Development of a CO2 laser collective scattering system on HL-2A tokamak

doi:10.16568/j.0254-6086.202402001

Nuclear Fusion and Plasma Physics ›› 2024, Vol. 44 ›› Issue (2): 125-132.DOI: 10.16568/j.0254-6086.202402001

• Nuclear Fusion Engineering • Next Articles

Development of a CO₂ laser collective scattering system on HL-2A tokamak

WEN Ruo-nan¹, YAO Ke¹, LIU Yi¹, XU Yu-hong², SHI Zhong-bin¹, ZHONG Wu-lü¹

(1. Southwestern Institute of Physics, Chengdu 610041; 2. Institute of Fusion Science and Technology, Southwest Jiaotong University, Chengdu 610031)

Received:2022-04-02 Revised:2023-09-26 Online:2024-06-15 Published:2024-06-11

HL-2A装置二氧化碳激光相干散射系统的研制

文若楠¹，姚可¹，刘仪¹，许宇鸿²，石中兵¹，钟武律¹

(1. 核工业西南物理研究院，成都 610041； 2. 西南交通大学聚变科学与技术研究所，成都 610031)

作者简介:文若楠(1997-)，男，四川泸州人，硕士研究生，从事等离子体激光诊断研究。
基金资助:
国家自然科学基金委面上项目(11875018)

Abstract

Abstract: A CO₂ laser coherent scattering diagnostic system was successfully developed on the HL-2A tokamak. The tangential optical path layout which can improve the spatial resolution of the system and a dual-channel homodyne detection design were adopted. The two channels can simultaneously measure the small-scale turbulent changes of the plasma core (ρ≈0.28) with wavenumber in the range of 10~45cm⁻¹. The wave number resolution is ±3cm⁻¹ and the time resolution is 0.5μs. The system can provide important data for the study of plasma core transport. In addition, the main beam and the local oscillator beam of the diagnostic system pass through the plasma at the same time, which can also detect various large-scale plasma fluctuations in the core. The analysis of the diagnostic signals indicates that the system can accurately respond to the evolution of the small-scale turbulence in the plasma core, and also provide useful information for studying the macro-instability in the core area of plasma.

Key words: Laser collective scattering, Density fluctuation, Short-scale turbulence

摘要： 在HL-2A装置上成功研制了一套CO₂激光相干散射诊断系统，采用了能提高系统空间分辨的切向布局以及双通道的零差式探测设计。两个通道能够同时测量等离子体芯部(ρ≈0.28)波数在10~45cm⁻¹范围中小尺度的湍流变化，其波数分辨率为±3cm⁻¹，时间分辨率为0.5 QUOTE μs，能够为等离子体芯部输运研究提供重要数据。此外，由于本诊断系统采用的是主光束与本振光束同时穿过等离子体的光路设计，它还能够探测到等离子体芯部的大尺度宏观等离子体扰动。诊断信号的分析结果显示该系统可以准确地响应等离子体芯部小尺度湍流的变化，同时也能够为芯部宏观不稳定研究提供诊断数据。

关键词: 激光相干散射, 密度扰动, 小尺度湍流

CLC Number:

TL65⁺3

WEN Ruo-nan, YAO Ke, LIU Yi, XU Yu-hong, SHI Zhong-bin, ZHONG Wu-lü. Development of a CO₂ laser collective scattering system on HL-2A tokamak[J]. Nuclear Fusion and Plasma Physics, 2024, 44(2): 125-132.

文若楠, 姚可, 刘仪, 许宇鸿, 石中兵, 钟武律. HL-2A装置二氧化碳激光相干散射系统的研制[J]. 核工业西南物理研究院, 2024, 44(2): 125-132.

