AgI(α-Fe2O3)复合离子导体相转变温度相互影响的研究

通过测量AgI(α-Fe₂O₃)复合离子导体的直流和交流电导率,发现α-Fe₂O₃的Morin转变温度随着AgI含量的增加而降低,电导率测量的结果与磁化率测量和M?ssbauer谱测量结果定性的符合。α-Fe₂O₃也使AgI的α→β相转变温度显著下降。结果表明复合离子导体二相材料各自存在的相转变温度彼此产生影响。 关键词：     

分散第二相γ-Al2O3对β-Li2SO4离子导电性的影响

本文研究了分散第二相γ-Al₂O₃对β-Li₂SO₄离子导电性的影响。β-Li₂SO₄(γ-Al₂O₃)的电导率随γ-Al₂O₃含量的增加而提高,到γ-Al₂O₃为50mol％时达到极大。当温度为253℃时,β-Li₂SO< 关键词：     

含碳Na-β(β")-Al2O3的导电性能

本文研究了含碳(1—10)wt％的Na-β(β″)-Al₂O₃,指出含碳6wt％以下仍是良好的快离子导体,而且由于混入了碳,离子电导率比纯的Na-β(β″)-Al₂O₃提高一到两个数量级。样品的体电阻,晶界电阻,双电层电容及其漏电阻等参量都随含碳量的不同而变化。文中详细地讨论了碳的影响。在-40℃到80℃温度范围测量了纯样品与含碳样品的电导温度特性,指出含碳的Na-β(β″)-Al₂O₃是做双电层电容器的良好材料。 关键词：     

包钴对α-Fe2O3粉末Morin相变的影响

用穆斯堡尔谱,磁性测量,中子衍射和X射线光电子能谱(XPS)等方法对纯的和包钴α-Fe₂O₃粉末Morin相变的影响以及有关性质进行了研究,发现包钴会使α-Fe₂O₃的Morin温度降低,相变温度的区域扩大,矫顽力明显增大,3d能带变化,假设包钴可使α-Fe₂O₃的单离子各向异性常数K_FS下降来解释上述实验结果。 关键词：     

基于拉曼光谱成像技术的铁质文物锈蚀产物定量模型研究

铁质文物是我国文化遗产的重要组成部分。由于化学性质较为活泼,铁质文物易发生腐蚀劣化。锈蚀产物对铁质文物的稳定性有较大影响,因此判断铁质文物锈蚀产物的组成特征,对于铁质文物稳定性评估具有重要意义。以赤铁矿(α-Fe₂O₃),磁铁矿(Fe₃O₄),四方纤铁矿(β-FeOOH)三种铁质文物的锈蚀产物为研究对象,采用拉曼光谱成像结合主成分回归法(PCR)和偏最小二乘法(PLS),同时结合多种预处理方法,构建了两组二元混合锈蚀(α-Fe₂O₃+Fe₃O₄, α-Fe₂O₃+β-FeOOH)的定量模型。结果表明,对于α-Fe₂O₃+Fe₃O₄二元体系,PCR和PLS算法构建模型的定量效果基本一致,α-Fe₂O₃和Fe₃O_...     

Ti和蓝宝石的界面反应

在超高真空中用电子束蒸发在抛光的(1102)取向的蓝宝石(α-Al₂O₃)衬底上蒸镀500nm的Ti膜,在恒温炉中退火,然后用XRD(包括一般的和小角度的X射线衍射),AES(俄歇电子谱,包括深度剖面分布和通过界面的谱形分析)和SIMS(二次离子质谱)等表面分析技术详细研究了从室温至850℃,Ti与α-Al₂O₃的固相界面反应.结果表明室温及300℃,30min退火已有反应,Al₂O_{3< 关键词：}     

