Understanding the formation mechanism of subsurface damage in potassium dihydrogen phosphate crystals during ultraprecision fly cutting 被引量：1

导出

摘要 Potassium dihydrogen phosphate(KDP)crystals play an important role in high-energy laser systems,but the laser damage threshold(LDT)of KDP components is lower than expected.The LDT is significantly influenced by subsurface damage produced in KDP crystals.However,it is very challenging to detect the subsurface damage caused by processing because a KDP is soft,brittle,and sensitive to the external environment(e.g.,humidity,temperature and applied stress).Conventional characterization methods such as transmission electron microscopy are ineffective for this purpose.This paper proposes a nondestructive detection method called grazing incidence X-ray diffraction(GIXD)to investigate the formation of subsurface damage during ultra-precision fly cutting of KDP crystals.Some crystal planes,namely(200),(112),(312),(211),(220),(202),(301),(213),(310)and(303),were detected in the processed subsurface with the aid of GIXD,which provided very different results for KDP crystal bulk.These results mean that single KDP crystals change into a lattice misalignment structure(LMS)due to mechanical stress in the subsurface.These crystal planes match the slip systems of the KDP crystals,implying that dislocations nucleate and propagate along slip systems to result in the formation of the LMS under shear and compression stresses.The discovery of the LMS in the subsurface provides a new insight into the nature of the laser-induced damage of KDP crystals.

作者 Yong Zhang Ning Hou Liang-Chi Zhang

机构地区 School of Mechatronics Engineering School of Mechatronics Engineering Laboratory for Precision and Nano Processing Technologies

出处《Advances in Manufacturing》 SCIE CAS CSCD 2019年第3期270-277,共8页 先进制造进展（英文版）

基金 This work was supported by the National Natural Science Foundation of China(Grant No.51875137) the Natural Science Foundation of Heilongjiang Province(Grant No.E2018033) Australian Research Council(Grant No.DP 170100567).

关键词 Potassium dihydrogen phosphate(KDP)crystals Subsurface damage Lattice misalignment structure Slip systems

分类号 TN2 [电子电信—物理电子学]

引文网络
相关文献

参考文献4

1吴东江,曹先锁,王强国,王奔,高航,康仁科.KDP晶体加工表面的亚表面损伤检测与分析[J].光学精密工程,2007,15(11):1721-1726. 被引量：31
2朱胜军,王圣来,刘琳,王端良,李伟东,黄萍萍,许心光.大尺寸磷酸二氢钾晶体的折射率均一性研究[J].物理学报,2014,63(10):386-391. 被引量：5
3王强国,高航,裴志坚,鲁春朋,王碧玲,滕晓辑.KDP晶体超声辅助磨削的亚表面损伤研究[J].人工晶体学报,2010,39(1):67-71. 被引量：14
4王波,王圣来,房昌水,孙洵,顾庆天,李义平,王坤鹏,李云南.Fe^(3+)对KDP晶体生长影响的研究[J].人工晶体学报,2005,34(2):205-208. 被引量：19

