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Your search keyword '"Pai, Chih-Hao"' showing total 33 results
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33 results on '"Pai, Chih-Hao"'

1. Ultra-short pulse generation from mid-IR to THz range using plasma wakes and relativistic ionization fronts

Author

Nie, Zan, Wu, Yipeng, Zhang, Chaojie, Mori, Warren B., Joshi, Chan, Lu, Wei, Pai, Chih-Hao, Hua, Jianfei, and Wang, Jyhpyng

Subjects
Physics - Plasma Physics, Physics - Optics
Abstract

This paper discusses numerical and experimental results on frequency downshifting and upshifting of a 10 $\mu$m infrared laser to cover the entire wavelength (frequency) range from $\lambda$=1-150 $\mu$m ($\nu$=300-2 THz) using two different plasma techniques. The first plasma technique utilizes frequency downshifting of the drive laser pulse in a nonlinear plasma wake. Based on this technique, we have proposed and demonstrated that in a tailored plasma structure multi-millijoule energy, single-cycle, long-wavelength IR (3-20 $\mu$m) pulses can be generated by using an 810 nm Ti:sapphire drive laser. Here we extend this idea to the THz frequency regime. We show that sub-joule, terawatts, single-cycle terahertz (2-12 THz, or 150-25 $\mu$m) pulses can be generated by replacing the drive laser with a picosecond 10 $\mu$m CO$_2$ laser and a different shaped plasma structure. The second plasma technique employs frequency upshifting by colliding a CO$_2$ laser with a rather sharp relativistic ionization front created by ionization of a gas in less than half cycle (17 fs) of the CO$_2$ laser. Even though the electrons in the ionization front carry no energy, the frequency of the CO$_2$ laser can be upshifted due to the relativistic Doppler effect as the CO$_2$ laser pulse enters the front. The wavelength can be tuned from 1-10 $\mu$m by simply changing the electron density of the front. While the upshifted light with $5 <\lambda(\mu$m$)< 10$ propagates in the forward direction, that with $1 <\lambda(\mu$m$)< 5$ is back-reflected. These two plasma techniques seem extremely promising for covering the entire molecular fingerprint region., Comment: 7 figures

Published
2020
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2. High-throughput injection-acceleration of electron bunches from a linear accelerator to a laser wakefield accelerator

Author

Wu, Yipeng, Hua, Jianfei, Zhou, Zheng, Zhang, Jie, Liu, Shuang, Peng, Bo, Fang, Yu, Ning, Xiaonan, Nie, Zan, Li, Fei, Zhang, Chaojie, Pai, Chih-Hao, Du, Yingchao, Lu, Wei, Mori, Warren B., and Joshi, Chan

Subjects
Physics - Plasma Physics, Physics - Accelerator Physics
Abstract

Plasma-based accelerators (PBAs) driven by either intense lasers (laser wakefield accelerators, LWFAs) or particle beams (plasma wakefield accelerators, PWFAs), can accelerate charged particles at extremely high gradients compared to conventional radio-frequency (RF) accelerators. In the past two decades, great strides have been made in this field, making PBA a candidate for next-generation light sources and colliders. However, these challenging applications necessarily require beams with good stability, high quality, controllable polarization and excellent reproducibility. To date, such beams are generated only by conventional RF accelerators. Therefore, it is important to demonstrate the injection and acceleration of beams first produced using a conventional RF accelerator, by a PBA. In some recent studies on LWFA staging and external injection-acceleration in PWFA only a very small fraction (from below 0.1% to few percent) of the injected charge (the coupling efficiency) was accelerated. For future colliders where beam energy will need to be boosted using multiple stages, the coupling efficiency per stage must approach 100%. Here we report the first demonstration of external injection from a photocathode-RF-gun-based conventional linear accelerator (LINAC) into a LWFA and subsequent acceleration without any significant loss of charge or degradation of quality, which is achieved by properly shaping and matching the beam into the plasma structure. This is an important step towards realizing a high-throughput, multi-stage, high-energy, hybrid conventional-plasma accelerator.

Published
2020
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3. Region-of-interest micro-focus CT based on an all-optical inverse Compton scattering source

Author

Ma, Yue, Hua, Jianfei, Liu, Dexiang, He, Yunxiao, Zhang, Tianliang, Chen, Jiucheng, Yang, Fan, Ning, Xiaonan, Yang, Zhongshan, Zhang, Jie, Pai, Chih-Hao, Gu, Yuqiu, and Lu, Wei

Subjects
Physics - Applied Physics, Physics - Accelerator Physics
Abstract

Micro-focus computed tomography (CT), enabling the reconstruction of hyperfine structure within objects, is a powerful nondestructive testing tool in many fields. Current X-ray sources for micro-focus CT are typically limited by their relatively low photon energy and low flux. An all-optical inverse Compton scattering source (AOCS) based on laser wakefield accelerator (LWFA) can generate intense quasi-monoenergetic X/gamma-ray pulses in the keV-MeV range with micron-level source size, and its potential application for micro-focus CT has become very attractive in recent years due to the fast pace progress made in LWFA. Here we report the first experimental demonstration of high-fidelity micro-focus CT using AOCS (~70 keV) by imaging and reconstructing a test object with complex inner structures. A region-of-interest (ROI) CT method is adopted to utilize the relatively small field-of-view (FOV) of AOCS to obtain high-resolution reconstruction. This demonstration of the ROI micro-focus CT based on AOCS is a key step for its application in the field of hyperfine nondestructive testing.

