Your search keyword '"Tijian Deng"' showing total 17 results

1. Sparse-View Artifact Correction of High-Pixel-Number Synchrotron Radiation CT

Author

Mei Huang, Gang Li, Rui Sun, Jie Zhang, Zhimao Wang, Yanping Wang, Tijian Deng, and Bei Yu

Subjects

synchrotron radiation CT, spare-view, artifact correction, deep learning, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

High-pixel-number synchrotron radiation computed tomography (CT) has the advantages of high sensitivity, high resolution, and a large field of view. It has been widely used in biomedicine, cultural heritage research, non-destructive testing, and other fields. The Nyquist sampling theorem states that when the detector’s pixels per row are increased, it requires more CT projections, resulting in a lengthened CT scan time and increased radiation damage. Sparse-view CT can significantly reduce radiation damage and improve the projection data acquisition speed. However, there is insufficient sparse projection data, and the slices reconstructed show aliasing artifacts. Currently, aliasing artifact correction processes more medical CT images, and the number of pixels of such images is small (mainly 512×512 pixels). This paper presents an aliasing artifact correction algorithm based on deep learning for synchrotron radiation CT with a high pixel number (1728×1728 pixels). This method crops high-pixel-number CT images with aliasing artifacts into patches with overlapping features. During the network training process, a convolutional neural network is utilized to enhance the details of the patches, after which the patches are reintegrated into a new CT slice. Subsequently, the network parameters are updated to optimize the new CT slice that closely approximates the full-view slice. To align with practical application requirements, the neural network is trained using only three samples to optimize network parameters and applied successfully to untrained samples for aliasing artifact correction. Comparative analysis with typical deep learning aliasing artifact correction algorithms demonstrates the superior ability of our method to correct aliasing artifacts while preserving image details more effectively. Furthermore, the effect of aliasing artifact correction at varying levels of projection sparsity is investigated, revealing a positive correlation between image quality after deep learning processing and the number of projections. However, the trade-off between rapid experimentation and artifact correction remains a critical consideration.

Published

2024

2. Synchrotron radiation X-ray imaging with large field of view and high resolution using micro-scanning method

Author

Rui Sun, Yanping Wang, Jie Zhang, Tijian Deng, Qiru Yi, Bei Yu, Mei Huang, Gang Li, and Xiaoming Jiang

Subjects

synchrotron radiation x-ray imaging, micro-scanning, oversampled image, point spread function (psf), Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798, Crystallography, QD901-999

Abstract

In synchrotron radiation X-ray imaging, the imaging field of view and spatial resolution are mutually restricted, which makes it impossible to have both a large field of view and high resolution when carrying out experiments. Constructing an oversampled image through the micro-scanning method and using the deconvolution algorithm to eliminate the point spread function introduced by pixel overlap can increase the resolution under a fixed imaging field of view, thereby improving the ratio of the field of view to the spatial resolution. In this paper, numerical simulation and synchrotron radiation experiments are carried out with a different number of micro-scanning steps. In numerical simulation experiments only affected by the image pixel size, as the number of micro-scanning steps increases, the ability of the oversampled image with deconvolution to improve the resolution is stronger. The achievable resolution of the oversampled image with deconvolution is basically the same as that of the sample image. In the synchrotron radiation experiments, the resolution of the oversampled image with deconvolution in the 2 × 2 mode is significantly improved. However, as the number of micro-scanning steps increases, the resolution improvement is limited, or even no longer improved. Finally, by analyzing the results of numerical simulation and synchrotron radiation experiments, three factors (four other factors affecting the resolution besides the camera resolution, translational accuracy of micro-scanning, and the signal-to-noise ratio of projections) affecting the micro-scanning method are proposed and verified by experiments.

