La0.8Sr0.2MnO3薄膜光生伏特效应的微结构起源

研究了外延La0.8Sr0.2MnO3薄膜的光生伏特效应。实验发现，当脉冲激光从基底一侧照射时，光生电压改变符号。电子衍射微结构分析表明，La0.8Sr0.2MnO3薄膜是外延生长的基底上的，样品显示出正交取向畴的形式。薄膜表面光生电压的分布研究表明，这种异常的光生伏特效应是由于薄膜中取向微结构畴的非对称性所致，当紫外激光照射薄膜时，在La0.8Sr0.2MnO3中感生出电子空穴时，而薄膜中非对称的微结构畴会产生内建电场，引导激发的非平衡载流子运动，最终诱导出光生电压。

螯合物-凝胶法制备La0.8Sr0.2MnO3粉体

以La(NO3)3·6H2O,Sr(NO3)2和Mn(NO3)3·6H2O为起始原料,采用螯合物-凝胶法制备出La0.8Sr0.2MnO3粉体.首先在混合盐溶液中入柠檬酸形成螯合的柠檬酸盐,然后加入单体和交联剂,在引发剂和催化剂的作用下形成湿凝胶.干燥后的前驱体为无定形的,DTA和XRD测试表明晶化温度在400℃～500℃.在500℃～1 200℃范围内煅烧,颗粒尺寸由500℃时的约38 nm 长大到1 200℃时的500 nm.

Combustion Synthesis of La0.8Sr0.2MnO3 and Its Effect on HMX Thermal Decomposition

Perovskite-type La0.8Sr0.2MnO3 was prepared by stearic acid gel combustion method.The obtained powders were characterized by X-ray diffraction(XRD),Fourier transform infrared spectroscopy(FT-IR),scaning electron micrograph(SEM)and X-ray photoelectron spectroscopy(XPS)techniques.The catalytic activity of La0.8Sr0.2MnO3 was investigated on thermal decomposition of octahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine (HMX)by thermal gravity-differential scanning calorimetry(TG-DSC)techniques.The experimental results show that La0.8Sr0.2MnO3 is an effective catalyst for HMX thermal decomposition.The surface-adsorbed species such as H2O,OH - and adsorbed oxygen(Oad)could result in an advance in the onset temperature of HMX thermal decomposition.The mixture system of Mn 3+ and Mn 4+ ions and lattice oxygen could play key roles for the increase of the decomposition heat of HMX because these exothermic reactions could be catalyzed by La0.8Sr0.2MnO3 between CO and NOx(from the thermal decomposition of HMX)and the oxidation reaction of CO.According to the previous researches and our results,perovskite-type La0.8Sr0.2MnO3 may be used as a novel catalyst or modifier for nitrate ester plasticized polyether(NEPE)propellant.

Preparation and Characterization of Single-Phase Perovskite La_(0.6)Sr_(0.4)Co_(0.8)Fe_(0.2)O_(3-δ)

Single-phase perovskite La0.6Sr0.4Co0.8Fe0.2O3-δ has been successfully prepared by using citrate-EDTA complexation method at relatively low calcination temperature. The structure and thermal decomposition process of the complex precursor have been investigated by means of differential scanning calorimetry-thermal gravimetric analysis （DSC/TGA）, X-ray diffraction （XRD）, and Fourier transform infrared spectroscopic （FT-IR） measurements. The precursor decomposed completely and started to form perovskite-type oxide above 420 ℃ according to the differential scanning calorimetry （DSC） and thermal gravimetric analysis （TGA） results. Single-phase perovskite La0.6Sr0.4Co0.8Fe0.2O3-δ obtained has been confirmed from the XRD pattern, and no peak of SrCO3 was found by XRD of the oxides synthesized at a relatively low temperature of 800℃. The reducibility of La0.6Sr0.4Co0.8Fe0.2O3-δ was also characterized by the temperature programmed reduction （TPR） technique. Disk shaped dense La0.6Sr0.4Co0.8Fe0.2O3-δ membrane was prepared by the isostatical pressing method. The oxygen flux rate of dense La0.6Sr0.4Co0.8Fe0.2O3-δ membrane was （2.8-18）× 10^-8 mol/（cm^2.s） in the temperature range of 800-1000 ℃.

Catalytic Oxidation of NO over La_(0.8)Sr_(0.2)MnO_3 Perovskite

Catalytic oxidation of NO by O2 over La0.8Sr0.2MnO3 was tested in a tubular reactor.The reaction temperature ranged from 373 to 473 K,space time from 0.090 to 0.720 s,inlet NO concentration from 300 to 2000μL/L, and O2 volume fraction from 3%to 9%.The steady-state conversion of NO was increased significantly with increasing reaction temperature and the space time,slightly with increasing the O2 concentration but decreased with increasing the inlet NO concentration at a lower temperature.Under the conditions of 0.720 s space time,500μL/L NO concentration, 5%O2 volume fraction and 473 K,NO conversion reached 90%.A kinetic model including a network of 12 elementary reactions with the desorption of NO2 as the rate-limiting step is established and fits the experimental data well.The activation energy of NO2 desorption from the catalyst surface is determined to be 101 kJ/mol.

