Worcester Polytechnic Institute Electronic Theses and Dissertations Collection

Title page for ETD etd-111005-142414


Document Typethesis
Author NamePartridge, James M
URNetd-111005-142414
TitleDevelopment of a Micro-Retarding Potential Analyzer for High-Density Flowing Plasmas
DegreeMS
DepartmentMechanical Engineering
Advisors
  • Dr. Nikolaos A Gatsonis, Advisor
  • Dr. John J. Blandino, Committee Member
  • Dr. Mark W. Richman, Committee Member
  • Dr. Michael A. Demetriou, Graduate Committee Rep
  • Keywords
  • Ion Energy Distribution
  • Current Collection Theory
  • Energy Diagnostic
  • Retarding Potential Analyzer
  • Electric Propulsion
  • Date of Presentation/Defense2005-10-05
    Availability unrestricted

    Abstract

    The development of Retarding Potential Analyzers (RPAs) capable of measuring high-density stationary and flowing plasmas is presented. These new plasma diagnostics address the limitations of existing RPAs and can operate in plasmas with electron densities in excess of 1x1018 m-3. Such plasmas can be produced by high-powered Hall Thrusters, Pulsed Plasma Thrusters (PPTs), and other plasma sources.

    The Single-Channel micro-Retarding Potential Analyzer (SC-microRPA) developed has a minimum channel diameter of 200 microns, electrode spacing on the sub-millimeter scale and can operate in plasmas with densities of up to 1x1017 m-3. The electrode series consists of 100 micron thick molybdenum electrodes and Teflon insulating spacers. The alignment process of the channel, as well as the design and fabrication of the stainless steel outer housing, the Delrin insulating tube, and all other microRPA components are detailed. To expand the applicability of the SC-microRPA to densities above 1x1018 m-3 a low transparency Microchannel Plate (MCP) has been incorporated in the design of a Multi-Channel micro-Retarding Potential Analyzer (MC-microRPA).

    The current collection theory for the SC-microRPA and the MC-microRPA is also derived. The theory is applicable to microRPAs with arbitrary channel length to diameter ratios and accounts for the reduction of ion flux due to the microchannel plate in the case of the MC-microRPA, due to absorption of ions by channel walls, and due to the applied potential. Current-voltage curves are obtained for incoming plasma flows that range from near-stationary to hypersonic, with temperatures in the range of 0.1 to 10 eV, and densities in the range of 1x1015 m-3 to 1x1021 m-3. The SC-microRPA current collection theory is validated by comparisons with the classical RPA theory and particle-in-cell simulations. Determination of unknown plasma properties is based on a fuzzy-logic approach that uses the generated current-voltage curves as lookup tables.

    Files
  • jpartridge.pdf

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