Published
2020

4. Relativistic, single-cycle tunable-infrared pulses generated by a tailored plasma density structure

Author

Nie, Zan, Pai, Chih-Hao, Hua, Jianfei, Zhang, Chaojie, Wu, Yipeng, Wan, Yang, Li, Fei, Zhang, Jie, Cheng, Zhi, Su, Qianqian, Liu, Shuang, Ma, Yue, Ning, Xiaonan, He, Yunxiao, Lu, Wei, Chu, Hsu-Hsin, Wang, Jyhpyng, Mori, Warren B., and Joshi, Chan

Subjects
Physics - Plasma Physics, Physics - Optics
Abstract

The availability of intense, ultrashort coherent radiation sources in the infrared region of the spectrum is enabling the generation of attosecond X-ray pulses via high harmonic generation, pump-probe experiments in the "molecular fingerprint" region and opening up the area of relativistic-infrared nonlinear optics of plasmas. These applications would benefit from multi-millijoule single-cycle pulses in the mid to long wavelength infrared (LW-IR) region. Here we present a new scheme capable of producing tunable relativistically intense, single-cycle infrared pulses from 5-14$\mu$m with a 1.7% conversion efficiency based on a photon frequency downshifting scheme that uses a tailored plasma density structure. The carrier-envelope phase (CEP) of the LW-IR pulse is locked to that of the drive laser to within a few percent. Such a versatile tunable IR source may meet the demands of many cutting-edge applications in strong-field physics and greatly promote their development., Comment: 6 figures

Published
2017
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8. Tunable Plasma Linearizer for Compensation of Nonlinear Energy Chirp

Author

Wu, Yipeng, primary, Hua, Jianfei, additional, Zhou, Zheng, additional, Zhang, Jie, additional, Liu, Shuang, additional, Peng, Bo, additional, Fang, Yu, additional, Ning, Xiaonan, additional, Nie, Zan, additional, Tian, Qili, additional, Pai, Chih-Hao, additional, Du, Yingchao, additional, Lu, Wei, additional, Mori, Warren B., additional, and Joshi, Chan, additional

Published
2021
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12. Temporal Characterization of Electron Bunches From Self-Injection and Ionization Injection in a Laser Wakefield Accelerator

Author

Zhang, Jie, He, Yun Xiao, Hua, Jianfei, Liu, De Xiang, Lu, Wei, Ma, Yue, Nie, Zan, Pai, Chih-Hao, Su, Qianqian, and Wu, Yipeng

Subjects
MC3: Novel Particle Sources and Acceleration Techniques, Accelerator Physics
Abstract

Plasma based accelerators (PBAs) have a proven capability to generate high energy electron beams with ultrashort duration (~ 10 fs) and high peak current (~ 10 kA), which opens the opportunity for compact free electron lasers. To meet the requirements of such challenging applications, controllable injection is highly needed to produce high-quality and highly stable electron beams. As we know, the beam parameters,including the current profile, strongly depend on the injection process. To explore the underlying physics and optimize beam parameters in PBAs, a temporal characterization is highly required for different injection schemes. Based on coherent transition radiation(CTR) method, the preliminary experiment to measure beam temporal profiles from both self-injection and ionization injection schemes in a single-shot mode has been performed at Tsinghua University. And the simulations using the similar experimental parameters have been performed to interpret the different injection processes, which show some agreement with the experimental results, especially for the features of bunch durations, Proceedings of the 10th Int. Particle Accelerator Conf., IPAC2019, Melbourne, Australia

Published
2019
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15. Demonstration of Tunable Relativistic, Single-Cycle Infrared Pulses from a Tailored Plasma Structure

Author

Nie, Zan, primary, Pai, Chih-Hao, additional, Zhang, Jie, additional, Ning, Xiaonan, additional, Hua, Jianfei, additional, Zhang, Chaojie, additional, He, Yunxiao, additional, Wu, Yipeng, additional, Su, Qianqian, additional, Liu, Shuang, additional, Ma, Yue, additional, Cheng, Zhi, additional, Lu, Wei, additional, Chu, Hsu-Hsin, additional, Wang, Jyhpyng, additional, Mori, Warren B., additional, and Joshi, Chan, additional