Published

2022

3. Enhancing Contrast of Spatial Details in X-ray Phase-Contrast Imaging through Modified Fourier Filtering

Author

Bei Yu, Gang Li, Jie Zhang, Yanping Wang, Tijian Deng, Rui Sun, Mei Huang, and Gangjian Guaerjia

Subjects

phase retrieval, propagation phase contrast imaging, Fourier filtering, Applied optics. Photonics, TA1501-1820

Abstract

In-line X-ray phase contrast imaging, which is simple to experiment with, provides significantly higher sensitivity, compared to conventional X-ray absorption imaging. The inversion of the relationship between recorded Fresnel diffraction intensity and the phase shift induced by the object is called phase retrieval. The transport of intensity equation (TIE), a simple method of phase retrieval, which is solved by the fast Fourier transform algorithm proposed by Paganin et al., has been widely adopted. However, the existing method suffers from excessive suppression of high-frequency information, resulting in loss of image details after phase retrieval, or insufficient detail contrast, leading to blurry images. Here, we present a straightforward extension of the two-distance FFT-TIE method by modifying the Fourier filter through the use of a five-point approximation to calculate the inverse Laplacian in a discrete manner. Additionally, we utilize a combination of continuous Fourier transform and a four-point approximation to compute the gradient operator. The method is evaluated by simulating samples with a shape similar to the resolution test map and by using a photograph of a dog for further evaluation. The algorithm that incorporates the modified gradient operator and the algorithm that solely utilizes the continuous Fourier transform for gradient computation were compared with the results obtained using the two-distance FFT-TIE method. The comparisons were conducted using the results obtained from two distances from the sample to the detector. The results show that this method improves the contrast of spatial details and reduces the suppression of high spatial frequencies compared to the two-distance FFT-TIE method. Furthermore, in the low-frequency domain, our algorithm does not lose much information compared to the original method, yielding consistent results. Furthermore, we conducted our experiments using carbon rods. The results show that both our method and the FFT-TIE method exhibit low-frequency distortion due to the requirement of close proximity between the absorption maps and the detector. However, upon closer inspection, our proposed method demonstrates superior accuracy in reproducing the finer details of the carbon rod fibers.

Published

2023

4. Sparse-view CT reconstruction based on fusion learning in hybrid domain

Author

Haolai Tian, Ling Li, Yu Hu, XiaoMeng Qiu, Tijian Deng, Gang Li, and Fazhi Qi

Published

2022

5. Synchrotron radiation X-ray imaging with large field of view and high resolution using micro-scanning method

Author

Rui Sun, Yanping Wang, Jie Zhang, Tijian Deng, Qiru Yi, Bei Yu, Mei Huang, Gang Li, and Xiaoming Jiang

Subjects

Nuclear and High Energy Physics, Radiation, Instrumentation

Abstract

In synchrotron radiation X-ray imaging, the imaging field of view and spatial resolution are mutually restricted, which makes it impossible to have both a large field of view and high resolution when carrying out experiments. Constructing an oversampled image through the micro-scanning method and using the deconvolution algorithm to eliminate the point spread function introduced by pixel overlap can increase the resolution under a fixed imaging field of view, thereby improving the ratio of the field of view to the spatial resolution. In this paper, numerical simulation and synchrotron radiation experiments are carried out with a different number of micro-scanning steps. In numerical simulation experiments only affected by the image pixel size, as the number of micro-scanning steps increases, the ability of the oversampled image with deconvolution to improve the resolution is stronger. The achievable resolution of the oversampled image with deconvolution is basically the same as that of the sample image. In the synchrotron radiation experiments, the resolution of the oversampled image with deconvolution in the 2 × 2 mode is significantly improved. However, as the number of micro-scanning steps increases, the resolution improvement is limited, or even no longer improved. Finally, by analyzing the results of numerical simulation and synchrotron radiation experiments, three factors (four other factors affecting the resolution besides the camera resolution, translational accuracy of micro-scanning, and the signal-to-noise ratio of projections) affecting the micro-scanning method are proposed and verified by experiments.

