Fabrication of Gd_(2)O_(3)-doped CeO_(2)thin films through DC reactive sputtering and their application in solid oxide fuel cells

Physical vapor deposition(PVD)can be used to produce high-quality Gd_(2)O_(3)-doped CeO2(GDC)films.Among various PVD methods,reactive sputtering provides unique benefits,such as high deposition rates and easy upscaling for industrial applications.GDC thin films were successfully fabricated through reactive sputtering using a Gd_(0.2)Ce_(0.8)(at%)metallic target,and their application in solid oxide fuel cells,such as buffer layers between yttria-stabilized zirconia(YSZ)/La0.6Sr0.4Co0.2Fe0.8O_(3−δ)and as sublayers in the steel/coating system,was evaluated.First,the direct current(DC)reactive-sputtering behavior of the GdCe metallic target was determined.Then,the GDC films were deposited on NiO-YSZ/YSZ half-cells to investigate the influence of oxygen flow rate on the quality of annealed GDC films.The results demonstrated that reactive sputtering can be used to prepare thin and dense GDC buffer layers without high-temperature sintering.Furthermore,the cells with a sputtered GDC buffer layer showed better electrochemical performance than those with a screen-printed GDC buffer layer.In addition,the insertion of a GDC sublayer between the SUS441 interconnects and the Mn-Co spinel coatings contributed to the reduction of the oxidation rate for SUS441 at operating temperatures,according to the area-specific resistance tests.

痕量双掺Sm^(3+)和Gd^(3+)对Y_2O_2S∶Eu^(3+)发光特性的影响

通过对Y2O2S∶Eu3+红色荧光粉痕量引入Sm3+和Gd3+的研究,发现可有效地增强发光强度,明显改善其电压特性(发射强度与激发电压间的关系特性),且不影响材料的其他物理化学性能。讨论和分析了发射强度增强、电压特性改善的原因:Gd3+对Y3+的置换,减少了因Eu3+对Y3+置换所引起的晶格的畸变、缺陷,使Eu3+离子晶场环境得到改善,从而减弱了无辐射过程及因晶格畸变所造成的能量损失;Sm3+的发射与Eu3+的吸收(激发)的部分重叠,且Eu3+激发光谱中包含有Sm3+激发跃迁谱线,导致了Sm3+→Eu3+共振能量传递可能性,有效地实现Sm3+对Eu3+的敏化效应。

Na^+离子掺杂Gd_2O_3∶Sm^(3+)纳米晶的发光增强

采用柠檬酸作燃烧剂,在柠檬酸-硝酸盐体系下制备了Gd2O3∶Sm3+和Gd2O3∶Sm3+,Na+纳米晶。用X射线衍射仪、透射电子显微镜、荧光光谱仪等对样品的结构、形貌和光致发光性能进行了分析。结果表明:所得纳米样品为纯立方相,晶粒尺寸约为30 nm。在室温下,用275 nm激发光激发各样品时,可观测到Sm3+离子的较强发光,其主发射峰位分别位于561.5,603.5,651.5 nm,分别对应着Sm3+离子的4G5/2→6H5/2,4G5/2→6H7/2和4G5/2→6H9/2的电子跃迁,其中以4G5/2→6H7/2跃迁的光谱强度最强。实验表明:Na+离子的掺入使得Sm3+离子的光发射强度显著增强。对引起样品荧光强度变化的原因进行了分析。

Gd^(3+)、Sm^(3+)共激活La_2O_2S:Eu^(3+)的发光特性

利用高温固相反应法合成了La2O2S:Eu3+及La2O2S:Eu3+、Sm3+、Gd3+荧光粉,并对其进行了表征。X射线衍射测试结果表明,合成样品为La2O2S纯物相,激光粒度分析测得荧光粉的平均粒径为18μm。光谱测试表明,Sm3+、Gd3+的掺入能有效增强Eu3+的627nm发射强度,所合成的(La0.945Gd0.01Sm0.005Eu0.03)2O2S荧光粉是一种具有应用前景的红色光致发光材料。

Upconversion Luminescence of Er^(3+), Tm^(3+) and Yb^(3+)Co-doped Gd_3Ga_5O_(12) Nanocrystals

