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Roles of resonant muonic molecule in new kinetics model and muon catalyzed fusion in compressed gas

Takuma Yamashita, Yasushi Kino, Kenichi Okutsu, S. Okada, Motoyasu Sato

2022Scientific Reports11 citationsDOIOpen Access PDF

Abstract

Muon catalyzed fusion ([Formula: see text]CF) in which an elementary particle, muon, facilitates the nuclear fusion between the hydrogen isotopes has been investigated in a long history. In contrast to the rich theoretical and experimental information on the [Formula: see text]CF in cold targets, there is relatively scarce information on the high temperature gas targets of deuterium-tritium mixture with high-thermal efficiency. We demonstrate new kinetics model of [Formula: see text]CF including three roles of resonant muonic molecules, (i) changing isotopic population, (ii) producing epi-thermal muonic atoms, and (iii) inducing fusion in-flight. The new kinetics model reproduces experimental observations, showing higher cycle rate as the temperature increasing, over a wide range of target temperatures ([Formula: see text] K) and tritium concentrations. Moreover, it can be tested by measurements of radiative dissociation X-rays around 2 keV. High energy-resolution X-ray detectors and intense muon beam which are recently available are suitable to reveal these dynamical mechanism of [Formula: see text]CF cycles. Towards the future [Formula: see text]CF experiments in the high-temperature gas target we have clarified the relationship between the fusion yield and density-temperature curve of adiabatic/shock-wave compression.

Topics & Concepts

MuonPhysicsFusionDeuteriumDissociation (chemistry)Atomic physicsHydrogenNuclear physicsAdiabatic processKineticsNuclear fusionChemistryThermodynamicsPhysical chemistryPhilosophyQuantum mechanicsLinguisticsAtomic and Molecular PhysicsMuon and positron interactions and applicationsAdvanced Chemical Physics Studies