This very new paper is a great find for LENR. It is another piece in the very complicated LENR puzzle.
Super-absorption in a LENR system is what a chain reaction is in a nuclear system. As infrared light (photons) aka heat is absorbed by a system of dipoles, the energy is increased and the electron tunneling that moves electrons away from their associated holes (ions) becomes increasingly more powerful. In Nanoplasmonics, this “dark mode” near field EMF absorption process is called Fano resonance. EMF power increases in a positive feedback mode within a small volume until the concentrated EMF begins to produce nuclear heat. The Superabsorbent ring in figure one of the reference is just a two dimensional projection of a three dimensional nano-particle. Nano-particles act as a super EMF absorbing structure which concentrates heat photons into a small volume between the nanoparticles. If there is little energy loss in this dipole system, and the limit of EMF increase is very large, the concentrated EMF becomes so great that the nuclear forces inside the nucleus become unbalanced and the nucleus disintegrates. . When all the various small volumes of EMF concentration form a Bose Ernestine condensate, the pumping of concentrated EMF is shared between each small volume in superposition and nuclear disintegration happens as a probabilistic phenomenon triggered by virtual particle creation out of the vacuum. On Thu, Jun 6, 2013 at 10:01 PM, <[email protected]> wrote: > A new arxiv paper, possibly related to missing LENR em-emissions - > > "Superabsorption of light via quantum engineering" > > ABSTRACT: Almost 60 years ago Dicke introduced the term superradiance to > describe a signature quantum effect: N atoms can collectively emit light > at a rate proportional to N^2. Even for moderate N this represents a > significant increase over the prediction of classical physics, and the > effect has found applications ranging from probing exciton delocalisation > in biological systems, to developing a new class of laser, and even in > astrophysics. Structures that super-radiate must also have enhanced > absorption, but the former always dominates in natural systems. Here we > show that modern quantum control techniques can overcome this restriction. > Our theory establishes that superabsorption can be achieved and sustained > in certain simple nanostructures, by trapping the system in a highly > excited state while extracting energy into a non-radiative channel. The > effect offers the prospect of a new class of quantum nanotechnology, > capable of absorbing light many times faster than is currently possible; > potential applications of this effect include light harvesting and photon > detection. An array of quantum dots or a porphyrin ring could provide an > implementation to demonstrate this effect. > > http://arxiv.org/abs/1306.1483 > > Perhaps also of interest - > > "SUPER-ABSORPTION" > > ABSTRACT: The concept of Super-Absorption has been proposed based on the > correlation between deuterium flux and excess heat, and based on the > selective resonant tunneling model. The experimental evidence for this > correlation is shown in the D/Pd system with a Calvet high precision > calorimeter. A theoretical model is set-up to show how the resonant > tunneling effect will correlate the deuterium flux to the generation of > excess heat. > > http://www.lenr-canr.org/acrobat/LiXZsuperabsor.pdf > > http://www.lenr-canr.org/acrobat/LiXZsuperabsor.pdf > > >