二级参考文献37

1李玉和,李庆祥,王东生,葛杨翔,廖小华.超精表面缺陷检测系统的实验研究[J].光学精密工程,2005,13(z1):65-68. 被引量：5
2王景贺,陈明君,董申,尚元江.KDP晶体光学零件超精密加工技术研究的新进展[J].工具技术,2004,38(9):56-59. 被引量：22
3谢英明,李新政,郑滨,杨兰兰.KDP(KH_2PO_4)晶体材料的研究进展[J].河北工业科技,2006,23(6):377-380. 被引量：17
4Kozlowski M R,Thomas I,Edwards G,et al.Influence of Diamond Turning and Surface Cleaning Processes on the Degradation of KDP Crystal Surfaces[J].Proceeding of SPIE,1991,1561:59-69.
5Wu D J,Wang B,Gao H,et al.Influence of Grinding to the Surface and Subsurface Quality of KDP Crystal[J].Advanced Materials Research,2008,53-54:203-208.
6Pei Z J,Prabhakar D,Ferreira P M,et al.A Mechanistic Approach to the Prediction of Material Removal Rates in Rotary Ultrasonic Machining[J].Journal of Engineering for Industry,1995,117:142-151.
7Wang Q G,Pei Z J,Gao H,et al.Rotary Ultrasonic Machining of Potassium Dihydrogen Phosphate (KDP) Crystal:An Experimental Investigation[J].International Journal of Mechatronics and Manufacturing Systems,2009,2(4):414-426.
8Kailer A,Gogotsi Y,Nickel K G.Phase Transformations of Silicon Caused by Contact Loading[J].J.Appl.Phys.,1997,81:3057-3063.
9Wang Q G,Gao H,Zhang Q Z,et al.Experimental Researches on Precision Grinding of KDP Crystal[J].Key Engineering Materials,2008,359-360:113-117.
10Bespalov V I,Bredikhin V I,Ershov V P,et al.Gained Experience in Production of Wide-aperture Optical Elements Using KDP,DKDP Crystals Rapid Growth Technology[J].Proceedings of SPIE,2001,4424:124-128.

共引文献62

1贾慧灵,于海滨,吴锦绣,谭心,王峰,孙士阳.Al、Cr、Fe掺杂对KDP(001)晶面力学性能影响的第一性原理研究[J].材料导报,2022,36(S01):173-178.
2吴沿鹏,杨炜,叶卉,胡陈林.光学元件亚表面损伤深度及形貌研究[J].制造技术与机床,2013(10):74-77. 被引量：6
3谢英明,李新政,郑滨,杨兰兰.KDP(KH_2PO_4)晶体材料的研究进展[J].河北工业科技,2006,23(6):377-380. 被引量：17
4孙洵,张艳珍,徐明霞,孙绍涛,季来林,王正平,李恪宇,程秀凤,许心光.Fe^(3+)对KDP晶体光学质量的影响[J].人工晶体学报,2007,36(6):1240-1244. 被引量：4
5孙绍涛,季来林,王正平,刘冰,牟晓明,孙洵,许心光,史崇德.不同原料DKDP晶体的生长和损伤阈值[J].强激光与粒子束,2008,20(5):755-759. 被引量：3
6曹先锁,吴东江,王奔,高航,康仁科.KDP晶体各向异性力学特性分析[J].人工晶体学报,2008,37(3):704-709. 被引量：22
7WANG Ben WU Dongjiang GAO Hang KANG Renke GUO Dongming.Subsurface Damage in Scratch Testing of Potassium Dihydrogen Phosphate Crystal[J].Chinese Journal of Mechanical Engineering,2009,22(1):15-20. 被引量：3
8王庆国,滕冰,于涛,钟德高,王东娟,赵严帅.EDTA和KCl掺杂对KDP晶体光学质量的影响[J].人工晶体学报,2009,38(2):313-316. 被引量：1
9孙绍涛,季来林,王正平,牟晓明,孙洵,许心光,史崇德.原料对DKDP晶体生长习性及光学性能的影响[J].人工晶体学报,2009,38(3):539-543. 被引量：3
10王波,梁晓亮,许心光,王圣来,孙洵,顾庆天,李毅平,房昌水,冯彧,史崇德.“点籽晶”法快速生长中等口径KDP单晶及其性能表征[J].人工晶体学报,2009,38(5):1051-1054. 被引量：3