Published
2019
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16. Experimental Demonstration of Energy-Chirp Reduction by a Plasma Dechirper

Author

Wu, Yipeng, Cheng, Zhi, Du, Ying-Chao, Hua, Jianfei, Lu, Wei, Pai, Chih-Hao, Zhang, Jie, Zhou, Shiyu, and Zhou, Zheng

Subjects
03 Novel Particle Sources and Acceleration Techniques, Physics::Plasma Physics, Physics::Accelerator Physics, Accelerator Physics
Abstract

The first experimental study is presented using a low density plasma dechirper to reduce a correlated energy chirp from the 41.5-MeV, 500-fs (RMS) beam at the linac in Tsinghua University. The plasma dechirper operates through the interaction of the electron bunch with its near linear self-wake to dechirp itself, leading to a reduction in energy spread. The experimental results demonstrate that the projected FWHM energy spread of the beam can be reduced from 1.2% to 0.9% with a 12 mm long plasma dechirper, which are in good agreement with full 3D PIC simulations. Theoretical analyses and simulations indicate that by optimizing the plasma density and length, the plasma dechirper can also be used to completely remove the characteristic energy chirp of the ultra-short high-current bunch generated from plasma based accelerator, such that its energy spread can be reduced from one percent level to 0.1 percent level[*]. Application of such a simple and effective method can significantly improve the beam quality and provide the path to realize the future compact free electron lasers and colliders driven by plasma based accelerators., Proceedings of the 8th Int. Particle Accelerator Conf., IPAC2017, Copenhagen, Denmark

Published
2017
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17. Study of High Transformer Ratio Plasma Wakefield Acceleration for Accelerator Parameters of SXFEL Using 3D PIC Simulations

Author

Huang, Shan, An, Weiming, Deng, Haixiao, Hua, Jianfei, Joshi, Chan, Li, Fei, Liu, Bo, Lu, Wei, Mori, Warren, Pai, Chih-Hao, Wan, Yang, Wang, Dong, Wang, Zhen, Wu, Yipeng, Xu, Xinlu, Zhao, Zhentang, and Zhou, Shiyu

Subjects
03 Novel Particle Sources and Acceleration Techniques, Physics::Plasma Physics, Physics::Accelerator Physics, Accelerator Physics
Abstract

High transformer ratio (HTR) Plasma Wakefield Accelerator (PWFA) based on shaped electron bunches is an important topic of plasma wakefield acceleration for future light sources and colliders [1]. To explore the possibility of implementing PWFA at SXFEL, we performed 3D PIC simulations using shaped electron beam parameters obtained by start-to-end beam line simulations [2]. The PIC simulations show that an average transformer ratio around 4 can be maintained for about 10 cm long low density plasma, and the energy gain of the trailing bunch eventually reaches 5.9 GeV. Simulations and analysis are also performed to check the effects of transverse beam size on HTR acceleration. In addition, plasma density downramp injection has also been tested as a possible high brightness injection method for HTR acceleration, and preliminary results will be presented., Proceedings of the 8th Int. Particle Accelerator Conf., IPAC2017, Copenhagen, Denmark

Published
2017
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21. Single-shot visualization of evolving plasma wakefields

Author

Li, Zhengyan, primary, Tsai, Hai-En, additional, Zhang, Xi, additional, Pai, Chih-Hao, additional, Chang, Yen-Yu, additional, Zgadzaj, Rafal, additional, Wang, Xiaoming, additional, Khudik, Vladimir, additional, Shvets, Gennady, additional, and Downer, Michael C., additional

Published
2016
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22. Generating 10–40 MeV high quality monoenergetic electron beams using a 5 TW 60 fs laser at Tsinghua University

Author

Hua, Jian-Fei, primary, Yan, Li-Xin, additional, Pai, Chih-Hao, additional, Zhang, Chao-Jie, additional, Li, Fei, additional, Wan, Yang, additional, Wu, Yi-Peng, additional, Xu, Xin-Lu, additional, Du, Ying-Chao, additional, Huang, Wen-Hui, additional, Chen, Huai-Bi, additional, Tang, Chuan-Xiang, additional, and Lu, Wei, additional

Published
2015
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33. Global optimization of quasi-monoenergetic electron beams from laser wakefield accelerators.

Author

Tsai, Hai-En, Pai, Chih-Hao, and Downer, M. C.

Subjects
*GLOBAL optimization, *ELECTRON beams, *ELECTRON accelerators, *LASER beams, *PARAMETER estimation
Abstract

We globally optimize a terawatt-laser-driven wakefield accelerator by systematically varying laser and target parameters to achieve 100 MeV electrons, 10% energy spread, 100 pC charge, 4 mrad divergence and 10 mrad pointing fluctuation with ∼100% reproducibility, thereby meeting conditions for producing ∼106 200 keV X-ray photons/pulse by inverse Compton scatter. [ABSTRACT FROM AUTHOR]

Published
2012
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