Near-Surface Plasma Characterization of the 12.5-kW NASA TDU1 Hall Thruster

To advance the state-of-the-art in Hall thruster technology, NASA is developing a 12.5-kW, high-specific-impulse, high-throughput thruster for the Solar Electric Propulsion Technology Demonstration Mission. In order to meet the demanding lifetime requirements of potential missions such as the Asteroid Redirect Robotic Mission, magnetic shielding was incorporated into the thruster design. Two units of the resulting thruster, called the Hall Effect Rocket with Magnetic Shielding (HERMeS), were fabricated and are presently being characterized. The first of these units, designated the Technology Development Unit 1 (TDU1), has undergone extensive performance and thermal characterization at NASA Glenn Research Center. A preliminary lifetime assessment was conducted by characterizing the degree of magnetic shielding within the thruster. This characterization was accomplished by placing eight flush-mounted Langmuir probes within each discharge channel wall and measuring the local plasma potential and electron temperature at various axial locations. Measured properties indicate a high degree of magnetic shielding across the throttle table, with plasma potential variations along each channel wall being less than or equal to 5 eV and electron temperatures being maintained at less than or equal to 5 eV, even at 800 V discharge voltage near the thruster exit plane. These properties indicate that ion impact energies within the HERMeS will not exceed 26 eV, which is below the expected sputtering threshold energy for boron nitride. Parametric studies that varied the facility backpressure and magnetic field strength at 300 V, 9.4 kW, illustrate that the plasma potential and electron temperature are insensitive to these parameters, with shielding being maintained at facility pressures 3X higher and magnetic field strengths 2.5X higher than nominal conditions. Overall, the preliminary lifetime assessment indicates a high degree of shielding within the HERMeS TDU1, effectively mitigating discharge channel erosion as a life-limiting mechanism.

[1]  A. Gallimore,et al.  Experimental Characterization of the Near-Wall Plasma in a 6-kW Hall Thruster and Comparison to Simulation , 2011 .

[2]  Hani Kamhawi,et al.  Effect of Background Pressure on the Performance and Plume of the HiVHAc Hall Thruster , 2013 .

[3]  A. Lichtenberg,et al.  Principles of Plasma Discharges and Materials Processing , 1994 .

[4]  Hani Kamhawi,et al.  Experimental Investigation of the Near-Wall Region in the NASA HiVHAc EDU2 Hall Thruster , 2015 .

[5]  I. Mikellides,et al.  Design of a Laboratory Hall Thruster with Magnetically Shielded Channel Walls, Phase III: Comparison of Theory with Experiment , 2012 .

[6]  Dan M. Goebel,et al.  Pole-piece interactions with the plasma in a magnetically shielded hall thruster , 2014 .

[7]  A. Mathers,et al.  Demonstration of 10,400 Hours of Operation on a 4.5 kW Qualification Model Hall Thruster , 2010 .

[8]  Binhao Jiang Experimental Investigation of Backpressure Effects on the Ionization and Acceleration Processes in a Hall Thruster , 2009 .

[9]  I. Mikellides,et al.  Design of a Laboratory Hall Thruster with Magnetically Shielded Channel Walls, Phase II: Experiments , 2012 .

[10]  I. Mikellides,et al.  Magnetic Shielding of the Acceleration Channel Walls in a Long-Life Hall Thruster , 2010 .

[11]  Rohit Shastry,et al.  Experimental Characterization of the Near-Wall Region in Hall Thrusters and its Implications on Performance and Lifetime. , 2011 .

[12]  I. Mikellides,et al.  Assessment of Pole Erosion in a Magnetically Shielded Hall Thruster , 2014 .

[13]  A. Lichtenberg,et al.  Principles of Plasma Discharges and Materials Processing: Lieberman/Plasma 2e , 2005 .

[14]  Hani Kamhawi,et al.  Langmuir Probe Measurements Within the Discharge Channel of the 20-kW NASA-300M and NASA-300MS Hall Thrusters , 2013 .

[15]  I. Mikellides,et al.  Design of a Laboratory Hall Thruster with Magnetically Shielded Channel Walls, Phase I: Numerical Simulations , 2011 .

[16]  Noah Hershkowitz,et al.  3 – How Langmuir Probes Work , 1989 .

[17]  S. Mazouffre,et al.  Two Ways to Evaluate the Xe+ Ion Flow Velocity in a Hall Effect Thruster , 2004 .

[18]  Vladimir Kim,et al.  Analysis of Energy Balance in the Discharge of SPT Using Results of Its Integral Parameters and Plume Characteristics Measurements , 2009 .

[19]  William A. Hargus,et al.  Background Pressure Effects on Ion Velocity Distribution Within a Medium-Power Hall Thruster , 2011 .

[20]  V. Kim,et al.  Local Plasma Parameter Measurements by Nearwall Probes Inside the SPT Accelerating Channel Under Thruster Operation with Kr , 2002 .

[21]  J. Wesson,et al.  RESEARCH NOTES: Heat flow through a Langmuir sheath in the presence of electron emission , 1967 .

[22]  James L. Myers,et al.  Non-Contact Thermal Characterization of NASA’s 12.5-kW Hall Thruster , 2015 .

[23]  Rostislav Spektor,et al.  Investigation of the Effects of Facility Background Pressure on the Performance and Voltage-Current Characteristics of the High Voltage Hall Accelerator , 2014 .

[24]  Noah Zachary Warner Performance testing and internal probe measurements of a high specific impulse Hall thruster , 2003 .

[25]  James Szabo,et al.  High Voltage Plume Measurements and Internal Probing of the BHT-1000 Hall Thruster , 2004 .