A series of Er3＋, Tm3＋ and Yb3＋ doped Gd3Ga5O12 nanocrystals were prepared by a combustion method. The X-ray diffraction （XRD）, field emission scanning electron microscope （FESEM） and upconversion （UC） emission spectra were used to characterize the samples. The results of XRD indicate that Gd3Ga5O12：Er3＋, Tm3＋, Yb3＋ nanocrystals with cubic phase can be obtained. Under the excitation of a 980 nm laser, the different rare earth ions doped Gd3Ga5O12 nanoerystals show upconversion luminescence involving the green emission attributed to the ^2H11/2→^4I15/2, 4^S3/2→^4I15/2 transitions of Er3＋ ions, respectively, the red emissions assigned to the ^4F9/2→^4I15/2 transitions of Er3＋ ions and the ^1G4→^3F4 as well as 3F2,3→^3H6 transitions of Tm3＋ ions, respectively, the blue emission attributed to ^1G4→^3H6 transitions of Tm3＋ ions, and the near-infrared assigned to the ^3H4→^3H6 transitions of Tm3＋ ions. The CIE coordinates for the samples are calculated. The dependence of their upconversion luminescence properties on Yb3＋ ion concentration is investieated.

Li^+离子掺杂Gd_2O_3：Sm^(3+)纳米晶的发光增强

采用燃烧法制备了Gd_2O_3:Sm^(3+)和Li^+离子掺杂的Gd_2O_3:Sm^(3+)纳米晶,根据X射线衍射图谱确定所得纳米样品为纯立方相。在室温下,用275 nm和980 nm激发光激发各样品时,可分别观测到Sm^(3+)离子的强荧光发射和上转换特征发射,其主发射峰分别位于560,602,650 nm处,分别对应着Sm^(3+)离子的~4G_(5/2)→~6H_(5/2),~4G_(5/2)→~6H_(7/2)和~4G_(5/2)→~6H_(9/2)的电子跃迁,其中以~4G_(5/2)→~6H_(7/2)跃迁的光谱强度最大。实验表明Li^+离子的掺入使得Sm^(3+)离子的荧光发射强度显著增加。通过对样品的XRD、TEM和激发光谱、发射光谱的研究,分析了引起样品荧光强度变化的原因。

银离子掺杂Gd_2O_3:Sm^(3+)纳米晶的发光增强研究

采用燃烧法制备了Gd2O3∶Sm3+和Ag+离子掺杂的Gd2O3∶Sm3+纳米晶材料,根据X射线衍射图谱确定所得纳米样品为纯立方相.在室温下,用275 nm光激发各样品时,可观察到来自Sm3+离子强的荧光发射线,其主发射峰位置分别位于560、602、650 nm处,分别对应着Sm3+离子的4G5/2→6H5/2,4G5/2→6H7/2和4G5/2→6H9/2的电子跃迁,其中以4G5/2→6H7/2跃迁的光谱强度最大.实验表明掺入Ag+离子可使Sm3+离子的荧光发射强度显著增强.通过对样品的XRD、TEM和激发光谱、发射光谱的研究,分析了引起样品荧光强度变化的原因.

Influence of annealing temperature on luminescent properties of Eu^(3+)/V^(5+) co-doped nanocrystalline Gd_2Ti_2O_7 powders

Nanosized Gd2(1–x)Eu2xTi2O7:yV5+ phosphors were prepared via sol-gel method and characterized with X-ray diffraction,Raman spectroscopy,diffuse reflectance spectra and photoluminescence spectra.Their PL properties were investigated as functions of the Eu3+ doping concentration and annealing temperature.The results indicated that the as-prepared samples showed a strong emission of Eu3+ under the irradiation of 303 nm.For Eu3+-doped Gd2Ti2O7,the orange emission at 586 nm was the strongest,which was correspond...

Preparation, Structural Analysis and Luminescence Properties of Nanocrystalline Phosphor Gd_2O_3∶Eu

Nanocrystalline monoclinic and cubic Gd 2O 3∶Eu with different Eu 3+ concentration were prepared using glycine-nitrate combustion synthesis. By changing the ratio of glycine to nitrate and proper heat treatment, pure monoclinic and cubic Gd 2O 3∶Eu with particle size less than 40 nm can be easily formed. Under ultraviolet excitation, main emission of Eu 3+ ( 5D 0→ 7F 2) locates at 624 nm in monoclinic Gd 2O 3∶Eu and 611 nm in cubic sample. In excitation spectrum two broad bands corresponding to the host absorption and charge transfer state (CTS) and f-f transitions of Gd 3+ and Eu 3+ were observed and discussed. The quenching concentration of monoclinic and cubic Gd 2O 3∶Eu is 10% and 15%, respectively, both of which are much higher than that of bulk Gd 2O 3∶Eu.

