RF Positive Ion Source with Solenoidal Magnetic Field

TL;DR

This paper presents a novel RF positive ion source with a saddle antenna and solenoidal magnetic field that significantly improves ion production efficiency by generating plasma near the emission aperture, suitable for continuous operation.

Contribution

Introduction of a saddle antenna design with magnetic field to enhance plasma density localization and ion production efficiency in RF ion sources.

Findings

Efficiency increased to ~100 mA/cm² per kW of RF power.

Plasma generation near the axis improves ion extraction.

CW operation demonstrated on ORNL SNS test stand.

Abstract

A positive ion source with RF discharge in solenoidal magnetic field is described. In this paper we present an overview of positive ion production in saddle antenna (helicon discharge) radio frequency (SA RF) ion sources. The efficiency of H+ ion production in recently developed RF sources with solenoidal antennas was improved to 2.9 mA/kW. About 24 kW of RF power is typically needed for 70 mA beam current production from a 7 mm emission aperture. This efficiency is relatively low because in the RF discharge with a solenoidal antenna, the plasma is generated near the coil and diffuses to the axis creating a nearly uniform plasma density distribution in all cross sections of the discharge chamber, when the plasma flow is necessary only near an emission aperture. The efficiency of the extracted ion generation was improved significantly by using a saddle antenna with solenoidal magnetic field. In the RF discharge with the saddle antenna the plasma is generated near the axis and the magnetic field suppress the plasma diffusion from the axis, creating a peaked plasma density distribution on the emission aperture. With the SA the efficiency of positive ion generation in the plasma has been improved up to ~100 mA/cm2 per kW of RF power at 13.56 MHz. Continuous wave (CW) operation of the RF source has been tested on the small ORNL SNS test stand. The general design of the CW RF source is based on the pulsed version. A compact design of ion source is presented. Some modifications were made to improve the cooling and to simplify the design. Features of SA RF discharges and ion generation are discussed.