检索规则说明:AND代表“并且”;OR代表“或者”;NOT代表“不包含”;(注意必须大写,运算符两边需空一格)
检 索 范 例 :范例一: (K=图书馆学 OR K=情报学) AND A=范并思 范例二:J=计算机应用与软件 AND (U=C++ OR U=Basic) NOT M=Visual
出 处:《应用光学》2007年第3期321-327,共7页Journal of Applied Optics
摘 要:传统分离脆性材料的技术由于易产生残余应力、显微裂纹与边部碎屑等缺陷,越来越不能满足半导体工业高精度与高清洁度的要求。激光微细加工技术以无污染、无接触及加工精度高、操作柔性好等优势,正成为一种很有潜力的脆性材料精密加工技术。介绍了用于分离脆性材料的几种典型激光微细加工技术,包括激光烧蚀切割技术、激光诱导张应力控制微裂纹扩展技术与激光剥离技术的工艺原理、特点及研究现状,指出了其存在的主要问题并探讨了其改进措施。最后预测了激光分离技术的发展前景。The traditional separation techniques of brittle materials can not meet the high precision and high cleanliness requirements in the semiconductor industry because they are susceptible to some flaws, such as residual stress, micro-cracks, chippings on the edge. However, the laser micro-processing technique is becoming a potential precision processing technique for brittle materials because of its advantages, such as non-pollution, non-contact, high processing precision and operational flexibility. The principle of processing, characteristic and research status on the several typical laser micro-processing techniques, such as laser ablation cutting technique, micro-crack propagation control technique by laser-induced tension, laser lift-off technique used to separate brittle materials are reviewed. The main problems existing in the techniques are pointed out and the improvements are briefly discussed. The development prospect of laser separation techniques is also predicted.
关 键 词:激光微细加工 激光烧蚀切割 微裂纹扩展控制 激光剥离 脆性材料
分 类 号:TN249-34[电子电信—物理电子学]
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在链接到云南高校图书馆文献保障联盟下载...
云南高校图书馆联盟文献共享服务平台 版权所有©
您的IP:216.73.216.7
