稀有金属材料与工程
稀有金屬材料與工程
희유금속재료여공정
RARE METAL MATERIALS AND ENGINEERNG
2009年
z2期
106-109
,共4页
仝建峰%钟凌生%陈大明%韩敏芳
仝建峰%鐘凌生%陳大明%韓敏芳
동건봉%종릉생%진대명%한민방
氮化硅%自增韧%氧化镥%晶种
氮化硅%自增韌%氧化镥%晶種
담화규%자증인%양화노%정충
silicon nitride ceramic%phase transformation%Lu_2O_3%self-reinforcing
以稀土氧化物Lu_2O_3作为单一添加剂,研究在热处理过程中,稀土氧化物对氮化硅在粉体状态下相变的影响.指出氮化硅粉体的α→β相变率与稀土氧化物的添加量、粉体的热处理温度之间的关系.发现热处理温度在1650 ℃以下时,氮化硅粉体的相变率随着添加剂含量的异常变化.以上述制备的β-氮化硅晶种,在不进行化学处理的情况下直接用于氮化硅陶瓷的增韧,使得所制备的氮化硅陶瓷在保持原有的室温强度基本不变的情况下,断裂韧性得到大幅度提高.在此体系中研究了β-氮化硅晶种的增韧效果及机制.分析了晶粒尺寸及其分布与氮化硅陶瓷性能及显微结构之间的关系.研究表明:以Lu_2O_3为单一添加剂的自增韧氮化硅陶瓷,晶种的加入使材料在保持强度的同时,断裂韧性提高了10%~20%.
以稀土氧化物Lu_2O_3作為單一添加劑,研究在熱處理過程中,稀土氧化物對氮化硅在粉體狀態下相變的影響.指齣氮化硅粉體的α→β相變率與稀土氧化物的添加量、粉體的熱處理溫度之間的關繫.髮現熱處理溫度在1650 ℃以下時,氮化硅粉體的相變率隨著添加劑含量的異常變化.以上述製備的β-氮化硅晶種,在不進行化學處理的情況下直接用于氮化硅陶瓷的增韌,使得所製備的氮化硅陶瓷在保持原有的室溫彊度基本不變的情況下,斷裂韌性得到大幅度提高.在此體繫中研究瞭β-氮化硅晶種的增韌效果及機製.分析瞭晶粒呎吋及其分佈與氮化硅陶瓷性能及顯微結構之間的關繫.研究錶明:以Lu_2O_3為單一添加劑的自增韌氮化硅陶瓷,晶種的加入使材料在保持彊度的同時,斷裂韌性提高瞭10%~20%.
이희토양화물Lu_2O_3작위단일첨가제,연구재열처리과정중,희토양화물대담화규재분체상태하상변적영향.지출담화규분체적α→β상변솔여희토양화물적첨가량、분체적열처리온도지간적관계.발현열처리온도재1650 ℃이하시,담화규분체적상변솔수착첨가제함량적이상변화.이상술제비적β-담화규정충,재불진행화학처리적정황하직접용우담화규도자적증인,사득소제비적담화규도자재보지원유적실온강도기본불변적정황하,단렬인성득도대폭도제고.재차체계중연구료β-담화규정충적증인효과급궤제.분석료정립척촌급기분포여담화규도자성능급현미결구지간적관계.연구표명:이Lu_2O_3위단일첨가제적자증인담화규도자,정충적가입사재료재보지강도적동시,단렬인성제고료10%~20%.
β-Si_3N_4 with completeness of phase transformation and pole-liked morphology was developed by means of heating the initial Si_3N_4 powder with certain additive of Lu_2O_3. The influence of Lu_2O_3 on phase transformation and seeds morphology was investigated. The result showed that the β-Si_3N_4 seeds with up to 95% a phase content could be gotten with 1 mol% Lu_2O_3 as additive contents at 1750 ℃ for 2 h. The microstructure and mechanical properties of hot-pressed Si_3N_4 ceramics, using 10 mol% of Lu_2O_3 additives were investigated by means of MTS measurements and Vickers indentation crack size measurements, as well as XRD and SEM. It was known that the high fracture toughness of Si_3N_4 ceramics was attributed to the rodlike morphology of β-Si_3N_4 grains. And the reinforcement effect and mechanism of β-Si_3N_4 seed were studied. It was found that the grain size and its distribution influence on the property and microstructure of Si_3N_4 ceramics were investigated. The improvement in the fracture toughness with the amount of additive was mainly attributed to elongated grain growth during the sintering process. By this method, self-reinforced Si_3N_4 ceramics with an increment of 10~20% of fracture toughness was fabricated.
