掺杂Ba(Zr_(0.15)Ti_(0.85))O_(3)陶瓷的结构与电性能研究

采用固相烧结法制备了不同氧化钬掺杂量的Ba(Zr_(0.15)Ti_(0.85))O_(3)(BZT)陶瓷,对比分析了未掺杂和掺杂不同含量氧化钬的BZT陶瓷的物相组成、显微组织、介电性能和铁电性能。结果表明:未掺杂或氧化钬掺杂量较小(质量分数≤2%)的BZT陶瓷主要以单相固溶体形式存在;当氧化钬质量分数增加至3%及以上时,BZT陶瓷中形成新的Ho_(2)Ti_(2)O_(7)相;掺杂氧化钬的BZT陶瓷晶粒尺寸明显小于未掺杂氧化钬的BZT陶瓷,且随着氧化钬掺杂量的增加,BZT陶瓷的平均晶粒尺寸逐渐减小。此外,随着氧化钬掺杂量的增加,BZT陶瓷的ε_(r RT)和tan δ_(RT)先增加后减小,当氧化钬质量分数为2%时可以得到高ε_(r RT)、低tan δ_(RT)的BZT陶瓷。掺杂氧化钬的BZT陶瓷具有弛豫铁电陶瓷特征,氧化钬质量分数为2%~7%的BZT陶瓷的剩余极化强度均低于未掺杂氧化钬的BZT陶瓷,且剩余极化强度随着氧化钬掺杂量的增加逐渐减小;掺杂氧化钬的BZT陶瓷的矫顽电场均小于未掺杂氧化钬的BZT陶瓷,且矫顽电场随着氧化钬掺杂量的增加逐渐减小;BZT陶瓷剩余极化强度和矫顽电场的变化主要与BZT陶瓷内部相变、晶粒尺寸等有关。

Sm^(3+)掺杂Ba_(0.85)Ca_(0.15)Ti_(0.90)Zr_(0.10)O_(3)无铅多功能铁电陶瓷的储能和光致发光性能

通过高温固相反应法制备了Ba_(0.85)Ca_(0.15)Ti_(0.90)Zr_(0.10)O_(3)∶xSm^(3+)(BCTZ∶xSm^(3+),x=0.0%、0.2%、0.4%、0.6%、0.8%、1.0%,物质的量分数)陶瓷,系统研究了其微观形貌、铁电性能、储能性能和光致发光性能。研究表明,Sm^(3+)掺入后,陶瓷平均晶粒大小明显下降,致密度显著提高。所有陶瓷均表现出典型的铁电性。BCTZ∶xSm^(3+)陶瓷放电储能密度得到了极大的提高,BCTZ∶1.0%Sm^(3+)陶瓷放电储能密度较纯BCTZ陶瓷可提高约49.0%。此外,在408 nm光的激发下,BCTZ∶xSm^(3+)陶瓷在596 nm左右表现出强烈的橙红色发光,且发光强度相对可调性可达449%。

Synthesis and characterization of Zr_(0.85)Y_(0.15)O_(1.925)-La_(9.33)Si_(6)O_(26) composite electrolyte for application in SOFCs

Composite oxide ionic conductors consisting of Zr_(0.85)Y_(0.15)O_(1.925)(YSZ)and La_(9.33)Si_(6)O_(26)(LSO)have been synthesized by a modified coprecipitation method.X-ray diffraction,electron microscope,and complex impedance were adopted to investigate the phase component,microstructures,and conductivities,respectively.The results show that the average grain sizes of the composite powders and as-sintered pellets are less than 20 nm and 200 nm,respectively.The conductivity of the composite materials composed of 94 wt%YSZ and 6 wt%LSO is 0.215 S/cm at 700℃.The conductivity of the composite is three times higher than that of the polycrystalline YSZ and has two orders in magnitude higher than that of the polycrystalline LSO at 700℃.By analyzing the impedance spectra and modulus spectra,the grain-boundary effect on the conductivity improvement is investigated and the conductive mechanisms of the composite materials are discussed.

退火温度对BCZT外延薄膜电学性能的影响及其导电机制分析

脉冲激光沉积技术制备Ba_(0.85)Ca_(0.15)Zr_(0.1)Ti_(0.9)O_(3)(BCZT)外延薄膜时通常需要较高的沉积温度,且易含有氧空位缺陷。本文旨在提供一种基于脉冲激光沉积技术接后退火处理工艺,并成功在导电基板上制备了高质量BCZT外延薄膜,探究了退火温度对BCZT外延薄膜结构和性能的影响。不同温度(750、800、850和900℃)退火后薄膜均呈现纯净物相,且随着退火温度的升高,薄膜的铁电性能逐渐提高,2Pr由4.2μC/cm^(2)提升至17.6μC/cm^(2),但900℃退火温度下薄膜样品的漏电流问题最严重。通过拟合J-E关系表明,低电场下700℃至850℃退火后的薄膜均遵循欧姆导电机制,而900℃退火后的薄膜遵循空间电荷限制电流机制,高电场下所有退火温度下的薄膜均遵循福勒-诺德海姆隧穿机制。