Published

2021

6. Long-time measurements of line-integrated plasma electron density using a two-color homodyne optical fiber interferometer

Author

A.D. Liu, Chijin Xiao, Hangqi Xu, Weixing Ding, Zian Wei, Shijie Lan, Junfeng Zhu, Hong Li, Defeng Kong, Yao Yuan, Chu Zhou, Xiaohui Wen, Chen Chen, Jie Wu, Tao Lan, Hai Wang, Zhengwei Wu, Sen Zhang, Jiaren Wu, Ge Zhuang, Yiming Zu, Wandong Liu, Shoubiao Zhang, Peng Yuan, Jinlin Xie, Haiyang Zhou, Tijian Deng, and Wenzhe Mao

Subjects

Electron density, Materials science, Optical fiber, business.industry, Resolution (electron density), Astrophysics::Instrumentation and Methods for Astrophysics, Physics::Optics, Torus, Plasma, law.invention, Interferometry, Wavelength, Optics, law, Demodulation, business, Instrumentation

Abstract

A two-color homodyne Mach–Zehnder (M–Z) optical fiber interferometer with wavelengths of 1.55 and 1.31 µm was developed for long-time measurement of line-integrated plasma electron density. A novel phase difference demodulation algorithm based on a single 3 × 3 optical coupler was implemented in a two-color optical fiber interferometer scheme for the first time. Our laboratory tests showed that this new optical fiber interferometer could determine the phase shift due to the low-frequency ambient vibration and could maintain high phase resolution measurement. The resolution of the new interferometer was less than 0.04 rad in 1000 s, corresponding to a line-averaged electron density of less than 1.0 × 1019 m−2. Actual plasma discharge experiments performed on KTX-CTI, which is a new compact torus injector (CTI) constructed at the Keda Torus eXperiment (KTX), showed that this interferometer has excellent several-second stability.

Published

2021

7. MHD Mode Analysis Using the Unevenly Spaced Mirnov Coils in the Keda Torus eXperiment

Author

Tao Lan, Weixing Ding, Chijin Xiao, Tijian Deng, Wenzhe Mao, Cui Tu, Jinlin Xie, Mingsheng Tan, Bing Luo, Wandong Liu, Adi Liu, Ge Zhuang, Hong Li, and Zichao Li

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Sideband, Torus, Plasma, Condensed Matter Physics, 01 natural sciences, Discrete Fourier transform, 010305 fluids & plasmas, law.invention, Matrix decomposition, Computational physics, Physics::Plasma Physics, law, 0103 physical sciences, Singular value decomposition, Magnetohydrodynamics

Abstract

Due to the discrete nature of the saddle coils for the active feedback control of the plasma instabilities, the emergence of the sideband modes is inevitable. In the Keda Torus eXperiment (KTX), the edge Mirnov coils are unevenly distributed on the inner surface of the vacuum vessel to suppress the sideband modes. These arrays of the Mirnov coils are used for the feedback control system of KTX. They are also used for the magnetohydrodynamics (MHD) mode identification, which is a fundamental and significant method to distinguish and describe the plasma instabilities. A set of suitable MHD mode analysis methods has been utilized to complete the mode detection, including the spatial discrete Fourier transform (SDFT) method, the singular value decomposition (SVD) method and the Lomb periodogram method. These methods can obtain comprehensive mode information of the plasma instabilities and their results can be used as the feedback of the feedback control system. These methods have been successfully applied to detect and characterize an impulsive mode of ( $m = 1$ , $n = 0$ ) and rotating modes of ( $m = 2$ , 3, 4, $n = 1$ ) in the tokamak plasma of KTX, while the matrix decomposition technique is not applicable for KTX.

