Reduction of Charge Transfer Loss in Atomic Laser Isotope Separation by Production of Excited Ions through Autoionization Levels

Abstract

A new technique to reduce charge transfer loss when extracting ions from photoionized plasma has been developed, thereby increasing the efficiency of atomic vapor laser isotope separation (AVLIS). By selecting autoionization levels, specific isotopes are ionized to the excitation levels of the ions. Cross sections for charge transfer between specific excited ions and ground state atoms are smaller than those between ground state ions and ground state atoms. The effectiveness of this technique was confirmed by measuring the difference in charge transfer cross sections between Gd⁺+Gd and Gd^+*+Gd. When the gadolinium atoms were ionized at the 53, 616cm^-1 autoionization level, the kinetic energy of the released electrons was measured with a time of flight electron spectrometer (energy resolution>30meV) and the produced ions were determined to be at levels of 4f⁷5d6s¹⁰i>D_13/2 and ⁸D_7/2. The charge transfer cross section for Gd^+* (¹⁰D_13/2 1, 935cm^-1, ⁸D_7/23, 427 cm^-1)+Gd(⁹D_J) was 1.5×10^-18m² at an impact energy of 250eV, which was a smaller value than that for Gd⁺ (¹⁰D_5/2 0cm^-1)+Gd(⁹D_J)(2.5×10^-18m²). When specific isotopes of gadolinium were ionized by autoionization, the charge transfer loss could be reduced from 14% to 9% at an atomic density of 1×1019m^-3 in the typical isotope separation region. Because this effect is also expected in charge transfer between other heavy metallic ions, it should be possible to improve the ion collection efficiency for isotopes like uranium by selecting autoionization levels to produce specific excited ions.