References

[1] Conner J W, Wilson H R. Survey of theories of anomalous transport [J]. Plasma Physics & Controlled Fusion, 1994, 36(5): 719.
[2] Durst R D, Fonck R J, Cosby G, et al. Density fluctuation measurements via beam emission spectroscopy (invited) [J]. Review of Scientific Instruments, 1992, 63(10): 4907.
[3] Deng B H, Hsia R P, Domier C W, et al. Electron cyclotron emission imaging diagnostic system for Rijnhuizen Tokamak Project [J]. Review of Scientific Instruments, 1999, 70(1): 998.
[4] Young P E, Neikirk D P, Tong P P, et al. Multichannel far-infrared phase imaging for fusion plasmas [J]. Review of Scientific Instruments, 1985, 56(1): 81.
[5] Crowley T P. Rensselaer heavy ion beam probe diagnostic methods and techniques [J]. Plasma Science, IEEE Transactions on, 1994, 22(4): 291.
[6] Behn R, Dicken D, Hackmann J, et al. Ion temperature measurement of tokamak plasmas by collective Thomson scattering of D2O laser radiation [J]. Physical Review Letters, 1989, 62(24): 2833.
[7] Mazzucato E. Detection of short-scale turbulence in the next generation of tokamak burning plasma experiments [J]. Plasma Physics & Controlled Fusion, 2006, 48(12): 1749.
[8] Surko C M, Slusher R E, Moler D R, et al. 10.6-μm laser scattering from cyclotron-harmonic waves in a plasma [J]. Physical Review Letters, 1972, 29(2): 81.
[9] Surko C M, Slusher R E. Study of the density fluctuations in the adiabatic toroidal compressor scattering tokamak using CO₂ laser [J]. Physical Review Letters, 1976, 37(26): 1747.
[10] Cao G M, Li Y D, Li Q, et al. A tangential CO₂ laser collective scattering system for measuring short-scale turbulent fluctuations in the EAST superconducting tokamak [J]. Fusion Engineering & Design, 2014, 89(12): 3016.
[11] Andel H W H V, Boileau A, Hellerman M V. Study of microturbulence in the TEXTOR tokamak using CO₂ laser scattering [J]. Plasma Physics & Controlled Fusion, 2000, 29(1): 49.
[12] Truc A, Quéméneur A, Hennequin P, et al. ALTAIR: An infrared laser scattering diagnostic on the TORE SUPRA tokamak [J]. Review of Scientific Instruments, 1992, 63(7): 3716.
[13] Simone P D, Frigione D, Orsitto F. Density fluctuations measurement on FT Tokamak by CO₂ coherent scattering [J]. Plasma Physics and Controlled Fusion, 1986, 28(5): 751.
[14] Chang L, Zeng L, Cao J, et al. Study of microturbulence on the KT-5 tokamak by CO₂ laser scattering [J]. Chinese Physics Letters, 1990, 7(1): 4.
[15] Zeng L, Cao J, Zhu G, et al. Density fluctuation in HT-6M tokamak by CO₂ laser scattering [J]. Proceedings of SPIE-The International Society for Optical Engineering, 1993, 1928(10): 293.
[16] Li Y, Li J, Mao J. CO₂ laser collective thomson scattering diagnostics on the HT-7 tokamak [J]. Plasma Science & Technology, 2004, 6(6): 2526.
[17] Li Y, Li J, Zhang X, et al. High wavenumber density fluctuation measurement in the HT-7 tokamak [J]. Plasma Science and Technology, 2009, 11(5): 529.
[18] 曹光明. EAST托卡马克装置上电子模湍流多尺度物理特性的实验研究 [D]. 合肥: 中国科学院大学, 2015.
[19] Mazzucato E. Density fluctuations in the adiabatic toroidal compressor [R]. United States: Princeton Plasma Physics Lab, 1975.
[20] Slusher R E, Surko C M. Study of density fluctuations in plasmas by small-angle CO₂ laser scattering [J]. Physics of Fluids, 1980, 23(3): 472.
[21] Mazzucato E. Localized measurement of turbulent fluctuations in tokamaks with coherent scattering of electromagnetic waves [J]. Physics of Plasmas, 2003, 10(3): 753.
[22] Kolmogorov A N. The local structure of turbulence in incompressible viscous fluid for very large reynolds numbers [J]. Proceedings of the Royal Society A: Mathematical, 1991, 434(1890): 9.
[23] Ding W X. Density fluctuation measurements by far-forward collective scattering in the MST reversed-field pinch [J]. Review of Scientific Instruments, 2012, 83(10): 058101.

Development of a CO₂ laser collective scattering system on HL-2A tokamak

HL-2A装置二氧化碳激光相干散射系统的研制

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 3

Recommended Articles

Metrics

[1]	WU Yi-fan1, 2, YU Yi1, 2, KE Rui2, XU Min2, NIE Lin2, WU Ting2, SUN Ai-ping2, LAN Tao1, YUAN Bo-da1, 2, LIU Hao1, 2, GONG Shao-bo1, 2, LONG Ting2, DUAN Xu-ru2, YE Min-you1, HL-2A team2. Development and test of the beam emission spectroscopy diagnostic based on neutral beam injection on HL-2A tokamak [J]. NUCLEAR FUSION AND PLASMA PHYSICS, 2020, 40(3): 200-207.
[2]	WU Ming-fu1, 2, WEN Fei2, XIANG Hao-ming1, 2, ZHANG Tao2, LIU Zi-xi1, WANG Yu-ming2, LI Gong-shun3, 4, GENG Kang-ning1, 2, ZHONG Fu-bin1, 2, YE Kai-xuan1, 2, HUANG Jia1, 2, HAN Xiang2, ZHANG Shou-biao2 , GAO Xiang1, 2. Development of a W-band multi-channel poloidal correlation reflectometry on EAST [J]. NUCLEAR FUSION AND PLASMA PHYSICS, 2020, 40(3): 241-247.
[3]	HU Shi-lin1, LI Ji-quan1, 2. Negative viscosity damping of zonal flows in tokamak edge turbulence [J]. NUCLEAR FUSION AND PLASMA PHYSICS, 2017, 37(2): 125-130.