부산대학교 도서관

High-power PW laser systems (HPLS) provide intense beams of accelerated reaction-driving protons simultaneously with spatially localized keV-plasmas. We herein depict our groundwork and strategy to use these unique features of the HPLS at the Extreme Light Infrastructure (ELI-NP) by exposing the long-lived nuclear isomer 93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo at 2.425 MeV (93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo = 6.85 h) to plasma facilitating the local petawatt beamlines. An intermediate short-lived (93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo = 3.52 ns) state situated only 4.85 keV above 93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo constitutes a gateway to allow for its prompt release. The controllable release of the nuclear isomer energy will henceforth enable harvesting energy densities in the nuclear regime of GJkg93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo (‘Nuclear Battery’). The campaign was inspired by the observation of the triggered release of 93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMovia the intermediate state by Chiara et al. [1] published in Nature. They assigned the hitherto elusive Nuclear Excitation by Electron Capture (NEEC) as the driving process and claimed a very high probability of 93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo. However, these claims are challenged by experimentalists [2, 3] and theory [4]. We herein outline our strategy following bespoke theoretical guidance in the quest to unambiguously and independently demonstrate the onset of NEEC in 93mMot1/2t1/293mMo-193mMoPNEECexp=0.010(3)93mMo. With the yield estimations derived for our forthcoming HPLS experiment at ELI-NP, we draw optimism to resolve the current conundrum between the conflicting experimental observations and theoretical interpretations as discussed in world-leading journals and to pave the way for the future utilization of isomer depopulation in applied physics.