A new ground-based expenmental device,the Space Plasma Environment Research Facility(SPERF),is being designed at Harbin Institute of Technology in China,with Asymmetric REconnection eXperiment-3 Dimensional(AREX-3D...A new ground-based expenmental device,the Space Plasma Environment Research Facility(SPERF),is being designed at Harbin Institute of Technology in China,with Asymmetric REconnection eXperiment-3 Dimensional(AREX-3D) as one of the experimental components to study the asymmetric reconnection dynamics relevant to the interaction between the interplanetary and magnetospheric plasmas.The asymmetry in the designed magnetic reconnection process not only refers to the distinct plasma parameters designed for the two upstream regions across the current sheet,but also refers to the inhomogeneity in the direction along the current sheet resulting from the designed 3D magnetic field geometry.These two asymmetries are fundamental features of the reconnection process at the Earth's magnetopause.In experiment,the reconnection process is driven by a set of flux cores through coil-currentramp-up from the 'magnetosheath-side' to interact with a dipole magnetic field generated by the Dipole Research Experiment(DREX) coil on the 'magnetosphere-side'.The AREX-3D will be able to investigate a range of important reconnection issues in 3D magnetic field geometry that is relevant to the Earth's magnetopause.A wide range of plasma parameters can be achieved through inductive plasma generation with flux cores on the 'magnetosheath-side' and electron cyclotron resonance(ECR) with microwave sources on the 'magnetosphere-side',e.g.high(low)plasma density at experimental magnetosheath(dipole) side.Different reconnection regimes and geometries can be produced by adjusting plasma parameters and coil setups as well as coil current waveforms.The three-dimensional magnetic field configurations in the SPERF relevant to the dayside magnetopause reconnection are discussed in detail.展开更多
The high magnetic field helicon experiment system is a helicon wave plasma(HWP)source device in a high axial magnetic field(B0)developed for plasma–wall interactions studies for fusion reactors.This HWP was reali...The high magnetic field helicon experiment system is a helicon wave plasma(HWP)source device in a high axial magnetic field(B0)developed for plasma–wall interactions studies for fusion reactors.This HWP was realized at low pressure(5×10^-3-10 Pa)and a RF(radio frequency,13.56 MHz)power(maximum power of 2 k W)using an internal right helical antenna(5 cm in diameter by 18 cm long)with a maximum B0of 6300 G.Ar HWP with electron density~10^18–10^20m^-3 and electron temperature~4–7 e V was produced at high B0 of 5100 G,with an RF power of 1500 W.Maximum Ar^+ion flux of 7.8×10^23m^-2s^-1 with a bright blue core plasma was obtained at a high B0 of 2700 G and an RF power of 1500 W without bias.Plasma energy and mass spectrometer studies indicate that Ar^+ ion-beams of 40.1 eV are formed,which are supersonic(~3.1cs).The effect of Ar HWP discharge cleaning on the wall conditioning are investigated by using the mass spectrometry.And the consequent plasma parameters will result in favorable wall conditioning with a removal rate of 1.1×10^24N2/m^2 h.展开更多
Dipole Research EXperiment(DREX) is a new terrella device as part of the Space Plasma Environment Research Facility(SPERF) for laboratory studies of space physics relevant to the inner magnetospheric plasmas. Adeq...Dipole Research EXperiment(DREX) is a new terrella device as part of the Space Plasma Environment Research Facility(SPERF) for laboratory studies of space physics relevant to the inner magnetospheric plasmas. Adequate plasma sources are very important for DREX to achieve its scientific goals. According to different research requirements, there are two density regimes for DREX. The low density regime will be achieved by an electron cyclotron resonance(ECR) system for the ‘whistler/chorus' wave investigation, while the high density regime will be achieved by biased cold cathode discharge for the desired ‘Alfvén' wave study. The parameters of ‘whistler/chorus' waves and ‘Alfvén' waves are determined by the scaling law between space and laboratory plasmas in the current device. In this paper, the initial design of these two plasma sources for DREX is described. Focus is placed on the chosen frequency and operation mode of the ECR system which will produce relatively low density ‘artificial radiation belt' plasmas and the seed electrons, followed by the design of biased cold cathode discharge to generate plasma with high density.展开更多
