Ultrafast dark-field surface inspection with hybrid-dispersion laser scanning

High-speed surface inspection plays an important role in industrial manufacturing, safety monitoring, and quality control. It is desirable to go beyond the speed limitation of current technologies for reducing manufacturing costs and opening a new window onto a class of applications that require hig...

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Bibliographic Details
Published in:Applied physics letters 2014-06, Vol.104 (25)
Main Authors: Yazaki, Akio, Kim, Chanju, Chan, Jacky, Mahjoubfar, Ata, Goda, Keisuke, Watanabe, Masahiro, Jalali, Bahram
Format: Article
Language:English
Subjects:
Applied physics
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
CONFIGURATION
Configurations
CURRENTS
DEFECTS
DETECTION
Diodes
Disk drives
Dispersion
DISPERSIONS
ELECTRIC BATTERIES
ELECTRIC UTILITIES
GAS UTILITIES
High speed
INSPECTION
LASERS
LIGHT EMITTING DIODES
LITHIUM IONS
Lithium-ion batteries
MAGNETIC DISKS
MANUFACTURING
Organic light emitting diodes
Photovoltaic cells
Production costs
PULSES
Quality control
Real time
Rechargeable batteries
Scanning
Smartphones
SOLAR CELLS
Surface defects
SURFACES
VISIBLE RADIATION
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Summary:High-speed surface inspection plays an important role in industrial manufacturing, safety monitoring, and quality control. It is desirable to go beyond the speed limitation of current technologies for reducing manufacturing costs and opening a new window onto a class of applications that require high-throughput sensing. Here, we report a high-speed dark-field surface inspector for detection of micrometer-sized surface defects that can travel at a record high speed as high as a few kilometers per second. This method is based on a modified time-stretch microscope that illuminates temporally and spatially dispersed laser pulses on the surface of a fast-moving object and detects scattered light from defects on the surface with a sensitive photodetector in a dark-field configuration. The inspector's ability to perform ultrafast dark-field surface inspection enables real-time identification of difficult-to-detect features on weakly reflecting surfaces and hence renders the method much more practical than in the previously demonstrated bright-field configuration. Consequently, our inspector provides nearly 1000 times higher scanning speed than conventional inspectors. To show our method's broad utility, we demonstrate real-time inspection of the surface of various objects (a non-reflective black film, transparent flexible film, and reflective hard disk) for detection of 10 μm or smaller defects on a moving target at 20 m/s within a scan width of 25 mm at a scan rate of 90.9 MHz. Our method holds promise for improving the cost and performance of organic light-emitting diode displays for next-generation smart phones, lithium-ion batteries for green electronics, and high-efficiency solar cells.
ISSN:0003-6951
1077-3118
DOI:10.1063/1.4885147