Published

2019

8. Optical fiber interferometer application for high electron density measurements on compact torus plasmas

Author

Hangqi Xu, Xiaohui Wen, Hong Li, Weixing Ding, Sen Zhang, A.D. Liu, Junfeng Zhu, Yiming Zu, Shoubiao Zhang, Hai Wang, Defeng Kong, Wandong Liu, Jiaren Wu, Yao Yuan, Jie Wu, Z. X. Liu, Haiyang Zhou, Zian Wei, Ge Zhuang, Chen Chen, Tao Lan, Tijian Deng, Wenzhe Mao, Jinlin Xie, Shijie Lan, and Chijin Xiao

Subjects

Accuracy and precision, Optical fiber, Materials science, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Physics::Optics, Torus, Plasma, law.invention, Time of flight, Interferometry, Wavelength, Optics, law, Phase noise, business, Instrumentation

Abstract

An optical fiber Mach-Zehnder interferometer at a wavelength of 1.55 µm has been developed for measurements of high electron density on compact torus (CT) plasmas with a high time resolution of 0.1 µs and high phase resolution of 6.4 × 10-4 rad. To improve density measurement accuracy, the phase noise of the interferometer has been investigated in detail and optimized. In the bench test, the interferometer was calibrated using a piezoelectric ceramic actuator with known stroke. Initial results on CT plasma show that the optical fiber interferometer provides reliable density measurements at two spatial locations and the bulk velocity of plasma can be determined by the method of time of flight.

Published

2020

9. Design of a Feedback Control System for Keda Torus Experiment Equilibrium Field Power Supply

Author

Junfeng Zhu, Lei Yang, Haiyang Zhou, P. Fu, Bing Luo, Jinlin Xie, Hai Wang, Weixing Ding, Tao Lan, Chijin Xiao, Wei Bai, Hangqi Xu, Shude Wan, Wandong Liu, Wei You, Tijian Deng, Wenzhe Mao, Adi Liu, Xiaohui Wen, and Hong Li

Subjects

Nuclear and High Energy Physics, Reversed field pinch, Field (physics), Mechanical Engineering, Torus, Plasma, H bridge, 01 natural sciences, 010305 fluids & plasmas, Power (physics), Nuclear Energy and Engineering, Control theory, 0103 physical sciences, Horizontal position representation, General Materials Science, 010306 general physics, Civil and Structural Engineering, Mathematics

Abstract

An equilibrium field (EQ) power supply (PS) circuit using a feedback H-bridge pulse-width-modulation controller has been developed to control the plasma horizontal position and to satisfy the requi...

Published

2017

10. Fluctuation-induced inward particle flux during L–I–H transition on HL-2A tokamak

Author

H. Li, H.G. Sheng, Jie Wu, Changxuan Yu, Xuan Sun, Jun Cheng, Junfeng Zhu, M. Xu, J. L. Xie, L. Nie, Weixing Ding, Longwen Yan, Wei Chen, Jiaren Wu, Xuru Duan, Tao Lan, Hangqi Xu, Tijian Deng, Wenzhe Mao, A. D. Liu, Liming Yu, Sijing Zhang, Ge Zhuang, Weihao Liu, and Ying Yu

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, law, Atomic physics, Condensed Matter Physics, Particle flux, law.invention

Abstract

The inward particle flux associated with the global long-lived mode (LLM) during the L–I–H transition on HL-2A tokamak has been measured. The inward particle flux arises from the phase change between density and radial velocity fluctuations, where density and velocity fluctuations are strongly correlated with magnetic fluctuations of LLM. Moreover, the radial velocity and its gradient rather than poloidal flow shear play an important role in particle transport associated with the large-scale mode. The strong nonlinear coupling between LLM and ambient turbulence has been confirmed, and this may contribute to most of the inward particle flux in the LLM during the I-phase state.

Published

2021

11. Fast radial scanning probe system on KTX

Author

Tijian DENG, Tao LAN, Mingsheng TAN, Junfeng ZHU, Jie WU, Hangqi XU, Chen CHEN, Yolbarsop ADIL, Sen ZHANG, Jiaren WU, Yiming ZU, Wenzhe MAO, Hong LI, Jinlin XIE, Ahdi LIU, Zixi LIU, Zhengwei WU, Hai WANG, Xiaohui WEN, Haiyang ZHOU, Zian WEI, Chijin XIAO, Weixing DING, Ge ZHUANG, and Wandong LIU

