Surface characterization of ICF capsule by AFM-based profilometer

被引:8
|
作者
Meng, Jie [1 ]
Zhao, Xuesen [2 ]
Tang, Xing [1 ]
Xia, Yihao [1 ]
Ma, Xiaojun [1 ]
Gao, Dangzhong [1 ]
机构
[1] CAEP, Res Ctr Laser Fus, 64 Mianshan Rd, Mianyang 621000, Peoples R China
[2] Harbin Inst Technol, POB 413, Harbin 150001, Heilongjiang, Peoples R China
来源
HIGH POWER LASER SCIENCE AND ENGINEERING | 2017年 / 5卷
关键词
inertial confinement fusion; target design and fabrication; SHELLS;
D O I
10.1017/hpl.2017.20
中图分类号
O43 [光学];
学科分类号
070207 ; 0803 ;
摘要
Outside surface fluctuations of inertial confinement fusion (ICF) capsule greatly affect the implosion performance. An atomic force microscope (AFM)-based profilometer is developed to precisely characterize the capsule surface with nanometer resolution. With the standard nine surface profiles and the complete coverage data, 1D and 2D power spectra are obtained to quantitatively qualify the capsule. Capsule center fast aligning, orbit traces automatic recording, 3D capsule orientation have been studied to improve the accuracy and efficiency of the profilometer.
引用
收藏
页数:7
相关论文
共 50 条
  • [21] AFM-based manipulation of InAs nanowires
    Conache, G.
    Gray, S.
    Bordag, M.
    Ribayrol, A.
    Froberg, L. E.
    Samuelson, L.
    Pettersson, H.
    Montelius, L.
    PROCEEDINGS OF THE 17TH INTERNATIONAL VACUUM CONGRESS/13TH INTERNATIONAL CONFERENCE ON SURFACE SCIENCE/INTERNATIONAL CONFERENCE ON NANOSCIENCE AND TECHNOLOGY, 2008, 100
  • [22] AFM-based force microsensor for a microrobot
    Fatikow, S
    Fahlbusch, S
    MICROROBOTICS AND MICROASSEMBLY III, 2001, 4568 : 90 - 99
  • [23] Examining the Casimir puzzle with an upgraded AFM-based technique and advanced surface cleaning
    Liu, Mingyue
    Xu, Jun
    Klimchitskaya, G. L.
    Mostepanenko, V. M.
    Mohideen, U.
    PHYSICAL REVIEW B, 2019, 100 (08)
  • [24] Towards the determination of surface energy at the nanoscale: A further assessment of the afm-based approach
    Lamprou D.A.
    Smith J.R.
    Nevell T.G.
    Barbu E.
    Willis C.R.
    Tsibouklis J.
    Journal of Advanced Microscopy Research, 2010, 5 (02) : 137 - 142
  • [25] AFM-BASED NANOINDENTATION PROCESS: A COMPARATIVE STUDY
    Promyoo, Rapeepan
    El-Mounayri, Hazim
    Varahramyan, Kody
    PROCEEDINGS OF THE ASME INTERNATIONAL MANUFACTURING SCIENCE AND ENGINEERING CONFERENCE, 2012, 2012, : 869 - 878
  • [26] AFM-based lithography for nanoscale protein assays
    Ngunjiri, Johnpeter
    Garno, Jayne C.
    ANALYTICAL CHEMISTRY, 2008, 80 (05) : 1361 - 1369
  • [27] Damaged Layer Analysis for AFM-based Mechanical Modifications on (100) Si Surface
    Park, Jeong Woo
    Kim, Nam Hun
    ADVANCES IN MATERIALS MANUFACTURING SCIENCE AND TECHNOLOGY XIII, VOL 1: ADVANCED MANUFACTURING TECHNOLOGY AND EQUIPMENT, AND MANUFACTURING SYSTEMS AND AUTOMATION, 2009, 626-627 : 29 - +
  • [28] AFM-based tribology as a probe of biofilm cohesion
    Ahimou, Francois
    Haugstad, Greg
    Novak, Paige
    Semmens, Michael
    ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, 2012, 244
  • [29] AFM-based voltage assisted nanoelectro spinning
    Wu, Yiquan
    Johannes, Matthew S.
    Clark, Robert L.
    MATERIALS LETTERS, 2008, 62 (4-5) : 699 - 702
  • [30] Fabrication of Nanopatterns on Silicon Surface by Combining AFM-Based Scratching and RIE Methods
    Geng Y.
    Yan Y.
    Wang J.
    Zhuang Y.
    Nanomanufacturing and Metrology, 2018, 1 (4) : 225 - 235
12345