Joseph wrote: "Based on context, I'm going to assume that what you mean by "screening" is really "blasting nuclei with massively powered lasers". If that's not what you mean, then you still need to explain to me what you mean by screening."
In the referenced I sited for you, the dissertation by Cort´es states: “Lifetimes and α-particle emission spectra are investigated for a number of α-emitting nuclei. We find that even at strong intensities, the laser-induced acceleration of the α decay is negligible, ranging from a relative modification in the decay rate of 10−3 for static fields of electric field strengths of 10^^15 V/m, to 10−8 for strong optical fields with intensities of 1022 W/cm2, and to 10−6 for strong x-ray fields with laser intensities around 10^^24 W/cm2.” So it is not laser light alone. When laser light is amplified, compressed and concentrated by nanoantennas by a factor of 10 to the 9 power for gold (reference has been provided) that is when the EMF is strong enough to be reactive. It is not just the EMF, but the sub-atomic quasiparticle formed from the combination of light and electrons called a* poloriton *that carries the electric negative charge that is concentrated is a sub-nanometer volume called a NAE. See http://en.wikipedia.org/wiki/Electric-field_screening for a description of *coulomb barrier screening*. On Fri, May 3, 2013 at 10:39 AM, Joseph S. Barrera III <j...@barrera.org>wrote: > On 5/3/2013 12:00 AM, Axil Axil wrote: > > > So sorry, please excuse me, the answer I requested is still pending. > > You mean this question? > > > "Science recognizes that screening can accelerated alpha decay. How does > such screening affect the pions in their ability to keep these nucleons > inside the atom? In detail, what does screening do to the pions? What > changes?" > > Based on context, I'm going to assume that what you mean by "screening" is > really "blasting nuclei with massively powered lasers". If that's not what > you mean, then you still need to explain to me what you mean by screening. > > So: the answer to your question is: it doesn't do anything to the pions. > It doesn't reduce the attractive forces. What it does is supply enough > additional energy to the nuclei that the energy hill it has to tunnel > through is shorter, increasing the probability of alpha decay. > > Here's a picture. > > http://hyperphysics.phy-astr.**gsu.edu/hbase/nuclear/alptun.**html<http://hyperphysics.phy-astr.gsu.edu/hbase/nuclear/alptun.html> > > Look at the graph for "Alpha Tunneling Model". If you raise the black > horizontal line, you'll get more red squiggles on the right hand side > (decay). > > - Joe > >
