Since the mid-20th century, it has been understood that Maxwell's equations are not exact laws of the universe, but are a classical approximation to the more accurate and fundamental theory of quantum electrodynamics. In most cases, though, quantum deviations from Maxwell's equations are immeasurably small. Exceptions occur when the particle<http://en.wikipedia.org/wiki/Photon>nature of light is important or for very strong electric fields.
On Sat, Jan 18, 2014 at 3:18 PM, David Roberson <[email protected]> wrote: > Maxwell's equations are classical and quantum mechanics are the more > recent theory. I am wondering how quantum mechanics explains this > behavior. Or, do they remain silent about the effect? > > What wave function allows this to occur? > > Dave > > > > -----Original Message----- > From: Axil Axil <[email protected]> > To: vortex-l <[email protected]> > Sent: Sat, Jan 18, 2014 2:49 pm > Subject: Re: [Vo]:The photo reactor > > EMF concentration is just on of the features that the Maxwell equations > allow to happen. With the proper methods, materials and procedures > involving EMF waveforms(sub-wave-length focusing and resonances), > restrictions on EMF concentration can be overcome to fantastic levels. > > The deep infrared(terahertz) is ideal for this type of wavelength > manipulation because the wavelength is so long. > > > On Sat, Jan 18, 2014 at 2:30 PM, David Roberson <[email protected]>wrote: > >> Axil, >> >> How does quantum mechanics explain this phenomenon? Is this new physics >> of some type or just super heating of the region where the IR contacts the >> particles? >> >> The IR must induce an extremely large electron current flow on the >> surface of the metal which of course leads to a strong magnetic field. Is >> it this field that lowers the threshold required to fuse? One of my >> favorite concepts is that the electric field induced by the rapidly >> changing magnetic field could accelerate protons so that they fuse. This >> would be a form of hot fusion if active. >> >> What is your opinion as to the mechanism? >> >> Dave >> >> >> >> -----Original Message----- >> From: Axil Axil <[email protected]> >> To: vortex-l <[email protected]> >> Sent: Sat, Jan 18, 2014 2:09 pm >> Subject: [Vo]:The photo reactor >> >> Beside neutrons, there is another less traveled road to the initiation >> of nuclear reactions that has been under the radar in the nuclear community. >> >> Many years ago, it was shown that high energy lasers could induce fission >> and fusion if the power of the laser pulse was strong enough >> >> http://physics.aps.org/story/v5/st3 >> >> Photo induced nuclear reactions begin to occur when the power density of >> the infrared light reached just under 10^^20 W/cm2. >> >> Since the time of unaided photo nuclear reactions were demonstrated at >> the turn of this century, it has been shown that gold nano-particles used >> as nano-lenses can amplify and concentrate infrared light by 9 orders of >> magnitudes. This is experimentally verified performance that comes out of >> the science of Nanoplasmonics. >> >> Now with gold Nano-particles, it is logical to expect nuclear reactions >> will occur when laser light with an intensity of 10^^10 W/cm2 to 10^^12 >> W/cm2 will occur. If you are interested, experimental results have been >> published as verification. That is 9 orders of magnitude less than unaided >> photo irradiation. Experiments using gold nano-particles in water >> suspension irradiated by laser light of this reduced level of intensity do >> in fact occur. >> >> Since then, experimentally verified light amplification by >> nano-structures has been observed to reach a top end of 10 to the 15 power. >> >> The idea is that if more and more nano-particle infrared photo >> concentration is applied to a system, then less and less infrared photon >> input energy will produce a nuclear reaction. >> >> In current photo reactors under development, with additional tweaking of >> more effective methods and materials, together with improved nano-structure >> shapes and topology, it is not unreasonable to expect that 10 to the 20th >> power concentration or more of photo application might be reached. >> >> In current photo based nuclear reactors, that means that it is reasonable >> to assume that nuclear reactions will occur if UNAPMLIFIED infrared light >> were to interact with properly engineered nanostructures. >> >> Increased infrared photo amplification is what has been done in the >> design of the current crop of Nickel/Hydrogen reactors. >> >> By the way, both the Mills reactor and the Santilli process are other >> examples of photo reactors but these inventors just don’t know it yet. >> >> The Open Physical Chemistry Journal, 2013, 5, 17-27 >> >> Confirmations of Santilli’s Intermediate Controlled Nuclear Fusion of >> Deuterium and Carbon Into Nitrogen Without Harmful Radiations >> >> J. V. Kadeisvili, C. Lynch and Y. Yang >> >> Abstract: We present five independent confirmations of the intermediate >> controlled nuclear fusion of Nitrogen from Deuterium and Carbon without the >> emission of harmful radiations or the release of radioactive waste, first >> achieved by R. M. Santilli [12] following extended mathematical, >> theoretical and experimental research, and preliminarily confirmed by >> R.Brenna, T. Kuliczkowski, and L.Ying [13]. >> >> http://www.benthamscience.com/open/topc ... 7TOPCJ.pdf >> >> This is just another spark driven nanoplasmonic LENR system. >> >> The photo driven anapole magnetic field produced by nanoparticles is >> recognized by the inventor but it is called a Santilli magnecules. >> >> A pattern is forming involving spark driven nanoparticle based LENR >> systems: Santilli, Mills, Rossi and DGT. >> >> The inventors of these systems all have a differing theoretical >> explanation of their reaction, but they are all basically the same >> nanoplasmonic driven photo reactors. >> > >
