Low-energy nuclear reactions (LENR), often referred to as cold fusion, representa long-standing controversial field at the boundary of experimental physics,electrochemistry, and materials research. A characteristic feature of this field isthe tension between repeatedly reported anomalies - especially excess heat,changes in isotopic composition, and occasional particle emissions - and thecurrent absence of robust, standardized reproducibility.This article proposes a hypothetical interpretive framework based on theDynamic Cosmic Medium Model (DKMM). Its starting point is the possibility thatthe non-reproducibility of observed phenomena does not necessarily imply thenon-existence of the effect, but may reflect the presence of a previouslyunmonitored environmental variable. Within this framework, the probability of ananomalous event is treated as a function not only of local laboratory parameters,but also of the state of a broader dynamic environment, represented by theschematic variable M(t,x).The article treats this approach as phenomenological and programmatic. Its aimis not to claim that LENR is already explained or technologically mastered, but toshow that DKMM offers a possible framework for interpreting the pulsed andvariable nature of reported results. On this basis, testable implications areformulated for experimental methodology, statistical evaluation, and possiblefuture adaptive regulation of systems, should the existence of such an effect beconfirmed.
Aleš Hrůza (Tue,) studied this question.