SiC对反应烧结多孔Al_2TiO_5的物相及组织性能影响

本研究以γ-AlOOH、TiO2和SiC为原料,通过无压反应烧结制备了Al2TiO5多孔材料,分析比较了SiC粒度和含量对合成产物的物相组成、显微组织、抗压强度、孔隙率和孔径分布的影响。结果表明:反应产物的物相组成为Al2TiO5、Al6Si2O13、TiC、SiO2和Al2O3,还有少量未反应的TiO2。SiC与TiO2反应生成TiC和SiO2,TiC颗粒弥散分布于多孔材料壁面或者骨架中,而SiO2进一步与γ-AlOOH分解出的Al2O3反应生成Al6Si2O13晶须,晶须交错分布于Al2TiO5颗粒之间或者孔洞中,与TiC颗粒一起提高复合材料的抗压强度,特别是采用小粒径SiC时,对抗压强度的改善效果更加显著;添加大粒径SiC后,改变原有颗粒堆积状态,可提高复合材料的孔隙率。但当SiC含量超过5wt%时,因为生成较多低熔点的SiO2,部分填充于多孔材料的孔隙中,部分则分布于Al2TiO5晶粒之间,既减小孔隙率,又降低晶粒间结合强度和试样的抗压强度。

3/2-Al_6Si_2O_(13)/蒙脱土∶Eu,Al复相发光材料的制备及性能

采用高温固相法合成了3/2-Al6Si2O13/蒙脱土∶Eu,Al复相基质蓝色发光材料。探讨基质中Al6Si2O13与蒙脱土比例、激活剂Eu浓度以及Al掺杂浓度对发光性能的影响。实验结果表明,相对于Al6Si2O13单一体系,复相体系的发射光谱产生红移,Stokes位移和FWHM均变大,发光强度显著增强,Eu的最佳含量为8mol%。在350nm激发下,样品的发射光谱为主峰位于450nm及位于483nm的肩峰组成的宽带峰,对应于Eu2+的4f65d→4f7宽带发射。Eu2+-Eu2+之间出现能量传递,能量传递临界距离Rc为1.75nm,传递方式为电多级相互作用。Al可增加基质禁带宽度,掺杂Al的量为5mol%的样品发光性能最好。

Phase Relations in Si-Al-Y-O-C Systems

The present work investigated the phase relations in SiC-Al2O3-Y2O3-SiO2 (Si-Al-Y-O-C) system. As a continuation of our previous works, the purpose of this study is to understand the high temperature reaction behaviors of SiO2 in the system and its effect on the phase relations of the valuable system of SiC-Al2O3-Y2O3. The phase compositions of six solid-state reacted samples with different components of Y2O3:Al2O3:SiC:SiO2 were analyzed by XRD. The phase relations of the systems were determined. The subsolidus phase diagrams of ternary Al2O3-SiC-SiO2 system and the tentative phase diagram of an extended quaternary Y2O3-Al2O3-SiC-SiO2 system were presented latter involving several coexisting regions of four phases. The high temperature reaction behavior of SiO2 in the system and its effect on the phase relations of system were discussed.

Al_6Si_2O_(13)晶须和TiC颗粒复合强化多孔Al_2TiO_5基复合材料

以γ-AlOOH和TiO_2为原料,添加不同质量分数SiC晶须(SiCw),采用无压反应烧结法制备多孔(Al_6Si_2O_(13)+TiC)/Al_2TiO_5复合材料,分析了SiCw质量分数对(Al_6Si_2O_(13)+TiC)/Al_2TiO_5复合材料孔隙率和抗压强度的影响,讨论了SiCw的强化机制。结果表明:不添加SiCw时,产物主要为Al_2TiO_5和少量Al_2O_3,还有少量未反应的TiO_2;加入SiCw之后,还形成了Al_6Si_2O_(13)和TiC相,TiC和Al_6Si_2O_(13)分别以规则颗粒状和晶须形态存在于Al_2TiO_5基体中。TiC颗粒与Al_6Si_2O_(13)晶须通过细化显微组织、裂纹偏转和晶须桥连机制,起到协同强化作用。SiCw的添加使孔隙率和抗压强度同时大幅度提高,随着SiCw质量分数的增加,(Al_6Si_2O_(13)+TiC)/Al_2TiO_5复合材料孔隙率降低,抗压强度提高的速率减小,当SiCw的质量分数为7.2%时,抗压强度最高,达到301.81 MPa。