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Bossonova fermion cancer magnetic-field resonance calls for catastrophic water affine telomeres protein gravity funneling of cross graphics e [Incident: 140130–000009] [email protected] hubblesite.org support: ISSUE=6794 PROJ=13
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Sankaravelayudhan Nandakumar Nandakumar
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Tractor wave in laser biostimulation may be used for genetic corrections using invisible cloaking dynamics combinations.
Three twisted supercapacitors connected in series could be used toto manipulate a invisible cloaking dynamics says Sankaravelyudhan Nandakumr in addition to tractor bessel beam connected genetic ATGU language may be used to correct a genetic defect as observed in the palm print at the meeting point of health line with life line.

An information available from Bossonova twisters may be utilised in all electronic super computers Bossonova twisters can be pushed up or down and this information could be utilise in Aerospace vehicles .The Electron by cross polarisation will act as twister by magnetic or electric field twisting may act as a capacitor says Sankaravelayudhan Nandakumar.They are really optical rogue waves by funnelling at the middle and sometimes at extereme domains for future merger and this could be utilise in our quantum entaglement teleportation in future.Electrons , pinned. as actually when an electron can behave like a sort of wave in the solid, but only an electron can stop an electron by their mutual interaction—their motion is almost freezed out. That is the essence of correlated electrons. The team was motivated by recent theoretical work which suggested that the behaviour of magnetic monopoles in momentum space is closely related to the anomalous Hall effect.This information will be utilised as extreme inductance algorithm as purely magnetic field as purely capacitive as electricfield monopoles as threseems to be shift by the mode of electron scattering such as a spirality as well as that of reflective dipole polaritons separations.digital 0,1 SQUAD applications.

Applying a magnetic field to a magnetic vortex pushes the vortex away from the center of the disk towards the frame. If one then turns the field off abruptly, the vortex moves either clockwise or counter clockwise on a spiral like trajectory back into its initial position in the center of the disk. This special movement is called gyration. In principal, the perpendicular magnetization of the vortex core can point either upwards or downwards, and four different kinds of movement can be found: right- and left rotating magnetic swirls, combined either with an up- or downward directed perpendicular core magnetization.Super conductive materials repel magneticfield when spin oposite directions and attract when spin in the same directions which becomes the beautiful nano digital circuit.At the quantum level, the forces of magnetism and superconductivity exist in an uneasy relationship. Superconducting materials repel a magnetic field, so to create a superconducting current, the magnetic forces must be strong enough to overcome the natural repulsion and penetrate the body of the superconductor. But there’s a limit: Apply too much magnetic force, and the superconductor’s capability is destroyed
When a magnetic field is applied to a superconducting material, vortices measured in nanometers (1 billionth of a meter) pop up. These vortices, like super-miniature tornadoes, are areas where the magnetic field has overpowered the superconducting field state, essentially suppressing it. Crank up the magnetic field and more vortices appear. At some point, the vortices are so widespread the material loses its superconducting ability altogether.But at critical stoke anstoke resonance on electron pairing at middle cross overs are amplified which seems to be an important finding.Normally the magnetic field is zero at this point ‚but sometimes this theory is broken.There seems to be a converging diverging magneticfield that resonante for such cross overs along gliding the waves fluctuated under certain cross over conditions, but when more magnetic energy is added, the fluctuations disappear and the waves resume their repeating, linear patterns.There seems to be linaer to nonlinaer dynamics at the middle point.Hence, our experts consider them as potential candidates for future non volatile magnetic memories.
Bossonova dynamics deals with frequency shifts at microlevel nanotechnology at electron triplets.
Experiments Unraveled Dynamic Core Movements Of Magnetic Swirls:Skew scattering related hopping observed at spin up and spin down cross resonance seems to be a very interesting phenomena — The spin polarization S( theta) n induced by the skew scattering due to the spin-orbit interaction of the scatterer and the spin unpolarized electron beam for polarization
In March 2011, Chinese scientists posited that a specific type of Bessel beam (a special kind of laser that that does not diffract at the centre) is capable of creating a pull-like effect on a given microscopic particle, forcing it towards the beam source.[31][32] The underlining physics is the maximization of forward scattering via interference of the radiation multipoles. They show explicitly that the necessary condition to realize a negative (pulling) optical force is the simultaneous excitation of multipoles in the particle and if the projection of the total photon momentum along the propagation direction is small, attractive optical force is possible.[33] The Chinese scientists suggest this possibility may be implemented for optical micromanipulation.
Applying a magnetic field to a magnetic vortex pushes the vortex away from the center of the disk towards the frame. If one then turns the field off abruptly, the vortex moves either clockwise or counter clockwise on a spiral like trajectory back into its initial position in the center of the disk. This special movement is called gyration. In principal, the perpendicular magnetization of the vortex core can point either upwards or downwards, and four different kinds of movement can be found: right- and left rotating magnetic swirls, combined either with an up- or downward directed perpendicular core magnetization.
Sankaravelyudhan Nandakumar ‚Astro geneticist
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Sankaravelyudhan Nandakumar,Hubble research scholar http://www.hawking.org.uk
[email protected]

