摘要
结合Si体微机械技术和电镀技术加工出Fe-Ni/Cu/Si复合悬臂梁,其中Fe-Ni膜厚3μm,Cu膜厚0.2μm.利用共振法首次测出在1.3Pa气压下,复合悬臂梁中Fe-Ni(Fe64,Ni36;质量分数,%,下同)电镀沉积膜的内耗为10-3.利用自行设计的微力/微位移天平法,测出Fe-Ni(Fe 57, Ni 43)/Cu/Si复合悬臂梁的Young’s模量为1.0×1011N/m2.Fe-Ni电镀沉积膜的内应力随膜中Fe含量的增加先是增大然后减小.在Invar合金(Fe64,Ni36)成分附近达到最大约 300 MPa.Fe-Ni电镀膜的热膨胀系数与膜中Fe含量关系则与内应力相反,但与合金体材料变化趋势一致,在Invar合金成分附近达到最小,其值高于相应成分的合金体材料,约6×10-6/℃。
The Fe-Ni/Cu/Si composite cantilevers were made with the combination of bulk- silicon micromaching technology and electrodeposition technology. Using the composite cantilever, the internal friction and Young's modulus of Fe-Ni deposit were measured. The internal friction of Fe-Ni deposit (Fe 64, Ni 36, mass fraction,%) is about 10-3 under resonant frequency 247 Hz and vaccum 1.3 Pa. Based on home-made load-deflection balance method, the Young's modulus of composite cantilever (Fe 57, Ni 43,mass fraction,%) was measured to be 1.0×1011N/m2. Average internal stress of Fe-Ni deposits increases with Fe content up to a maximum of about 300 MPa at 64% Fe, then decreases with Fe content. On the contrary,thermal expansion coefficients (TECs) of Fe-Ni deposits decrease with Fe content down to a minimum of about 6×10-6/℃ near the composition of Invar alloy. TECs of Fe-Ni deposits change with the same trend as those of bulk Fe-Ni alloys, although TECs of Fe-Ni deposits were higher than those of bulk Fe-Ni alloys near the Invar composition.
出处
《金属学报》
SCIE
EI
CAS
CSCD
北大核心
2000年第5期525-529,共5页
Acta Metallurgica Sinica
关键词
微机械
Fe-Ni合金电镀沉积膜
内应力
热膨胀系数
microelectromechanical system (MEMS), Fe-Ni alloy deposit, internal stress,ther- mal expansion coefficient (TEC), Young's modulus, internal friction