AgI(α-Fe_2O_3)复合离子导体相转变温度相互影响的研究

通过测量AgI(α-Fe_2O_3)复合离子导体的直流和交流电导率,发现α-Fe_2O_3的Morin转变温度随着AgI含量的增加而降低,电导率测量的结果与磁化率测量和Mossbauer谱测量结果定性的符合。α-Fe_2O_3也使AgI的α→β相转变温度显著下降。结果表明复合离子导体二相材料各自存在的相转变温度彼此产生影响。     

α-Al2O3单晶的热释光和光释光特性

研究了纯α-Al₂O₃单晶的热释光发光曲线和三维发光谱，以及光释光衰变曲线，对它们的发光机理和剂量学特性进行了分析和讨论.实验观察到α-Al₂O₃单晶β射线照射后立即测量的热释光发光曲线，有峰温为76℃和207℃两个发光峰.经γ射线照射数小时后测量的三维发光谱，只有峰温207℃波长为416 nm发光峰，它与α-Al₂O₃:C晶体的发光波长基本相同，是受热激发到导带的电子与F< 关键词： 2O₃')" href="#">α-Al₂O₃ 三维发光谱 TL/OSL剂量响应     

α-Al2O3:C晶体的热释光和光释光特性

以高纯α-Al₂O₃和石墨为原料,采用温梯法生长了α-Al₂O₃：C晶体,使用Ris TL/OSL-DA-15型热释光和光释光仪研究了其热释光和光释光特性.α-Al₂O₃：C晶体在462K附近有单一热释光峰,发射波长位于410nm.随着辐照剂量的增加,热释光强度逐渐增强,462K的热释光特征峰位置保持不变.α-Al₂O₃：C晶体的 关键词： 2O₃：C')" href="#">α-Al₂O₃：C 热释光 光释光     

FeOx上AsH3吸附净化的密度泛函研究

基于密度泛函理论研究了AsH₃和O₂分子在α-Fe₂O₃(001)表面和FeO(100)表面的吸附及共吸附性质.结果表明：AsH₃和O₂分子在α-Fe₂O₃(001)表面最稳定的吸附构型都是Hollow吸附位点. AsH₃分子在FeO(100)表面最稳定的吸附位点为Top O吸附位点. O₂分子在FeO(100)表面最稳定的吸附位点为Hollow吸附位点. O₂分子在α-Fe₂O₃(001)和FeO(100)表面吸附后均被活化从而促进AsH₃分子的催化氧化. AsH₃分子在α-Fe₂O₃(001)表面最小的吸附能为-0.7991 eV,在FeO(100)表面最小的吸附能为-0.9117 eV.吸附值数据表明AsH     

Electrical and structural modifications of TZP

The stability range of the metastable tetragonal phase in the ZrO₂-Y₂O₃-TiO₂ and ZrO₂-Y₂O₃-Fe₂O₃ systems was investigated by XRD at room temperature. The solid solubility limit of TiO₂ was found to be as high as 20 mol%, while that of Fe₂O₃ does not exceed 0.8 mol%. Impedance measurements show a decrease of the total conductivity, bulk conductivity and grain boundary conductivity as a result of the TiO₂ and Fe₂O₃ addition. Dc-polarization measurements using the Hebb-Wagner technique were applied to determine the partial hole and electron conductivities of TiO₂ and Fe₂O₃ co-doped samples. These show a slightly higher hole conductivity as compared to pure TZP and a remarkably higher electron conductivity as compared to TiO₂ or Fe₂O₃ doped samples. The Hebb-Wagner curves are interpreted according to a model which considers the addition of mixed valence ions. The influence of the minority charge carriers on the charge-transfer resistance is investigated. Paper presented at the 4th Euroconference on Solid State Ionics, Renvyle, Galway, Ireland, Sept. 23–19, 1997.     