Partial Oxidation of Methane Over the Perovskite Oxides

Ba0.5Sr0.5Co0.8Fe0.2O3-delta and Ba0.5Sr0.5Co0.8Ti0.2O3-delta oxides were synthesized by a combined EDTA-citrate complexing method. The catalytic behavior of these two oxides with the perovskite structure was studied during the reaction of methane oxidation. The pre-treatment with methane has different effect on the catalytic activities of both the oxides. The methane pre-treatment has not resulted in the change of the catalytic activity of BSCFO owing to its excellent reversibility of the perovskite structure resulting from the excellent synergistic interaction between Co and Fe in the oxide. However, the substitution with Ti on Fe-site in the lattice makes the methane pre-treatment have an obvious influence on the activity of the formed BSCTO oxide.

Combustion Synthesis,Character and Electromagnetic Properties of Nano-Sized La_(0.8)Sr_(0.2)FeO_3 Perovskite

The perovskite-type nanocrystal La0.8Sr0.2FeO3 was prepared using a sol-gel auto-combustion method with citric acid as the chelating agent. The metal ions coordination compound, obtained from nitrate and citrate, underwent an auto-combustion process and voluminous ashes formed when calcining the complex in the air. Some analytical methods, which consisted of FT-IR, XRD, TEM and wave-guide, were used to characterize the gel and the final products. It was shown that metal ions and carboxyl were combined to form a homogeneous organic complex base salts in the process of gelation. The nanocrystalline had dielectric loss in the microwave frequency range of measurement.

具有LSM致密扩散障碍层的片式极限电流型氧传感器

采用了一种新的有效工艺,制备出了以8mol％Y2O3稳定的ZrO2为固体电解质基体材料,以La0.8Sr0.2MnO3混合导体材料为致密扩散障碍层的极限电流型氧传感器,避免了YSZ和LSM两种材料在烧结时收缩率不匹配的问题,且能够很好给出全范围空燃比的极限电流.该传感器与以往的极限电流型传感器相比具有结构简单,响应更快,工作稳定,成本低廉等优点,有很好的应用前景.

负载型La_(0.8)Sr(0.2)MnO_3催化剂对油烟燃烧的催化作用

采用浸渍法制备La0 8Sr0 2 MnO3负载型纳米催化剂 ,用X 射线衍射仪 (XRD) ,扫描电镜 (SEM)对催化剂负载层的表面形态、晶相结构和粒径大小进行了表征 .并考察了催化剂对油烟低温燃烧的催化活性 ,以及不同负载量和不同浸渍时间对催化活性的影响 .结果显示 ,催化剂经 70 0℃焙烧后形成了钙钛矿La0 8Sr0 2 MnO3纳米晶粒 ,催化剂对油烟催化燃烧具有较好的低温高活性 .

钙钛矿型La_0.8Sr_0.2FeO_3中的晶格氧用于甲烷选择氧化制取合成气

用自燃烧法制备了钙钛矿型La0 8Sr0 2 FeO3 催化剂 .用H2 TPR考察了催化剂表面的氧消耗过程 ,用程序升温表面反应(TPSR)研究了甲烷与催化剂表面氧物种的反应 ,用在线质谱脉冲反应和甲烷 /氧切换反应研究了催化剂的晶格氧选择氧化甲烷制合成气 .结果表明 ,催化剂上存在两种氧物种 ,无气相氧存在时 ,强氧化性氧物种首先将甲烷氧化为CO2 和H2 O ;而后提供的氧化性较弱的晶格氧具有良好的甲烷部分氧化选择性 ,可将甲烷氧化为合成气CO和H2 (选择性可达 95 %以上 ) .在 90 0℃下的CH4/O2 切换反应结果表明 ,甲烷能与La0 8Sr0 2 FeO3 中的晶格氧反应选择性地生成CO和H2 ,失去晶格氧的La0 8 Sr0 2 FeO3 能与气相氧反应恢复其晶格氧 .在合适的反应条件下 ,用La0 8Sr0 2 FeO3 催化剂的晶格氧代替分子氧按Redox模式实现甲烷选择氧化制合成气是可能的 .