Negative magnetic material on lunar surface is frequency selective.

Negative materials are nevertheless easy to find. Materials with ε negative include metals (e.g., silver, gold,aluminum) at optical frequencies, while materials with negative include resonant ferromagnetic orantiferromagnetic systems silicon dioxide, also known as silica, the primary component of sand, glass, and concrete. Broken down by element, about 43% of lunar soil is oxygen, 21% silicon, 13% iron, 8% calcium, 6% aluminum, 5% magnesium, and 4% other elements Cavities in rock crystal are called “negative crystals”; those containing bubbles are known as two-phase inclusions, and interior ‘cracks’ appear as iridescence.

We first need to understand what it means to have a negative ε or μ , and how it occurs in materials. The Drude-Lorentz model of a material is a good starting point, as it conceptually replaces the atoms and molecules of a real material by a set of harmonically bound electron oscillators, resonant at some frequency ω0 . At frequencies far below ω0 , an applied electric field displaces the electrons from the positive core, inducing a polarization in the same direction as the applied electric field. At frequencies near the resonance, the induced polarization becomes very large, as is typically the case in resonance phenomena; the large response represents accumulation of energy over many cycles, such that a considerable amount of energy is stored in the resonator (medium) relative to the driving field. So large is this stored energy that even changing the sign of the applied electric field has little effect on the polarization near resonance! That is, as the frequency of the driving electric field is swept through the resonance, the polarization flips from in-phase to out-of-phase with the driving field and the material exhibits a negative response. If instead of electrons the material response were due to harmonically bound magnetic moments, then a negative magnetic response.

That negative material parameters occur near a resonance has two important consequences. First, negative material parameters will exhibit frequency dispersion: that is to say they will vary as a function of frequency. Second, the usable bandwidth of negative materials will be relatively narrow compared with positive materials. This can help us answer our initial question as to why materials with both negative ε and μ are not readily found. The resonances in existing materials that give rise to electric polarizations typically occur at very high frequencies, in the optical, for metals, or at least in the THz to infrared region for semiconductors and insulators. On the other hand, resonances in magnetic systems typically occur at much lower frequencies, usually tailing off toward the THz and infrared region. In short, the fundamental electronic and magnetic processes that give rise to resonant phenomena in materials simply do not occur at the same frequencies, although no physical law would preclude this.

An interesting question arises if there is absorption in the system represented by positive imaginary parts of either or both of ε and μ . Conditions for the theorem may still be satisfied but require that for every instance of a positive part to ε,μ there is a mirror antisymmetric negative ε,μ somewhere else in the system. This implies that parts of the system must exhibit gain. Loss can only be compensated by active amplification.
At frequencies above ω0 and below ωp , the permittivity is negative and, because the resonant frequency can be set to virtually any value in a metamaterial, phenomena usually associated with optical frequencies—including negative ε —can be reproduced at low frequencies., the path to achieving Electrons emit light over a broad spectrum of wavelengths when they change their direction of motion or speed.

Sankaravelayudhan Nandakumjar, Oxford astrogeneticist

Waxing and waning of lunar surface producing frequency based selective band width becoming negative refractive index medium with refractio9n and amplification as focal length becomes a curvature as f=R/1-n .This gives a clue that along the plane of hologram with solar rays interference the medium as lunar surface behave typically to enhance negative refractive index. The negative band width is relatively small narrow. This giver rise to electric polarisation at high frequencies and a resonance occurs at lower frequencies. A negative refractive index implies that the phase of the medium advancing will be negative and th amplification is a function of thickness varied bey the angle of incidence of solar rays.Thus the resonance frequency is determined by the geometry of lunar surface lattice. Thus the eighth cusp from new moon seems to be very important factor of increased invisible cloaking dynamics

Sankaravelyudhan Nandakumar, Hubble research scholar http://www.hawking.org.uk
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