Density Functional Study on Compounds to Accelerate the Electron Capture Decay of ⁷Be

In radionuclide compounds undergoing electron capture (EC) decay, the electron density at the nucleus (rho(0)) and half-life of the nucleus are inversely proportional. Thus, the decay can be accelerated by changing the chemical or physical conditions. A previous study reported a 1.1-1.5% reduction in the half-life of Be-7 encapsulated in C-60 compared with Be-7 metal. However, Be-7 was inserted into the fullerene using the rebound energy of the nuclear reaction, which may not be a practical method. This paper elucidates the mechanism of rho(0) change in various Be compounds from density functional calculations and attempts to propose better systems that show faster EC decay (larger rho(0)) and/or that are easier to generate than Be in C-60. In typical Be compounds, rho(0) decreases because Be donates electrons to other atoms through chemical bonds and, thus, is not effective. Among the various Be-encapsulated fullerenes (C (20)-C-180), the largest increase in rho(0) was obtained for C-50 fullerene, but the magnitude was almost similar to that of C-60. As new systems, we propose Be-encapsulated rare gas solids, which would be generated only by applying high pressure. An increase in rho(0) from Be metal in the range 2-10%, which depends on the lattice constant, is obtained.