表面的化学状态、烧结体的断面微结构及电导率进行了表征。用交流阻抗谱法在550-700℃范围测试了LBSCF-30%SDC（Sm0.2Ce0.8O1.9）复合阴极的电化学性能。结果表明：LBSCF粉体主晶相为六方晶系钙钛矿结构,存在少量的第二相。XPS结果显示,Ba2＋掺杂不影响A位离子（La3＋、Ba2＋、Sr2＋）的价态,但对B位离子的价态有不同的影响：x=0.10的样品中,钴离子以Co3＋和Co4＋混合价态存在,其余样品中以低氧化态（Co3＋和Co2＋混合价）或Co3＋价存在;铁离子以高氧化态（Fe3＋和Fe4＋）存在。在500-700℃空气气氛中,LBSCF的电导率均超过700 S/cm,在同一温度下,电导率随着Ba2＋掺杂量的增加而增大。x=0.20的样品在500℃时,电导率最大可达1.59×103 S/cm。随着Ba2＋含量增加,极化电阻减小,x=0.20时,复合阴极LBSCF-30%SDC的极化电阻最小,700℃时的极化电阻为0.20？·cm2。