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Jiaxing XIE, Xuechao WEI, Haiqing LIU, Songjian LI, Jibo ZHANG, Yuan YAO, Yunfei WANG, Yinxian JIE. Development of a combined interferometer using millimeter wave solid state source and a far infrared laser on ENN's XuanLong-50 (EXL-50)[J]. Plasma Science and Technology, 2022, 24(6): 064004. DOI: 10.1088/2058-6272/ac5e72
Citation: Jiaxing XIE, Xuechao WEI, Haiqing LIU, Songjian LI, Jibo ZHANG, Yuan YAO, Yunfei WANG, Yinxian JIE. Development of a combined interferometer using millimeter wave solid state source and a far infrared laser on ENN's XuanLong-50 (EXL-50)[J]. Plasma Science and Technology, 2022, 24(6): 064004. DOI: 10.1088/2058-6272/ac5e72

Development of a combined interferometer using millimeter wave solid state source and a far infrared laser on ENN's XuanLong-50 (EXL-50)

  • A millimeter wave solid state source—far infrared laser combined interferometer system (MFCI) consisting of a three-channel 890 GHz hydrogen cyanide (HCN) laser interferometer and a three-channel 340 GHz solid state source interferometer (SSI) is developed for real-time line-integrated electron density feedback and electron density profile of the EXL-50 spherical tokamak device. The interferometer system is a Mach–Zehnder type, with all probe-channels measured vertically, covering the plasma magnetic axis to the outermost closed magnetic plane. The HCN laser interferometer uses an HCN laser with a frequency of 890 GHz as a light source and modulates a 100 kHz beat signal by a rotating grating, giving a temporal resolution of 10 μs. The SSI uses two independent 340 GHz solid-state diode sources as the light source, the frequency of the two sources is adjustable, and the temporal resolution of SSI can reach 1 μs by setting the frequency difference of the two lasers at 1 MHz. The main optical path of the two interferometers is compactly installed on a set of double-layer optical platform directly below EXL-50. Dual optical path design using corner cube reflectors avoids the large support structures. Collinear the probe-beams of two wavelengths, then the phase error caused by vibration can be compensated. At present, the phase noise of the HCN Interferometer is 0.08 rad, corresponding to a line-integrated electron density of 0.88×1017 m-2, one channel of measuring result was obtained by the MFCI system, and the highest density measured is about 0.7×1019 m-2.
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