Abstract
Abstract
We demonstrate how a high surface-to-volume ratio porous electrode structure within an ionizing radiation field generates a nuclear-excited low-temperature plasma source. In a foundational experiment, we compared the I–V characteristics of two electrode systems comprised of: (1) open-cell reticulated copper foam discs (pore radius ∼500 µm) and (2) solid copper discs. Both systems were held at 2 atm neon and irradiated in a nuclear reactor under steady-state operation. The primary source of plasma ionization was electrons derived from reactor γ-rays; the secondary source was electrons from the β
− decay of 64Cu and 66Cu formed by the capture of thermal neutrons. The two electrode systems exhibited identical I–V proportionality for applied voltages between 2 V and 5 V, evidencing a sheath structure evolving within the copper foam discs. The energy fraction absorbed in the gas per unit electrode mass was 20%–70% greater for the porous electrode than for the solid electrode, corresponding to a factor of 3.5 increase in the specific ion output current [A g−1]. The plasma densities achieved in the porous and solid electrode systems were estimated to be
(
3.2
−
3.9
)
×
10
9
cm−3 and
7.1
×
10
9
cm−3 respectively, assuming a spatially independent density profile and approximately ambient electron temperature.