La_(0.8)Sr_(0.2)Mn_(1-y)Fe_yO_3微波电磁特性与损耗机制

用溶胶-凝胶法制备La0.8Sr0.2Mn1-yFeyO3（y=0．10，0．12，0．14，0．16）样品，测试并分析该样品在2～18GHz微波频率范围的复介电常数、复磁导率、损耗角正切及微波吸收系数与频率的关系，发现y=0．12，0．14时吸波的效果最好。样品厚度为2mm、y为0．12时，有2个吸收峰，吸收峰值最高达22dB，10dB以上吸收频带宽度达6．2GHz；厚度2．21mm样品8dB以上的吸收频宽达8．5GHz。初步探讨了该材料的电磁损耗机理，电磁特性参数在频率为12．4GHz位置发生阶跃式变化，在小于12．4GHz频率范围以介电损耗为主，在大于12．4GHz频率范围以磁损耗为主，这与Fe对Mn^3＋-O-Mn^4＋之间的影响有关。电导率测试表明在室温范围内电导在半导体范围内，有利于降低微波在氧化物表面的反射率。

钙钛矿型La_(0.8)Sr_(0.2)MnO_3催化剂对氯苯催化燃烧的性能研究

采用共沉淀法制备了钙钛矿型La0.8Sr0.2MnO3催化剂,用XRD,SEM,BET对催化剂进行了表征,考察了催化剂对氯苯的催化燃烧性能.结果表明：La0.8Sr0.2MnO3催化剂呈现钙钛矿晶型,催化剂具有较好的分散性,颗粒尺寸约为60 nm,对氯苯有较好的催化燃烧性能.在氯苯浓度为800～1 600 mg/m^3,空速（GHSV）为1 000～4 000 h^-1的情况下,反应温度高于350 ℃时,氯苯几乎能完全去除.稳定性实验结果表明：该催化剂在氯苯浓度为800 mg/m^3,空速（GHSV）为1 000 h^-1,反应温度为410 ℃的条件下,经历了100 h连续催化燃烧后,没有出现明显失活,说明La0.8Sr0.2MnO3催化剂对含氯有机物具有较强的抗毒性.

蜂窝陶瓷型La_(0.8)Sr_(0.2)MnO_3催化剂VOCs催化燃烧反应活性

以堇青石(CH)为第一载体,六铝酸盐(HA)为第二载体(washcoat),La0.8Sr0.2MnO3(LSM)为活性物种,制备了LSM/HA/CH催化剂.XRD表征发现,LSM具有完善的钙钛矿晶型.SEM观察表明,活性物种在涂层表面分散均匀.通过对苯、甲苯、二甲苯、乙酸乙酯、丙酮和乙醇六种有机物的性能测试,发现LSM/HA/CH对上述六种有机物均具有很好的催化活性,特别是对乙酸乙酯等含氧有机物表现出更好的燃烧性能,在10000 h-1空速下,反应温度为240℃时即可将含氧有机物完全燃烧.

金属丝网型La_(0．8)Sr_(0．2)MnO_3催化剂的制备及其表征

以316L不锈钢丝网为基材,利用电泳沉积技术对丝网表面进行改性,考察了添加剂浓度、电压加压方式、热处理温度对铝粉在丝网表面包覆效果的影响,制备出表面规整、高粘结强度的Al_2O_3/Al载体膜,在30min超声振荡后,载体膜脱落率仅为0.5wt%;结合表面浸涂技术,在丝网上涂覆纳米La_(0.8)Sr_(0.2)MnO_3,通过SEM、XRD、BET等手段对催化剂进行表征,发现丝网表面催化剂负载均匀,比表面积达到119.4m^2/g,在30min超声振荡后,脱落率为5.0wt%.催化燃烧性能测试表明,La_(0.8)Sr_(0.2)MnO_3在不锈钢丝网上有较好的活性,高空速、高浓度的甲苯在400℃基本能被完全燃烧.

La_(0.6)Sr_(0.4)Co_(0.8)Fe_(0.2)O_3钙钛矿复合氧化物的柠檬酸盐法合成与导电性能

采用柠檬酸盐法合成出La0.6Sr0.4Co0.8Fe0.2O3钙钛矿复合氧化物超细粉料,考查了各种影响溶胶与凝胶的形成以及合成粉料晶体结构与颗粒形态的因素,并确定了最佳的合成条件。研究了烧成温度对La0.6Sr0.4Co0.8Fe0.2O3电导率的影响,发现1200℃是最合适的烧成温度。研究结果表明,在室温～900℃范围内,样品的电导率在600℃附近出现峰值(～103S·cm-1),在低温段样品的导电行为符合小极化子导电机制,不同烧成温度的样品的导电活化能基本一致(5.31～5.79kJ·mol-1)。与常规固相合成法相比,柠檬酸盐法合成的La0.6Sr0.4Co0.8Fe0.2O3具有更高的烧结活性和电导率。

