Saturated cavity ringdown spectroscopy at Balmer-α line of atomic hydrogen for estimating sheath electric field in plasma

IF 1.3 4区工程技术 Q3 INSTRUMENTS & INSTRUMENTATION Journal of Instrumentation Pub Date : 2023-10-01 DOI:10.1088/1748-0221/18/10/c10002

Kimika Fushimi, Shusuke Nishiyama, Satoshi Tomioka, Koichi Sasaki

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Abstract

Abstract We applied saturated cavity ringdown spectroscopy (CRDS) to the measurement of the Doppler-free absorption spectrum of the Balmer-α line of atomic hydrogen in an inductively coupled hydrogen plasma. The spectrum was used for estimating the electric field in the sheath region in the vicinity to a biased electrode. The absorption frequency (the absorption coefficient multiplied by the speed of light) and the saturation parameter were estimated by fitting the experimental ringdown curve with the theory reported by Giusfredi and coworkers ( Phys. Rev. Lett. 104 (2010) 110801). We detected the Lamb dip corresponding to the 2 p 2 P o 3/2 - 3 d 2 D 5/2 transition in the absorption spectrum in the field-free condition. We observed the change in the Lamb dip spectrum when we repeated the measurement in the sheath, and we succeeded in estimating the sheath electric field of 220–230 V/cm at a distance of 1.8 mm from the electrode which was biased at -100 V with respect to the ground potential. The experimental results indicate the potential of saturated CRDS for the measurement of sheath electric fields in plasmas.

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氢原子Balmer-α线饱和腔衰荡光谱估计等离子体鞘层电场

摘要应用饱和腔衰荡光谱(CRDS)测量了电感耦合氢等离子体中氢原子Balmer-α谱线的无多普勒吸收光谱。该光谱用于估计偏置电极附近鞘层区域的电场。吸收频率(吸收系数乘以光速)和饱和度参数通过拟合实验衰荡曲线和Giusfredi及其同事(物理学家)所报告的理论来估计。Rev. Lett. 104(2010) 110801)。在无场条件下，我们检测到吸收光谱中的2p2p3 /2 - 3d2d5 /2跃迁对应的Lamb倾角。当我们在鞘层中重复测量时，我们观察到了Lamb dip光谱的变化，我们成功地估计了在距离电极1.8 mm处鞘层电场为220-230 V/cm，相对于地电位偏置为-100 V。实验结果表明，饱和CRDS具有测量等离子体鞘层电场的潜力。

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来源期刊

Journal of Instrumentation 工程技术-仪器仪表

CiteScore

2.40

自引率

15.40%

发文量

827

审稿时长

7.5 months

期刊介绍： Journal of Instrumentation (JINST) covers major areas related to concepts and instrumentation in detector physics, accelerator science and associated experimental methods and techniques, theory, modelling and simulations. The main subject areas include. -Accelerators: concepts, modelling, simulations and sources- Instrumentation and hardware for accelerators: particles, synchrotron radiation, neutrons- Detector physics: concepts, processes, methods, modelling and simulations- Detectors, apparatus and methods for particle, astroparticle, nuclear, atomic, and molecular physics- Instrumentation and methods for plasma research- Methods and apparatus for astronomy and astrophysics- Detectors, methods and apparatus for biomedical applications, life sciences and material research- Instrumentation and techniques for medical imaging, diagnostics and therapy- Instrumentation and techniques for dosimetry, monitoring and radiation damage- Detectors, instrumentation and methods for non-destructive tests (NDT)- Detector readout concepts, electronics and data acquisition methods- Algorithms, software and data reduction methods- Materials and associated technologies, etc.- Engineering and technical issues. JINST also includes a section dedicated to technical reports and instrumentation theses.