Gd_2O_3:Eu^(3+)溶胶-凝胶薄膜发光特性研究

以无机稀土氧化物为原料制备了Gd2O3:Eu3+溶胶-凝胶薄膜,通过对不同Eu3+离子掺杂浓度、不同烧结温度薄膜发光强度的研究,得出Gd2O3薄膜中Eu3+离子的最佳掺杂浓度为10%、最佳热处理工艺为800℃下烧结2h;由薄膜和粉末激发谱的比较发现:薄膜中存在着比粉末更有效的能量传递,从而更有利于高能射线激发发光;首次观察到薄膜经过1000℃烧结2h后发光消失,并通过SEM和XRD的实验分析对这一现象进行了解释。

溶胶-冷冻法制备纳米Gd_2O_3：Eu^(3+)发光材料

采用溶胶-冷冻法合成了粒径为20nm左右的近似于球形的Gd_2O3:Eu^(3+)发光材料.XRD和FTIR分析表明:所合成的前驱体样品为带有结晶水的晶态氢氧化物,经过热处理后得到了立方相的Gd_2O_3.荧光光谱测试表明:所合成的样品具有良好的Eu^(3+)特征红光发射,Gd^(3+)到Eu^(3+)之间具有有效的能量传递过程.随着灼烧温度的升高,发射峰和激发峰的强度有所增强,荧光寿命变长,这是由于热处理温度升高,晶体生长变好,表面缺陷减少,使表面的猝灭中心减少,从而提高了荧光强度和荧光寿命.

Li^+,Zn^(2+)共掺杂对Gd_2O_3:Eu^(3+)纳米粉结构和发光性能的影响

采用燃烧法制备出Li+,Zn2+掺杂的Gd2O3∶Eu3+纳米荧光粉,研究了掺杂离子对Gd2O3∶Eu3+的结晶性能、晶粒形貌和光致发光特性的影响。以X射线衍射(XRD)、透射电子显微镜(TEM)、发射光谱和衰减时间谱等手段表征材料性能。结果表明,Li+,Zn2+掺杂可显著提高Gd2O3∶Eu3+纳米粉在611 nm处的发光强度,最大可达到未掺杂时的2.5倍。发光增强的主要原因可归结为3个方面:(1)使晶粒由单斜相向更利于发光的立方相转变;(2)氧空位的敏化剂作用;(3)掺杂离子的助熔剂效应,使晶粒的结晶性能提高、粒径增大,从而降低表面态引起的发光猝灭。

纳米晶Gd_2O_3∶Eu^(3+)的制备及发光性能

采用低温燃烧合成法制备了Gd2O3∶Eu3+纳米晶。用X射线衍射仪(XRD)、高分辨透射电子显微镜(HRTEM)和荧光光谱仪分别对样品的结构、形貌和发光性能进行了研究。结果表明,改变甘氨酸与稀土离子的比例(G/M)、退火温度可以制备出不同结构和晶粒尺寸的Gd2O3∶Eu3+纳米晶。在退火温度为800℃,G/M等于0.83和1.0时,均得到了纯立方相的Gd2O3∶Eu3+纳米晶,随着G/M的增加,Gd2O3∶Eu3+从立方相逐渐向单斜相转变。粉末的晶粒尺寸随着退火温度的增高而增大,晶粒尺寸在10~30 nm之间。立方相的Gd2O3∶Eu3+纳米晶主发射峰位置在612 nm(5D0→7F2跃迁),激发光谱中电荷迁移态发生了红移。

Gd_2O_3:Eu^(3+)纳米棒的制备与发光性能

在表面活性剂辅助的水热条件下合成出尺寸均一的Gd2O3∶Eu3+纳米棒,对其结构和荧光性质进行了表征,并对其生长机理进行了初步讨论.XRD结果表明,水热前驱体样品为六方晶相的Gd(OH)3,经过灼烧之后样品为立方相的Gd2O3.TEM照片表明,所得样品为直径60nm、长度约600nm的纳米棒.荧光光谱表明,在波长为254nm的紫外光激发下,Gd2O3∶Eu3+纳米棒产生了不同于前驱体的特征红光发射,对应于Eu3+的5D0-7F2跃迁,表明Gd2O3是红色发光材料的良好基质.

