Naoji Yamamoto scite author profile

Laboratory generation of strong magnetic fields opens new frontiers in plasma and beam physics, astro- and solar-physics, materials science, and atomic and molecular physics. Although kilotesla magnetic fields have already been produced by magnetic flux compression using an imploding metal tube or plasma shell, accessibility at multiple points and better controlled shapes of the field are desirable. Here we have generated kilotesla magnetic fields using a capacitor-coil target, in which two nickel disks are connected by a U-turn coil. A magnetic flux density of 1.5 kT was measured using the Faraday effect 650 μm away from the coil, when the capacitor was driven by two beams from the GEKKO-XII laser (at 1 kJ (total), 1.3 ns, 0.53 or 1 μm, and 5 × 1016 W/cm2).

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Discharge Current Oscillation in Hall Thrusters

Yamamoto

Komurasaki

Arakawa

2005

Journal of Propulsion and Power

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Antenna Configuration Effects on Thrust Performance of Miniature Microwave Discharge Ion Engine

Yamamoto

Masui

Kataharada

et al. 2006

Journal of Propulsion and Power

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Effects of magnetic field configuration on thrust performance in a miniature microwave discharge ion thruster

Yamamoto

Kondo

Chikaoka

et al. 2007

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Articles you may be interested inIon ejection from a permanent-magnet mini-helicon thruster Phys. Plasmas 21, 093511 (2014); 10.1063/1.4896238 Measurement of axial neutral density profiles in a microwave discharge ion thruster by laser absorption spectroscopy with optical fiber probes Rev. Sci. Instrum. 82, 123103 (2011); 10.1063/1.3665954 Effect of applied magnetic field on a microwave plasma thruster Phys. Plasmas 15, 023503 (2008); 10.1063/1.2841026 Effect of magnetic field profile on the anode fall in a Hall-effect thruster dischargea) Phys. Plasmas 13, 057104 (2006); 10.1063/1.2174825The ultimate performance of gridded ion thrusters for interstellar missions AIP Conf.The effects of magnetic field configuration on thrust performance in a miniature microwave discharge ion thruster were investigated in order to improve thrust performance. First, the extracted ion beam current was measured for various levels of strength of the magnetic field. It was found that there is an optimum magnitude of the magnetic field. That this is due to the tradeoff between magnetic mirror confinement and microwave-plasma coupling was confirmed by measurement of the ion saturation current into the antenna of the ion thruster. The ion saturation current was found to decrease with an increase in magnetic field strength, due to the improvement in magnetic mirror confinement. The estimated electron temperature also decreases with an increase in magnetic field strength. This result shows that the increase in magnetic field strength leads to a decrease in microwave-plasma coupling. Next, the ion beam current for three magnetic field shapes was measured by changing the length of the central yoke. The results show that the optimum magnetic field shape depends on the mass flow rate because of the tradeoff between magnetic confinement and ionization probability. For the configurations tested, the 3 mm length central yoke is optimal for low mass flow, whereas 7 mm is the best for high mass flow. Overall, the extracted ion beam current is 21.4 mA, at a xenon mass flow rate of 0.036 mg/s, beam voltage of 1500 V, and incident microwave power of 16 W.

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Development of a miniature microwave electron cyclotron resonance plasma ion thruster for exospheric micro-propulsion

Dey

Toyoda

Yamamoto

et al. 2015

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A miniature microwave electron cyclotron resonance plasma source [(discharge diameter)/(microwave cutoff diameter) < 0.3] has been developed at Kyushu University to be used as an ion thruster in micro-propulsion applications in the exosphere. The discharge source uses both radial and axial magnetostatic field confinement to facilitate electron cyclotron resonance and increase the electron dwell time in the volume, thereby enhancing plasma production efficiency. Performance of the ion thruster is studied at 3 microwave frequencies (1.2 GHz, 1.6 GHz, and 2.45 GHz), for low input powers (<15 W) and small xenon mass flow rates (<40 μg/s), by experimentally measuring the extracted ion beam current through a potential difference of ≅1200 V. The discharge geometry is found to operate most efficiently at an input microwave frequency of 1.6 GHz. At this frequency, for an input power of 8 W, and propellant (xenon) mass flow rate of 21 μg/s, 13.7 mA of ion beam current is obtained, equivalent to an calculated thrust of 0.74 mN.

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Naoji Yamamoto

Kilotesla Magnetic Field due to a Capacitor-Coil Target Driven by High Power Laser

Discharge Current Oscillation in Hall Thrusters

Antenna Configuration Effects on Thrust Performance of Miniature Microwave Discharge Ion Engine

Effects of magnetic field configuration on thrust performance in a miniature microwave discharge ion thruster

Development of a miniature microwave electron cyclotron resonance plasma ion thruster for exospheric micro-propulsion

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