Abstrakt: |
A global enhanced vibrational kinetic model (GEVKM) is developed for multitemperature, chemically reacting hydrogen plasmas in inductively coupled cylindrical discharges for low- to high-pressure regimes. The species in a GEVKM are ground-state hydrogen atoms H and molecules H2, 14 vibrationally excited hydrogen molecules \textrm H2 (v) , v=1-14 , electronically excited hydrogen atoms H(2) and H(3), ground-state positive ions H+, H2+, and H3+, ground-state negative ions H− and electrons e. The GEVKM involves volume-averaged steady-state continuity equations for the plasma species, an electron energy equation, a total energy equation, a heat transfer equation to the chamber walls, and a comprehensive set of surface and volumetric chemical processes governing vibrational and ionization kinetics of hydrogen plasmas. The GEVKM is verified and validated by comparisons with previous numerical simulations and experimental measurements of a negative hydrogen ion source in the low-pressure (20–100 mtorr), low-absorbed-power-density (0.053–0.32 W/cm ^{3}) regime and of a microwave plasma reactor in the intermediate- to high-pressure (1–100 torr), high-absorbed-power-density (8.26–22 W/cm ^{3})$ regime. The GEVKM is applied to the simulation of a high-current negative hydrogen ion source (HCNHIS). The HCNHIS consists of a high-pressure (20–65 torr) radio-frequency discharge chamber in which the main production of high-lying vibrational states of the hydrogen molecules occurs, a bypass system, and a low-pressure (0.1–0.4 torr) negative hydrogen ion production region where negative ions are generated by the dissociative attachment of low-energy electrons to rovibrationally excited hydrogen molecules. The discharge pressure and negative hydrogen ion current predicted by the GEVKM compare well with the measurements in the HCNHIS. [ABSTRACT FROM PUBLISHER] |