Subjects

Electron density, Optics, Materials science, business.industry, Resolution (electron density), Plasma, Condensed Matter Physics, business, Image resolution

Published

2020

12. Observation of inward transport flux accompanied with the long-lived mode during the L-H transition in the HL-2A tokamak

Author

Jun Cheng, Hangqi Xu, Junfeng Zhu, Tao Lan, H. Li, Tijian Deng, Jiaren Wu, Wenzhe Mao, Xuru Duan, Xuan Sun, L. Nie, Weixing Ding, Weihao Liu, Ge Zhuang, Ying Yu, W. Chen, J. L. Xie, Sijing Zhang, Changxuan Yu, Jie Wu, Longwen Yan, Liming Yu, M. Xu, and A. D. Liu

Subjects

Physics, Electron density, Tokamak, Condensed matter physics, Flux, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Radial velocity, symbols.namesake, Heat flux, law, Electric field, 0103 physical sciences, symbols, Electron temperature, Langmuir probe, 010306 general physics

Abstract

The inward transport flux accompanied by the long-lived mode (LLM) has been observed by the edge Langmuir probe array during the L-H transition in the HL-2A tokamak. The cross phase between the poloidal electric field fluctuation and the electron density fluctuation in the LLM frequency changed greatly during the L-H transition, which led to the radial transport flux in the LLM frequency to change its transport direction in a given radial region near the pedestal barrier. By using the long distance correlation method, the phase shift of poloidal electric field fluctuation proved to be the key reason, which led to the cross-phase term to change in the LLM frequency. Furthermore, the shear effect has a mode-selecting characteristic on the LLM and turbulence because the direction of turbulent transport still remains radially outward during the H-mode. In addition, when the inward conducted heat flux accompanied by LLM occurs, the poloidal electric field fluctuation and electron temperature fluctuation both have a positive gradient in the LLM frequency; this may indicate that the positive gradient of radial velocity and electron temperature in the LLM frequency play an important role during the entire transport direction change process.

Published

2020

13. Coupling circuit model and discharge waveform prediction for Keda Torus eXperiment

Author

Shude Wan, Weixing Ding, Chijin Xiao, Cui Tu, Bin Luo, Tijian Deng, Wenzhe Mao, Lei Yang, A.D. Liu, Wandong Liu, Hai Wang, Haiyang Zhou, Wei Bai, Hangqi Xu, Chenguang Li, Mingsheng Tan, Jinlin Xie, Wei You, Xiaohui Wen, Junfeng Zhu, Chengshuo Fu, Tao Lan, Hong Li, Fangchen Huang, and P. Fu

Subjects

Physics, Toroid, Reversed field pinch, Mechanical Engineering, Torus, Mechanics, Magnetic field, Nuclear magnetic resonance, Nuclear Energy and Engineering, Physics::Plasma Physics, Power Balance, Pinch, Waveform, General Materials Science, Civil and Structural Engineering, Voltage

Abstract

A poloidal and toroidal magnetic field coupling circuit model is developed to simulate discharge waveforms of the Keda Torus eXperiment (KTX) reversed field pinch (RFP) to ensure that the design of the power supply systems is able to achieve the typical discharge parameters. The radial profiles of plasma current density and magnetic field used in the coupling model are characterized by modified Bessel function model (MBFM) derived from the well-known Taylor's theory. The power balance in the energy conservation of poloidal and toroidal fields is used to establish the connection between these two fields. The numerical solutions of the coupling show that the KTX power supply system is capable of achieving the designed discharge parameters, such as field reversal parameter ( F ), pinch parameter (Θ), magnetic field, plasma current and loop voltage. Furthermore, the delay of magnetic field penetration due to the effect of vacuum vessel is also considered in the model.

