@misc{oai:repo.qst.go.jp:00066315,
 author = {ホァン, カイ and 小瀧, 秀行 and 森, 道昭 and 林, 由紀雄 and 中新, 信彦 and エシロケポフ, ティムル and コーガ, ジェームズ and ブラノフ, セルゲイ and 神門, 正城 and 黄 開 and 小瀧 秀行 and 森 道昭 and 林 由紀雄 and 中新 信彦 and エシロケポフ ティムル and コーガ ジェームズ and ブラノフ セルゲイ and 神門 正城},
 month = {May},
 note = {Laser wakefield acceleration (LWFA)1 has been studied intensively due to the inherent ultrashort bunch duration (fs) and large acceleration gradient (GV/cm) over conventional accelerators. This regime is considered promising on construction of compact table-top X-ray free electron lasers (XFEL) which have broad application in ultrafast process studies2. The generation of XFEL relies on the process of self-amplification of spontaneous emission (SASE)3, which requires electron beam with extremely high current, low energy spread,  and low emittance to cause micro-bunching. Also, the jitter issue in the pump-probe experiment is dependent on the electron injection timing. During LWFA experiment, it is essential to establish real time electron bunch temporal diagnostics to monitor the electron pulse duration and arrival time.
We present LWFA study via single-shot non-destructive electro-optic (EO) sampling4 technique for the first time. The electron spectra and divergence information had been detected simultaneously with electron bunch temporal signal. In the experiment, we observed stable and earlier electron pulse arrival time with higher plasma density. At density above 3×1019cm-3, multi-bunch signal was frequently observed. In addition, we achieved high quality electron bunch with divergence <1 mrad and energy spread <1 MeV in the self-modulated laser wakefield acceleration regime. PIC simulation has been performed to study the injection process. This diagnostic proved to have superior data attainability compared with previous works5-7 and could be introduced as a real time non-destructive electron pulse duration monitor for LWFA experiment., Opto 2017　Symposium on Photon and Beam Science},
 title = {Real-time Non-destructive Electro-optic Sampling Study on Laser Wakefield Acceleration},
 year = {2017}
}