掺杂离子对Gd_2O_2S:Eu^(3+)磷光体结构和发光性能的影响

采用高温固相反应法制备出新型红色长余辉发光材料Gd2O2S:Eu3+,Xn+(X为Mg、Si、Ti中的一种或两种),研究掺杂离子对Gd2O2S:Eu3+磷光体的晶体结构、形貌粒度和发光性能的影响。通过X射线粉末衍射(XRD)、扫描电镜(SEM)和分光光度计等对合成产物进行分析与表征。结果表明:掺杂离子没有改变Gd2O2S:Eu3+磷光体的晶体结构,颗粒的形貌为类球形,分散性良好。同时,掺杂离子显著地延长发光材料Gd2O2S:Eu3+的余辉时间,并显示纯正的红色发光。

绿色荧光粉Gd_2Ba_3B_3O_(12):Tb^(3+)的发光性能研究

采用高温固相法制备了一系列Gd2Ba3B3O12:Tb3+绿色荧光粉,借助X射线粉末衍射仪(XRD)、真空紫外光谱和荧光光谱仪(VUV-UV)对样品的物相、发光性能进行了表征。结果表明,Tb3+作为发光中心全部进入到基质Gd2Ba3B3O12的晶格中并占据Gd3+的位置。样品Gd2Ba3B3O12:Tb3+的VUV-UV激发光谱主要由160～200nm和200～250nm的宽峰以及260～280nm和300～320nm的锐利峰组成。宽峰是由于基质吸收和Tb3+的f—d的跃迁形成的,锐利峰是由于Tb3+和Gd3+的f—f特征跃迁形成。样品Gd2Ba3B3O12:Tb3+的最强发射峰位于543nm,对应于Tb3+的5 D4→7 F5跃迁。在172nm激发下,样品Gd1.85Tb0.15Ba3B3O12的发光强度最强,其色坐标为(0.313 6,0.484 3),衰减时间为2.98ms,可作为绿色荧光粉应用于等离子体显示器(PDP)领域。

水热法制备多层核壳结构Gd_2O_3∶Eu^(3+)空心微球

以稀土硝酸盐-葡萄糖的混合溶液作为前驱体,采用一步水热法和随后的热处理得到了多层核壳结构Gd2O3∶Eu3+空心微球,并用X-射线衍射(XRD)、场发射扫描电镜(FESEM)、透射电镜(TEM)、X-射线能量色散光谱(EDS)和荧光光谱等测试手段对所得样品进行了表征。结果表明:所得空心球样品为纯的立方相的Gd2O3。具有规则的多层核壳空心结构,空心球的直径在2~3μm左右,壁厚约为100nm,并且Gd2O3∶Eu3+空心球是由尺寸约为30nm的球形纳米颗粒自组装而成。样品中含有Gd、Eu、O元素。该空心球样品具有强的Eu3+的特征红光发射以及长的荧光寿命,可以用来作为时间分辨荧光标记物。

Gd_2O_3的掺入对BaTiO_3陶瓷的形貌及相变等性能的影响

通过先制备钛酸钡 (BaTiO3 )的纳米粉 ,然后按一定质量比与Gd2 O3 混合 ,烧结成陶瓷。利用XRD、RAMAN技术研究了Gd2 O3 的掺入对BT陶瓷结构的影响。通过SEM、DSC技术分别观察了Gd2 O3 对BT陶瓷颗粒形貌、一级相变的影响。研究表明 :Gd2 O3 主要存在于晶界 ;由于Gd2 O3 引起的应力的作用 ,Gd2 O3 的对BT的振动模式和一级相变产生了一定的影响 ,影响最显著的是对BaTiO3

Gd_2O_3∶(Ce^(3+),Eu^(3+))微晶中稀土离子间的级联能量传递

本文报道了纳米Gd2 O3∶(Ce3+ ,Eu3 + )的紫外与真空紫外 (UV VUV)激发谱及其选择激发下的荧光光谱。这些光谱实验表明 ,除了Gd2 O3 基质与Ce3+ ,Eu3 + 离子之间的能量传递外 ,还存在着Gd3+ 与Ce3 + 、Eu3 +间的能量传递 ,即存在Gd3+ →Ce3+ →Eu3 +