溶胶-凝胶法制备La_(0．8)Sr_(0．2)CoO_3纳米材料及其气敏性能的研究

以La(NO_3)_3·6H_2O、Sr(NO_3)_2、Co(NO_3)_2·6H_2O为原料,用EDTA络合溶胶-凝胶法制备La_(0.8)Sr_(0.2)CoO_3凝胶,在700℃、800℃、900℃煅烧,制得La_(0.8)Sr_(0.2)CoO_3粉体。用DTA、FT-IR、XRD、SEM等手段对制备过程、热分解机理及粉体的性能进行了研究。在700℃焙烧2 h得到La_(0.8)Sr_(0.2)CoO_3纯相纳米粉,颗粒呈球形。选取700℃焙烧2 h的La_(0.8)Sr_(0.2)CoO_3粉体制成管状传感器,进行NO_2敏感性能测试,探讨了相同NO_2浓度下,传感器敏感信号与温度的关系。结果表明:纳米La_(0.8)Sr_(0.2)CoO_3粉体在450℃时对NO_2的敏感信号最大,输出的电动势信号与NO_2浓度之间呈线性关系。

整体构件型La_(0.8)Sr_(0.2)MnO_3催化剂的制备和催化燃烧特性

为了解不同整体构件钙钛矿催化剂的VOCs催化燃烧特性,以不锈钢316L丝网和堇青石蜂窝陶瓷为基材,通过电泳沉积和浸涂技术在基材表面均匀涂覆γ-Al2O3粘合层,再在涂层表面负载钙钛矿型2.0%(wt)的La0.8Sr0.2MnO3活性组分。SEM表征发现100nm左右的La0.8Sr0.2MnO3颗粒可以均匀、牢固地分散在不锈钢丝网和蜂窝陶瓷表面,经过550℃焙烧后无龟裂现象。超声振荡30min后,活性组分损失率均小于5.0%(wt)。甲苯催化燃烧测试表明,金属丝网型、蜂窝陶瓷型和颗粒型La0.8Sr0.2MnO3催化剂表现出相似的催化性能,但金属丝网具有更好的传质效果和热响应速率,更适合处理高空速、温度和浓度波动较大的有机废气。

空气等离子喷涂板式SOFC连接体保护涂层的性能(英文)

在中温平板型固体氧化物燃料电池(ITSOFC)设计中,可以采用金属作为连接材料。Fe-16Cr合金是较为理想的金属连接材料,它存在的主要问题是连接体阴极侧表面的高温氧化和腐蚀,会导致电池性能的迅速降低。本研究采用空气等离子喷涂的方法喷涂了La0.8Sr0.2MnO3-σ(LSM)钙钛矿型保护涂层在金属连接板的表面,并讨论了主要过程参数及其作用效果。研究发现,喷涂后热处理是降低涂层孔隙率的有效方法,经喷涂-热处理后,涂层的孔隙率可降至1%以下。等离子喷涂LSM保护涂层后,Fe-16Cr合金的耐高温氧化性能明显提高,氧化速率降低了76%。

中温复合固体电解质SDC-LSGM的制备和性能

采用甘氨酸-硝酸盐法分别制备了Ce0.85Sm0.15O2-δ（SDC）与La0．9Sr0.1Ga0.8Mg0.2O3-δ（LSGM）两种电解质材料，并用固相混合法将两种材料按不同质量比（SDC与LSGM的质量比分别为9：1，8：2，5：5）混合制备复合电解质材料．采用交流阻抗技术对样品的电学性能进行研究．实验结果表明，SDC与LSGM的质量比为9：1（SL91）时，样品具有较高的电导率，在350～800℃温度范围内其电导率均比SDC的高．以复合电解质为支撑体，以Sm0.5Sr0.5CoO3为阴极、NiO／SDC为阳极制成单电池，测试结果显示，在800℃时以SL91为电解质的单电池的最大输出功率密度为0．25W／cm^2，最大电流密度为1．06A／cm^2．在电池的工作温度区间（600～800℃）内以复合材料为电解质的单电池的开路电压比以SDC为电解质的高．

大比表面积La_(0.8)Sr_(0.2)CoO_3的制备及甲烷催化燃烧性能研究

采用丙氨酸溶液燃烧法、丙烯酰胺-丙氨酸法、丙烯酰胺-氨基乙酸法和环氧丙烷法制备了大比表面积钙钛矿型La0.8Sr0.2CoO3复合氧化物,研究了制备方法对复合氧化物结构和性能的影响,考察了其CH4催化燃烧活性,并运用XRD,FI-TR,BET,TPR等进行了表征。结果表明,制备方法对复合氧化物的性能有较大的影响,其中以丙氨酸溶液燃烧法制备的复合氧化物的比表面积较大(20.31 m2.g-1)和催化燃烧活性较好(T50和T100分别为470和550℃)。表征结果表明,该法所制复合氧化物的平均晶粒度较小,表面和氧空穴处的化学吸附氧更容易移动,表观活化能较低,这均有利于催化活性的提高。