*http://scitation.aip.org/content/aip/journal/jcp/136/3/10.1063/1.3678015 <http://scitation.aip.org/content/aip/journal/jcp/136/3/10.1063/1.3678015>*
*Quote:* Within the optical cavity, the photons acquire an effective mass as determined by the cut-off frequency of the cavity that can be 6–7 orders of magnitude less than mass of an electron. *Depending upon the density, this allows for a BEC transition temperature that can approach room temperature. *Polaritons are also ultra-light quasiparticles that are known to condense in systems composed of a semiconducting quantum well sandwiched between two reflective mirrors. 2–6 In this case, however, the polaritons act as hard-core Bosons and scattering at high density allows for a rapid thermalization of the gas. Note: the temperature of condensation of polaritons is proportional to the density of the polaritons and so is their effective mass. The Ni/H reactor produces a huge density of coherent polaritons far greater than what a single Nano-cavity can produce. The effective mass of the polariton can drop into the millivolts. Within the Ni/H reactor's reaction, there is a positive feedback mechanism in place that converts nuclear energy into infrared photons and electrons from more vigorous dipole motion. This energy infusion pushes the density of the polaritons to extreme levels causing the condensate to establish at ever higher temperatures. <http://www.talk-polywell.org/bb/report.php?f=10&p=116454>