传感技术学报
傳感技術學報
전감기술학보
Chinese Journal of Sensors and Actuators
2015年
9期
1282-1287
,共6页
王心心%梁庭%贾平岗%王涛龙%刘雨涛%张瑞%熊继军
王心心%樑庭%賈平崗%王濤龍%劉雨濤%張瑞%熊繼軍
왕심심%량정%가평강%왕도룡%류우도%장서%웅계군
MEMS%碳化硅直接键合%微观结构%碳化硅过渡层%粘性流动%熔融键合
MEMS%碳化硅直接鍵閤%微觀結構%碳化硅過渡層%粘性流動%鎔融鍵閤
MEMS%탄화규직접건합%미관결구%탄화규과도층%점성류동%용융건합
MEMS%SiC direct bonding%microstructure%SiO2 transition layer%viscous flow%fusion bonding
随着碳化硅(SiC)材料的MEMS器件在恶劣环境测量中的应用前景和迫切需求,进行了碳化硅的直接键合实验.研究了工艺条件对键合样品力学性能的影响,同时借助激光共聚焦扫描显微镜(CLSM)、扫描电子显微镜(SEM)、能谱仪(EDS)和拉曼光谱仪等对碳化硅键合样品界面的微观结构进行了分析.结果表明:退火温度和加载压力是影响键合效果的关键性因素.当退火温度为1 300℃,加载压力为3 MPa和退火时间为3 h时,此时键合样品的气密性非常好,力学性能达到最佳,键合强度2 MPa.最后通过样品微观界面分析表明碳化硅直接键合的机理为界面氧化硅过渡层的形成及粘性流动与碳化硅和碳化硅的熔融直接键合.
隨著碳化硅(SiC)材料的MEMS器件在噁劣環境測量中的應用前景和迫切需求,進行瞭碳化硅的直接鍵閤實驗.研究瞭工藝條件對鍵閤樣品力學性能的影響,同時藉助激光共聚焦掃描顯微鏡(CLSM)、掃描電子顯微鏡(SEM)、能譜儀(EDS)和拉曼光譜儀等對碳化硅鍵閤樣品界麵的微觀結構進行瞭分析.結果錶明:退火溫度和加載壓力是影響鍵閤效果的關鍵性因素.噹退火溫度為1 300℃,加載壓力為3 MPa和退火時間為3 h時,此時鍵閤樣品的氣密性非常好,力學性能達到最佳,鍵閤彊度2 MPa.最後通過樣品微觀界麵分析錶明碳化硅直接鍵閤的機理為界麵氧化硅過渡層的形成及粘性流動與碳化硅和碳化硅的鎔融直接鍵閤.
수착탄화규(SiC)재료적MEMS기건재악렬배경측량중적응용전경화박절수구,진행료탄화규적직접건합실험.연구료공예조건대건합양품역학성능적영향,동시차조격광공취초소묘현미경(CLSM)、소묘전자현미경(SEM)、능보의(EDS)화랍만광보의등대탄화규건합양품계면적미관결구진행료분석.결과표명:퇴화온도화가재압력시영향건합효과적관건성인소.당퇴화온도위1 300℃,가재압력위3 MPa화퇴화시간위3 h시,차시건합양품적기밀성비상호,역학성능체도최가,건합강도2 MPa.최후통과양품미관계면분석표명탄화규직접건합적궤리위계면양화규과도층적형성급점성류동여탄화규화탄화규적용융직접건합.
For the broad prospect and imminence requirement of silicon carbide(SiC)material MEMS devices in harsh environments,direct bonding between SiC and SiC was achieved. The influence of the bonding process on the mechanical properties of bonded samples was investigated and optimized,and the bonding interfaces of the bonded sample were analyzed by confocal laser scanning microscope(CLSM),scanning electron microscopy(SEM),energy dispersive spectrometer(EDS)and Raman spectroscopy,respectively.The results indicate that the annealing temper-ature and the loading force are the main factors of the formation of the bonded samples. At the condition of anneal-ing temperature=1 300℃,loading force=3 MPa,and annealing time=3 h,air tightness of the bonded sample is ex-cellent,and it has the best mechanical property. Its bonding strength reaches 2 MPa. A transition layer between the bonding interface at the high temperature,which can appears viscous flow,and SiC-SiC fusion direct bonding are the principles of direct bonding between SiC and SiC through the microscopic interface.
