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Dry, Preloaded NANOR®-Type CF/LANR Components


Affiliations
1 JET Energy, Inc., Wellesley, MA 02481, United States
2 Massachusetts Institute of Technology, Cambridge, MA02139, United States
 

Dry, preloaded NANOR®-type technology makes LANR reactions more accessible. These self-contained, twoterminal nanocomposite ZrO2-PdNiD CF/LANR components have at their core ZrO2-PdD nanostructured material. The excess energy gain compared to driving input energy is up to 20 times the input; characterized by reasonable reproducibility and controllability. The CF/LANR/CF activation is separated from its loading. Although small in size, the LANR excess power density is more than 19,500 W/kg of nanostructured material, with zero carbon footprint.

Keywords

Cold Fusion, Excess Energy, Nanomaterial, Preloading.
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  • Dry, Preloaded NANOR®-Type CF/LANR Components

Abstract Views: 385  |  PDF Views: 144

Authors

Mitchell R. Swartz
JET Energy, Inc., Wellesley, MA 02481, United States
Gayle M. Verner
JET Energy, Inc., Wellesley, MA 02481, United States
Jeffrey W. Tolleson
JET Energy, Inc., Wellesley, MA 02481, United States
Peter L. Hagelstein
Massachusetts Institute of Technology, Cambridge, MA02139, United States

Abstract


Dry, preloaded NANOR®-type technology makes LANR reactions more accessible. These self-contained, twoterminal nanocomposite ZrO2-PdNiD CF/LANR components have at their core ZrO2-PdD nanostructured material. The excess energy gain compared to driving input energy is up to 20 times the input; characterized by reasonable reproducibility and controllability. The CF/LANR/CF activation is separated from its loading. Although small in size, the LANR excess power density is more than 19,500 W/kg of nanostructured material, with zero carbon footprint.

Keywords


Cold Fusion, Excess Energy, Nanomaterial, Preloading.



DOI: https://doi.org/10.18520/cs%2Fv108%2Fi4%2F595-600