Synthesis and characterization of hybrid nanocomposites of polypyrrole filled with iron oxide nanoparticles

Hybrid polypyrrole (PPy)/α-Fe₂O₃ nanocomposite films were fabricated by spin coating on a glass substrate. X-Ray diffraction analysis revealed the crystalline structure of α-Fe₂O₃ nanostructures and the nanocomposites. The broad PPy peak weakened in intensity as the α-Fe₂O₃ content increased in PPy/α-Fe₂O₃ nanocomposites. Characteristic Fourier-transform IR peaks for pure PPy shifted to higher wavenumbers on addition of α-Fe₂O₃ to PPy/α-Fe₂O₃ nanocomposites. This can be attributed to better conjugation and interactions between PPy and α-Fe₂O₃ nanoparticles. Field-emission scanning electron microscopy, transmission electron microscopy, and atomic force microscopy images of the nanocomposites reveal a uniform distribution of α-Fe₂O₃ nanoparticles in the PPy matrix. UV-vis absorption spectroscopy revealed a blue shift from λ_max= 441 nm for PPy to λ_max= 392 nm for PPy/α-Fe₂O₃, reflecting strong interactions between PPy and α-Fe₂O₃ nanoparticles. The room-temperature dc electrical conductivity increased from 4.33×10⁻⁹ to 1.81×10⁻⁸ S/cm as the α-Fe₂O₃ nanoparticle content increased from 10 to 50 wt.% in PPy/α-Fe₂O₃ nanocomposites.     

Cu-doped flower-like hematite nanostructures for efficient water splitting applications

This study reports the successful preparation of Cu-doped hematite (α-Fe₂O₃) flower-like nanostructures with different Cu concentrations on FTO glass substrates using a facile hydrothermal method. The Cu-doped α-Fe₂O₃ flower-like nanostructure combines the advantage of p-type doping with the feature of a flower-like architecture. The prepared nanostructure film was applied as a photocathode in a photoelectrochemical (PEC) water splitting experiment and achieved a significantly improved photocurrent density of −5.34 mA cm⁻² at −0.6 V vs. reversible hydrogen electrode (RHE) for 1 mol% Cu doping. The obtained photocurrent is about 4.85 times higher than that of the pure α-Fe₂O₃ based photoelectrode. The incorporation of Cu into α-Fe₂O₃ results in a dramatic enhancement in the water splitting performance. The enhancement is gained through an improvement in light harvesting and charge carrier separation. The copper-modified α-Fe₂O₃ sample also exhibited an up shift in the conduction band edge potential, which is energetically favorable for the water reduction reaction. This result demonstrated high performance PEC water splitting as a potential route for the production of hydrogen gas using a single Cu-doped α-Fe₂O₃ photoelectrode without the need for other catalysts and hybrid structures.     

Fe-C—Sb合金中液态急冷获得的ε相的分解

本工作用示差热分析法,淬火样品X射线衍射法和Guinier-Lenn透射式高温单色聚焦粉末照相法研究了Fe-C-Sb合金中液态急冷获得的ε相的高温分解过程,实验结果指出,ε相在125℃开始分解,首先分解成ε-Fe₂C,而后在450℃分解成α-Fe,并析出Sb和Fe₃Sb₂,还保留有ε-Fe₂C;在550℃以后ε-Fe₂C转变成Fe₃C,并在770℃时发生Fe的α→γ转变,在800℃时主要组成相为:γFe,Sb,Fe₃C(Fe₃Sb分解);在冷却过程中750℃发生Fe的γ→α转变,冷至室温时的主要组成相是:αFe,Fe₃C,Sb,Fe₃Sb₂。 关键词：     

Study of low temperature ferromagnetism,surface paramagnetism and exchange bias effect in α-Fe1.4Ga0.6O3 oxide

The compound α-Fe_1.4Ga_0.6O₃ has been prepared by mechanical alloying of α-Fe₂O₃ and β-Ga₂O₃ and subsequent heating under vacuum condition. X-ray diffraction, Raman and Mössbauer spectroscopy confirmed stabilization of the material in rhombohedral phase. A remarkable change in the magnetic ordering has been found by substitution of non-magnetic Ga atoms in α-Fe₂O₃. The ferromagnetism in α-Fe_1.4Ga_0.6O₃ is found to be more soft and enhanced in comparison to α-Fe₂O₃. The samples also exhibited features of exchange bias, low temperature surface paramagnetism, and suppression of Morin transition. Nano-sized grains and alloying process of the material affected these features up to certain extent. The results of magnetic measurements are highly interesting for designing metal doped α-Fe₂O₃ based ferromagnet for room temperature applications.     