Published

2015

14. Overview of Keda Torus eXperiment initial results

Author

Tijian Deng, Wenzhe Mao, Bing Luo, Chenshuo Fu, Chenguang Li, Bingjia Xiao, Qingxi Yang, Tao Lan, Zhengping Luo, Wei You, Weixing Ding, Junfeng Zhu, J. Q. Hu, Jinlin Xie, Ping Zhang, P. Fu, A.D. Liu, Yolbarsop Adil, Wei Bai, Hangqi Xu, Cui Tu, Haiyang Zhou, Lei Yang, Hai Wang, Yuntao Song, Shude Wan, Biao Shen, Huazhong Wang, Sen Zhang, Jinxing Zheng, Fangcheng Huang, Jian Zheng, Chijin Xiao, Hong Li, Hao Xu, Xiaohui Wen, Wandong Liu, and Mingsheng Tan

Subjects

Physics, construction, Nuclear and High Energy Physics, Reversed field pinch, Nuclear engineering, Thyristor, conditioning, reversed field pinch, Pulsed power, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Capacitor, Electromagnetic coil, law, 0103 physical sciences, Vacuum pump, Vacuum chamber, 010306 general physics, Joule heating

Abstract

The Keda Torus eXperiment (KTX) is a new reversed field pinch (RFP) device at the University of Science and Technology of China. The construction and assembly of KTX, including the vacuum chamber, conducting shell, magnetic field windings, power supply system, active control coils, vacuum pump and data acquisition system, have been completed on August 1, 2015. Immediately following that, the first plasma was obtained on August 15, 2015. Intensive conditioning of the machine is underway to ramp up the plasma current toward its full operation. An active feedback mode control system has been built and has been implemented to control the error field around the vertical gaps of the conducting shell. The pulsed power supply systems of ohmic heating field and toroidal field (TF), using thyristor and energy storage capacitors, have been tested and commissioned. The TF power supply has flexibility in being able to operate with a reversed TF configuration and stable TF configuration. The fundamental diagnostic tools are developed for early KTX operation. Currently, the plasma current is up to 205 kA and the maximum discharge length is 21 ms, approaching to the conducting shell penetration time. Furthermore, typical RFP discharges are being produced with RFP state lasting 2 ms. These initial operation results for KTX are described in detail.

Published

2017

15. A parametric method for correcting polluted plasma current signal and its application on Keda Torus eXperiment

Author

Chijin Xiao, Tijian Deng, Wenzhe Mao, Sen Zhang, Zhengwei Wu, Junfeng Zhu, Xiaohui Wen, Hangqi Xu, Wandong Liu, Jinlin Xie, A.D. Liu, Weixing Ding, Yiming Zu, Hong Li, Jie Wu, Yolbarsop Adil, Hai Wang, Jiaren Wu, Zian Wei, Haiyang Zhou, Chen Chen, Z. X. Liu, Ge Zhuang, Mingsheng Tan, and Tao Lan

Subjects

010302 applied physics, Physics, Toroid, Reversed field pinch, Torus, Plasma, 01 natural sciences, 010305 fluids & plasmas, Computational physics, Magnetic field, Physics::Plasma Physics, Electromagnetic coil, 0103 physical sciences, Vacuum chamber, Instrumentation, Rogowski coil

Abstract

We have developed a parametric method for eliminating the background component of the plasma current, which is measured by a Rogowski coil and polluted by the toroidal magnetic field in the vacuum vessel of the Keda Torus eXperiment (KTX) reversed field pinch (RFP) device. The method considers the toroidal magnetic field windings, the KTX vacuum chamber, and the Rogowski coil as a linear time-invariant system; in this case, a constant frequency response function characterizes the system. Using this response function, the current component caused by pollution from the toroidal magnetic field can be predicted exactly for an arbitrary input current to the toroidal magnetic field windings. Compared with the traditional proportional compensation method, the proposed method has great flexibility and universality and it is potentially applicable to cases in which the toroidal field current signal changes over time with plasma feedback signals. Furthermore, the method can be applied to other similarly affected signals, such as magnetic field signals. As an example, we have corrected the poloidal and toroidal magnetic field signals better to reveal the true physical processes for the RFP state.

