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http://dx.doi.org/10.5516/NET.2009.41.5.709

CU+ ION EXTRACTION FROM A MODIFIED BERNAS ION SOURCE IN A METAL-ION IMPLANTER  

Hong, In-Seok (Proton Engineering Frontier Project, Korea Atomic Energy Research Institute Nuclear physics, Fusion, and Laser technology)
Lee, Hwa-Ryun (Proton Engineering Frontier Project, Korea Atomic Energy Research Institute Nuclear physics, Fusion, and Laser technology)
Trinh, Tu Anh (Proton Engineering Frontier Project, Korea Atomic Energy Research Institute Nuclear physics, Fusion, and Laser technology)
Cho, Yong-Sub (Proton Engineering Frontier Project, Korea Atomic Energy Research Institute Nuclear physics, Fusion, and Laser technology)
Publication Information
Nuclear Engineering and Technology / v.41, no.5, 2009 , pp. 709-714 More about this Journal
Abstract
An ion implanter, which can serve as a metal-ion supply, has been constructed and performance tested. Copper ions are generated and extracted from a Bernas ion source with a heating crucible that provides feed gases to sustain the plasma. Sable arc plasmas can be sustained in the ion source for a crucible temperature in excess of $350^{\circ}C$. Stable extraction of the ions is possible for arc Currents less than 0.3 A. Arc currents increase with the induced power of a block cathode and the transverse field in the ion source. $Cu^+$ ions in the extracted beam are separated using a dipole magnet. A $20{\mu}A$ $Cu^+$ ion current can be extracted with a 0.2 A arc current. The ion current can support a dose of $10^{16}ions/cm^2$ over an area of $15\;cm^2$ within a few hours.
Keywords
Ion Source; Copper; Metal Chloride; Ion Implanter;
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