Mössbauer study of α-Fe2O3 fine particles coated with cobalt and pyridine

The properties of α-Fe₂O₃ line particles coated with cobalt and pyridine have been investigated by means of magnetic measurements and Mössbauer spectra. The Morin transition temperature, T_M for Co-coated α-Fe₂O₃ decreases and that for pyridine-coated α-Fe₂O₃ increases, comparing with the pure α-Fe₂O₃. The angles between (111) axis and the spin of iron ions for these samples have been calculated from the quadrupole splitting.     

Mössbauer spectroscopic properties of tin-doped iron oxides

The ⁵⁷Fe Mössbauer spectra recorded in situ from tin-doped Fe₃O₄ at elevated temperature in vacuo shows the Curie temperature to decrease with increasing concentrations of the dopant. Thermal treatment under oxidising conditions results in the initial formation of tin-doped γ-Fe₂O₃ which subsequently undergoes a phase transformation to tin-doped α-Fe₂O₃. ⁵⁷Fe Mössbauer spectroscopy at elevated temperatures shows the Néel temperature for tin-doped γ-Fe₂O₃ to be lower than that of pure γ-Fe₂O₃. The ¹¹⁹Sn Mössbauer spectra recorded from all the tin-doped iron oxides show the presence of a hyperfine magnetic field at the Sn⁴⁺ site which is more complex in the spectra recorded from tin-doped γ-Fe₂O₃ and α-Fe₂O₃.     

Ionic conductivity in nanoporous composites SiO2/AgI

In this work, porous silicate glasses were mixed with an ionic conductor AgI to obtain SiO₂/AgI composites. The porous glasses were either commercial Vycor glass (VPG) from Corning or synthesised from phase separated SiO₂–B₂O₃–Na₂O glasses. Depending upon the elaboration process, glasses with different pore sizes were obtained (4, 20 and 40 nm). Composites comprising different amounts of AgI were prepared by heating above the melting point of AgI. SEM characterisation of the obtained composites indicated that heat treatment induced an increase in the pore sizes. The conductivity of the composites was measured by impedance spectroscopy. The maximum conductivity, twice as large as that of pure AgI, was obtained for the 50AgI/50VPG composite, i.e. that comprising the glasses with the smallest pores.     

Dye-sensitized solar cells with 3D flower-like α-Fe<Subscript>2</Subscript>O<Subscript>3</Subscript>-decorated reduced graphenes oxide as photoanodes

For the first time, we report a one-step fabrication of an environment-friendly approach to synthesize flower-like α-Fe₂O₃ hierarchical nanoparticles (NPs)/reduced graphene oxide (RGO) hybrids by combining the graphene oxide (GO) with the growth of α-Fe₂O₃ NPs. The GO sheet which possesses the functional group, such as hydroxyl (–OH) and carbonyl groups (–OOH), can be easily incorporated with the petal of the flower-like α-Fe₂O₃ in ethanol and water solution through a solvothermal process, during which GO is reduced to RGO without the addition of any strong reducing agent or requiring any post-high-temperature annealing process. The as-prepared samples are loose and porous with flower-like structure, and the RGO hybrids were wrapped up uniformly on the sheet of α-Fe₂O₃ NPs. To demonstrate the potential applications, we have fabricated dye-sensitized solar cells (DSSCs) from the as-synthesized hierarchical flower-like α-Fe₂O₃/RGO and investigated it for the photoanode of DSSCs. Results show that the hierarchical α-Fe₂O₃/RGO solar cell exhibits improved performances in comparison with the free α-Fe₂O₃ NPs. The enhancement of photovoltaic properties is attributed to the unique porous nature and good conductivity which allow more efficient diffusion of I^? ions and facilitate the transfer of electron in the network.