基金supported by the NSFC under Grant Nos.11261140326,11275034,51577043,11505040, 61402138HIT.NSRIF under Grant No.2017009the Natural Science Foundation of Heilongjiang Province(No. E201452)
文摘A new ground-based expenmental device,the Space Plasma Environment Research Facility(SPERF),is being designed at Harbin Institute of Technology in China,with Asymmetric REconnection eXperiment-3 Dimensional(AREX-3D) as one of the experimental components to study the asymmetric reconnection dynamics relevant to the interaction between the interplanetary and magnetospheric plasmas.The asymmetry in the designed magnetic reconnection process not only refers to the distinct plasma parameters designed for the two upstream regions across the current sheet,but also refers to the inhomogeneity in the direction along the current sheet resulting from the designed 3D magnetic field geometry.These two asymmetries are fundamental features of the reconnection process at the Earth's magnetopause.In experiment,the reconnection process is driven by a set of flux cores through coil-currentramp-up from the 'magnetosheath-side' to interact with a dipole magnetic field generated by the Dipole Research Experiment(DREX) coil on the 'magnetosphere-side'.The AREX-3D will be able to investigate a range of important reconnection issues in 3D magnetic field geometry that is relevant to the Earth's magnetopause.A wide range of plasma parameters can be achieved through inductive plasma generation with flux cores on the 'magnetosheath-side' and electron cyclotron resonance(ECR) with microwave sources on the 'magnetosphere-side',e.g.high(low)plasma density at experimental magnetosheath(dipole) side.Different reconnection regimes and geometries can be produced by adjusting plasma parameters and coil setups as well as coil current waveforms.The three-dimensional magnetic field configurations in the SPERF relevant to the dayside magnetopause reconnection are discussed in detail.
基金supported by the National Magnetic Confinement Fusion Science Program of China(Grant Nos.2014GB106005 and 2010GB106000)National Natural Science Foundation of China(Nos.11505123 11435009 11375126)a Project funded by China Postdoctoral Science Foundation(No.156455)
文摘The high magnetic field helicon experiment system is a helicon wave plasma(HWP)source device in a high axial magnetic field(B0)developed for plasma–wall interactions studies for fusion reactors.This HWP was realized at low pressure(5×10^-3-10 Pa)and a RF(radio frequency,13.56 MHz)power(maximum power of 2 k W)using an internal right helical antenna(5 cm in diameter by 18 cm long)with a maximum B0of 6300 G.Ar HWP with electron density~10^18–10^20m^-3 and electron temperature~4–7 e V was produced at high B0 of 5100 G,with an RF power of 1500 W.Maximum Ar^+ion flux of 7.8×10^23m^-2s^-1 with a bright blue core plasma was obtained at a high B0 of 2700 G and an RF power of 1500 W without bias.Plasma energy and mass spectrometer studies indicate that Ar^+ ion-beams of 40.1 eV are formed,which are supersonic(~3.1cs).The effect of Ar HWP discharge cleaning on the wall conditioning are investigated by using the mass spectrometry.And the consequent plasma parameters will result in favorable wall conditioning with a removal rate of 1.1×10^24N2/m^2 h.
基金supported by National Natural Science Foundation of China(Nos.11505040,11261140326,11405038 and 51577043)China Postdoctoral Science Foundation(Nos.2016M591518,2015M570283)HIT.NSRIF under Grant No.2017008
文摘Dipole Research EXperiment(DREX) is a new terrella device as part of the Space Plasma Environment Research Facility(SPERF) for laboratory studies of space physics relevant to the inner magnetospheric plasmas. Adequate plasma sources are very important for DREX to achieve its scientific goals. According to different research requirements, there are two density regimes for DREX. The low density regime will be achieved by an electron cyclotron resonance(ECR) system for the ‘whistler/chorus' wave investigation, while the high density regime will be achieved by biased cold cathode discharge for the desired ‘Alfvén' wave study. The parameters of ‘whistler/chorus' waves and ‘Alfvén' waves are determined by the scaling law between space and laboratory plasmas in the current device. In this paper, the initial design of these two plasma sources for DREX is described. Focus is placed on the chosen frequency and operation mode of the ECR system which will produce relatively low density ‘artificial radiation belt' plasmas and the seed electrons, followed by the design of biased cold cathode discharge to generate plasma with high density.