同被引文献7

1曹先锁,吴东江,王奔,高航,康仁科.KDP晶体各向异性力学特性分析[J].人工晶体学报,2008,37(3):704-709. 被引量：22
2鲁春朋,高航,王奔,郭东明,腾晓辑,康仁科,吴东江.磷酸二氢钾晶体单点划痕试验研究[J].机械工程学报,2010,46(13):179-185. 被引量：15
3王栋,冯平法,张承龙,张建富.KDP晶体各向异性对划痕特性影响的实验研究[J].人工晶体学报,2012,41(3):568-572. 被引量：16
4王栋,冯平法,张承龙,张建富.磷酸二氢钾晶体微尺度力学行为试验研究[J].机械工程学报,2013,49(18):119-124. 被引量：4
5Dan-Dan Cui,Liang-Chi Zhang.Nano-machining of materials： understanding the process through molecular dynamics simulation[J].Advances in Manufacturing,2017,5(1):20-34. 被引量：1
6Yong Zhang,Ning Hou,Liang-Chi Zhang.Investigation into the room temperature creep-deformation of potassium dihydrogen phosphate crystals using nanoindentation[J].Advances in Manufacturing,2018,6(4):376-383. 被引量：2
7Yong Zhang,Ning Hou,Liang-Chi Zhang,Qi Wang.Elastic-plastic-brittle transitions of potassium dihydrogen phosphate crystals:characterization by nanoindentation[J].Advances in Manufacturing,2020,8(4):447-456. 被引量：1

引证文献1

1Ning Hou,Yong Zhang,Liang-Chi Zhang,Ming-Hai Wang.Material removal mechanisms and characteristics of potassium dihydrogen phosphate crystals under nanoscratching[J].Advances in Manufacturing,2021,9(4):558-567.

1Ivan V. Maksimovich.Possibilities of transcatheter treatment of patients after extensive ischemic stroke[J].World Journal of Neuroscience,2013,3(3):171-185.
2Dongping Zhang,Yan Li,Jingting Luo,Zhuanghao Zheng,Guangxing Liang,Xingmin Cai,Fan Ye,Ping Fan,Jianjun Huang.Microstructure and 355 nm Laser-Induced Damage Characteristics of Al<sub>2</sub>O<sub>3</sub>Films Irradiated with Oxygen Plasma under Different Energy[J].Optics and Photonics Journal,2013,3(2):152-157. 被引量：1
3魏富鹏,陈凤东,唐军,彭志涛,刘国栋.Final optics damage online inspection in high power laser facility[J].Optoelectronics Letters,2019,15(4):306-311. 被引量：1
4Alejandro Heredia,Maria Colin-Garcia,Miguel A.Pena-RicoLuis F.L.Aguirre Beltrán,Jose Grácio,Flavio F.Contreras-Torres,Andrés Rodríguez-Galván,Lauro Bucio,Vladimir A.Basiuk.Thermal,infrared spectroscopy and molecular modeling characterization of bone:An insight in the apatite-collagen type I interaction[J].Advances in Biological Chemistry,2013,3(2):215-223.
5Ivan V. Maksimovich.Transcatheter treatment of atherosclerotic lesions of the brain complicated by vascular dementia development[J].World Journal of Neuroscience,2012,2(4):200-209. 被引量：1
6Tiancheng Yu,Jiangtao Guo,Gang Xia,Xiang Zhang,Fan Gao,Jiangfeng Wang,Wei Fan,Xiao Yuan.High-extraction-efficiency, nanosecond bidirectional ring amplifier with twin pulses[J].High Power Laser Science and Engineering,2019,7(2):71-75.
7孙立成,刘廷昊,付星,郭亚丁,王小军,邵崇峰,郑亚旻,孙闯,林仕兵,黄磊.1.57 times diffraction-limit high-energy laser based on a Nd:YAG slab amplifier and an adaptive optics system[J].Chinese Optics Letters,2019,17(5):39-43. 被引量：3
8Yong Zhang,Ning Hou,Liang-Chi Zhang.Investigation into the room temperature creep-deformation of potassium dihydrogen phosphate crystals using nanoindentation[J].Advances in Manufacturing,2018,6(4):376-383. 被引量：2
9皮梦,刘心志,张书平,张后雷.城市污泥与水稻秸秆混合热解特性及动力学分析[J].能源研究与利用,2019,0(6):37-44. 被引量：2
10Lei Zhang,Youheng Dong,Jianxin Wang,Chaoen Xiao,Ding Ding.A Hardware Trojan Detection Method Based on the Electromagnetic Leakage[J].China Communications,2019,16(12):100-110. 被引量：1

Advances in Manufacturing

2019年第3期

浏览历史

内容加载中请稍等...