Electron-hole pair creation and conversion efficiency in radioisotope microbatteries

The ultimate conversion efficiency of semiconductor radioisotope microbatteries is set by the average energy consumed in the creation of an electron-hole pair, w. Although the Klein relationship between w and semiconductor bandgap, Eg, is widely cited, not only for radioisotope microbatteries, but indeed for a multitude of fields requiring accurate values of w, its validity has been recently questioned; new experimental measurements have resulted in the refined Bertuccio-Maiocchi-Barnett (BMB) relationship. Here, it is shown that the new relationship indicates the ultimately achievable conversion efficiencies of radioisotope microbatteries are much greater than had ever been expected. For example, it appears possible to produce planar 63Ni-Diamond radioisotope microbatteries with output powers 130x greater than has currently been achieved. The ultimate limit for batteries employing pore channels rather than planar designs is likely to be even greater still. These new findings open the possibility of using radioisotope microbatteries in a far greater variety of applications than has been traditionally assumed. As well as being of direct applicability to radioisotope microbatteries, the results highlight the need to reconsider the use of the Klein relationship in all fields that currently employ it.

Automated summary

The ultimate conversion efficiency of semiconductor radioisotope microbatteries is determined by the average energy consumed in creating an electron-hole pair. Recent experimental measurements have led to a refined relationship that suggests higher achievable efficiencies than previously expected, opening up new possibilities for applications in various fields. This challenges the traditional assumptions and highlights the need to reconsider the use of the Klein relationship in all related fields.