Published

2019

16. Construction of an H α diagnostic system and its application to determine neutral hydrogen densities on the Keda Torus eXperiment*

Author

Tao Lan, Yiming Zu, Zhengwei Wu, Chen Chen, A.D. Liu, Hangqi Xu, Junfeng Zhu, Weixing Ding, Hai Wang, Chijin Xiao, Jinlin Xie, Jie Wu, Jiaren Wu, Liu Wandong, Z. X. Liu, Haiyang Zhou, Sen Zhang, Hong Li, Ge Zhuang, Xiaohui Wen, and Tijian Deng

Subjects

Physics, Hydrogen, Analytical chemistry, General Physics and Astronomy, chemistry.chemical_element, Alpha (ethology), Torus, Plasma, Diagnostic system, symbols.namesake, chemistry, symbols, Langmuir probe, Electron temperature, Neutral density filter

Abstract

A 10-channel H α diagnostic system has been designed with the rapid response rate of 300 kHz, spatial resolution of about 40 mm, and overlap between adjacent channels of about 3%, and it has been implemented successfully on Keda Torus eXperiment (KTX), a newly constructed, reversed field pinch (RFP) experimental device at the University of Science and Technology of China (USTC). This diagnostic system is a very important tool for the initial KTX operations. It is compact, with an aperture slit replacing the traditional optical lens system. A flexural interference filter is designed to prevent the center wavelength from shifting too much as the increase of angle from vertical incidence. To eliminate the stray light, the interior of the system is covered with the black aluminum foil having a very high absorptivity. Using the H α emission data, together with the profiles of electron temperature and density obtained from the Langmuir probe, the neutral density profiles have been calculated for KTX plasmas. The rapid response rate and good spatial resolution of this H α diagnostic system will be beneficial for many studies in RFP plasma physics.

Published

2019

17. An overview of diagnostic upgrade and experimental progress in the KTX

Author

Weixing Ding, Cui Tu, Haiyang Zhou, Shude Wan, Z. X. Liu, Yiming Zu, Jiaren Wu, Zian Wei, Wei You, Chen Chen, Tijian Deng, Wenzhe Mao, Sen Zhang, Wandong Liu, Chijin Xiao, Bing Luo, Jinlin Xie, Ge Zhuang, Yolbarsop Adil, A.D. Liu, Hangqi Xu, Jian Zheng, Hai Wang, Tao Lan, Mingsheng Tan, Peng Yuan, Zhengwei Wu, Junfeng Zhu, Hong Li, Zichao Li, and Xiaohui Wen

Subjects

Physics, Nuclear and High Energy Physics, Upgrade, Systems engineering, Soft X-radiation, Condensed Matter Physics

Abstract

The Keda Torus eXperiment (KTX) is still operated in the commissioning phase, and preparation for the operation capability of the KTX phase II upgrade is underway. The diagnostics in the KTX have been greatly developed: (1) the terahertz interferometer has been upgraded to seven chords for electron density profile inversion; (2) a Thomson scattering system with a 5 Joule laser has been installed and commissioning is in progress; (3) a 3D movable probe system has been developed for the electromagnetic turbulence measurement; (4) double-foil soft x-ray imaging diagnostics have been set up and a bench test has been completed; (5) an edge capacitive probe has been installed for the radial electrical field measurement; (6) a multi-channel spectrograph system has been built for detecting impurities of carbon and oxygen. In addition, the design of a new compact torus injection system has been completed for feeding and momentum driving. Pilot research, such as the 3D reversed field pinch physics and electromagnetic turbulence, etc, have been conducted in the discharge status of the KTX. The 3D spectra characters of electromagnetic turbulence are firstly measured using a classical two-point technique by Langmuir probe arrays set on the 3D movable probe system and edge magnetic sensors. The forward scattering is collected by the interferometer system, which shows the potential for turbulence research. The electromagnetic turbulence is tentatively investigated in the KTX. The formation of a quasi-single-helicity state in the KTX regime is also preliminarily explored in simulation.

Published

2019