"Why do entangled proton pairs pass through the coulomb barrier of a heavy element nucleus with high probability in collisions with energies well below those required to breach this barrier?"
Those who have been hangin' out in the Dime Box Saloon for a few years know of my descriptions of subatomic particles as some form of localized (dimensionally constrained) oscillations of some mediu, (the vacuum). This physical model would predict the empirical observation of how two coupled (entangled) protons do this... -Mark Iverson From: Axil Axil [mailto:janap...@gmail.com] Sent: Saturday, June 01, 2013 11:29 AM To: vortex-l Subject: Re: [Vo]:On deception Did you see this recent post as follows: =============================== If you remember this thread as follows: Entangled proton pairs show enhanced tunneling - 1/31/12 Why do entangled proton pairs pass through the coulomb barrier of a heavy element nucleus with high probability in collisions with energies well below those required to breach this barrier? This curiosity has been observed is heavy low energy ion collision studies. http://arxiv.org/pdf/1101.1393.pdf This letter presents evidence that (1) 2p transfer (and not _-particle transfer) is the dominant transfer process leading to _Z = 2 events in the reaction 16O+208Pb at energies well below the fusion barrier, and (2) 2p transfer is significantly enhanced compared to predictions assum- ing the sequential transfer of uncorrelated protons, with absolute probabilities as high as those of 1p transfer at energies near the fusion barrier. Measurements of transfer probabilities in various reac- tions and at energies near the fusion barrier have there- fore been utilized to investigate the role of pairing corre- lations between the transferred nucleons. Pairing effects are believed to lead to a significant enhancement of pair and multi-pair transfer probabilities [2, 4{7]. Closely re- lated to the phenomenon of pairing correlations is the nuclear Josephson effect [8], which is understood as the tunneling of nucleon pairs (i.e. nuclear Cooper-pairs) through a time-dependent barrier at energies near but be- low the fusion barrier. This effect is believed to be similar to that of a supercurrent between two superconductors separated by an insulator. An enhancement of the trans- fer probability at sub-barrier energies is therefore com- monly related to the tunneling of (multi-)Cooper-pairs from one superfluid nucleus to the other [2]. Following up on this thread as follows: There has been a new type of Klein tunneling proposed where a high-potential barrier can be made transparent. Even though the barrier is impenetrable for single particles, it becomes transparent when the two particles cross the energy barrier together. Coupled particles cross energy wall http://www.springer.com/about+springer/media/springer+select?SGWID=0-11001-6 -1421254-0 On Sat, Jun 1, 2013 at 1:51 PM, <pagnu...@htdconnect.com> wrote: Axil, I missed that post. Can you repost the reference. Does it have any relationship with the following arxiv.org paper that might be relevant in plasmons? "New Enhanced Tunneling in Nuclear Processes" http://arxiv.org/abs/nucl-th/0307012 ABSTRACT: The small sub-barrier tunneling probability of nuclear processes can be dramatically enhanced by collision with incident charged particles. Semiclassical methods of theory of complex trajectories have been applied to nuclear tunneling, and conditions for the effects have been obtained. We demonstrate the enhancement of alpha particle decay by incident proton with energy of about 0.25 MeV. We show that the general features of this process are common for other sub-barrier nuclear processes and can be applied to nuclear fission. -- Lou Pagnucco Axil^2 wrote: > I showed Joshua Cude an experiment using Nanoplasmonic processes that > changed the alpha particle emission half-life of U232 form 69 years to 6 > microseconds. > [...]
