Lou,
I believe that the huge energy concentrations seen in Nanoplasmonic hot spots are "Dark mode" concentrations of LIGHT that can produce magnetic anapole EMF. A new post will be written on this subject shortly. Matter/light interactions can pack light into solitons in an open ended manor to account for various LENR experimental vortex observations. In a polariton laser turned in on itself, light can be stored coherently, propagated, converted, compressed, concentrated and controlled both in time and space by exploiting long-lived coherent memory for photon states and electromagnetically induced transparency (EIT) in an optically dense atomic medium (alkali metals/hydrogen) at high temperatures. https://www.physics.harvard.edu/uploads/files/thesesPDF/Eisaman.pdf Generation, Storage, and Retrieval of Nonclassical States of Light using Atomic Ensembles On Tue, Nov 12, 2013 at 3:30 PM, <[email protected]> wrote: > Axil, > > First, if you use paragraphs, your posts will be much more readable. > > Second, your URL link is broken. The new one is - > "Structure Enhancement Factor Relationships in Single Gold Nanoantennas.." > > http://sites.weinberg.northwestern.edu/vanduyne/files/2013/01/2012_Kleinman_2.pdf > > A good, even if difficult to read, paper. > > The momentum "superkick" example I cited already includes the momentum > a charged particle acquires at an optical vortex. > > As you note, the high local E-field can be enormous when amplified. > It would be good to know how much momentum a charged particle can > acquire in such a field. This is the calculation, I am interested in: > > Assume a static electrical field = E[V/m] lasting a duration time = T > > Then if two oppositely charged particles, with charges -e and +e > (e = electron charge) and masses m and M, collide head-on both > acquire equal, opposite impulses, or momentum kicks = TE/e > > The kinetic energy TE/e represents depends on m and M. > (It can be waveform squeezing, as well as linear displacement speed. > The transient colliding composite particle can have zero velocity.) > > So what amplitudes and durations must an e-m wave crest have to give > charged particles kinetic energies sufficient to reach LENR levels? > - e.g., for electron capture, pair-creation, etc. > > - And, perhaps it's worth noting that electron, protons, some nuclei are > spin-1/2 fermions, so the Dirac equation, instead of the Schrodinger > equation sometimes applies. This could involve the 'Klein paradox'. > (http://en.wikipedia.org/wiki/Klein_paradox) > > -- Lou Pagnucco > > Axil wrote: > > *Experimentally measuring hot spot energy concentration.* In a seminal > > Nanoplasmonics paper, the ability of hot spots to concentrate power is > > experimentally determined for the first time. > > http://www.google.com/url? > > [...] > >
