Neutrons in a commercial reactor or a big problem given the activation and the radioactive waste resulting. LENR is a more practical option IMHO. This impractically does not hold a candle to the security issues associated with the generation of fissile materials by such reactors. For example , Th- 232 to U-233. well established by light water breeder reactors.
Bob Cook ________________________________ From: Jones Beene <[email protected]> Sent: Thursday, February 7, 2019 3:12:25 PM To: [email protected] Subject: Re: [Vo]:Stand by for a big breakthrough in LENR Speaking of Holmlid, muons and/or muon substitute here is a new article from Fusion, Rather prestigious venue, one would think... This is not all that far from commercial realization Existing Source for Muon-Catalyzed Nuclear Fusion Can Give Megawatt Thermal Fusion Generator Article in Fusion Science and Technology<https://www.researchgate.net/journal/1536-1055_Fusion_Science_and_Technology> · January 2019 * <https://www.researchgate.net/profile/Leif_Holmlid> Leif Holmlid<https://www.researchgate.net/profile/Leif_Holmlid> * University of Gothenburg<https://www.researchgate.net/institution/University_of_Gothenburg> Abstract Fusion power generators employing muon-catalyzed nuclear fusion can be developed using a new type of laser-driven muon generator. Results using this generator have been published, and those data are now used to derive the possible fusion power using this generator. Muon-catalyzed fusion has been studied for 60 years, and the results found in such studies are used here to determine the possible power output. Since the muon source gives complex mixtures of mesons and leptons, which have very different interactions with the measuring equipment, the number of negative muons formed is not easily found exactly, but reasonable values based on numerous published experiments with different methods are used to predict the energy output. With deuterium-tritium as fuel, a fusion power generator employing the novel muon generator could give more than 1 MW thermal power. The thermal power using pure deuterium as fuel may be up to 220 kW initially: It will increase with time up to over 1 MW due to the production of tritium in one reaction branch. The power required for running a modern laser and the muon generator is estimated to be of the order of 100 W, thus giving a total energy gain of more than 10 000. The harmful radiation from such fusion power generators is mainly in the form of neutrons from the fusion reactions. Thus, thick radiation shields are necessary as for almost all other fusion concepts. This means that medium-scale thermal fusion power generators of the muon-catalyzed fusion type may become available within a relatively short time.
