Single-shot optical imaging with spectrum circuit bridging timescales in high-speed photography.
Takao SaikiKeitaro ShimadaAyumu IshijimaHang SongXinyi QiYuki OkamotoAyako MizushimaYoshio MitaTakuya HosobataMasahiro TakedaShinya MoritaKosuke KushibikiShinobu OzakiKentaro MotoharaYutaka YamagataAkira TsukamotoFumihiko KannariIchiro SakumaYuki InadaKeiichi NakagawaPublished in: Science advances (2023)
Single-shot optical imaging based on ultrashort lasers has revealed nonrepetitive processes in subnanosecond timescales beyond the recording range of conventional high-speed cameras. However, nanosecond photography without sacrificing short exposure time and image quality is still missing because of the gap in recordable timescales between ultrafast optical imaging and high-speed electronic cameras. Here, we demonstrate nanosecond photography and ultrawide time-range high-speed photography using a spectrum circuit that produces interval-tunable pulse trains while keeping short pulse durations. We capture a shock wave propagating through a biological cell with a 1.5-ns frame interval and 44-ps exposure time while suppressing image blur. Furthermore, we observe femtosecond laser processing over multiple timescales (25-ps, 2.0-ns, and 1-ms frame intervals), showing that the plasma generated at the picosecond timescale affects subsequent shock wave formation at the nanosecond timescale. Our technique contributes to accumulating data of various fast processes for analysis and to analyzing multi-timescale phenomena as a series of physical processes.
Keyphrases
- high speed
- high resolution
- atomic force microscopy
- image quality
- mass spectrometry
- blood pressure
- single cell
- physical activity
- mental health
- computed tomography
- multiple sclerosis
- dengue virus
- signaling pathway
- stem cells
- deep learning
- zika virus
- machine learning
- ms ms
- bone marrow
- mesenchymal stem cells
- big data
- energy transfer
- fluorescence imaging