Celalettin-Field Quantum Observation Tunnel

The 'Celalettin-Field Quantum Observation Tunnel' (Celalettin Tunnel) is a theoretical speculative structure that contributes to Quantum Theory by attempting to further an understanding of how a quantum system reaches quantum decoherence^[1].

Celalettin introduces a concept 'Quantum Interaction^[2]' which is based on filling an electron hole in a superposition with a free electron^[2][3].

Theoretical Use

The 'Celalettin Tunnel' was originally developed to protect stealth fighter jets^[4][2] from Quantum Radars, however more recently it is being used in research to develop a hand held Magnetic Resonance Imaging (MRI) machine which would remove the need to administer anasthesia to paediatric patients in order to image them.^[5] Dr Metin Celalettin initially created the tunnel after a career as a counterintelligence field investigator in a little known counterintelligence agency within the Defence Intelligence Group^[2], Australian Government Department of Defence in order to protect fighter jets from a Quantum Radar.

Celalettin writes that he was recruited by a Brigadier from the Defence Intelligence Organisation who stated Celalettin was recruited "for his mind" because he scored a considerably high IQ and was diagnosed with Low Latent Inhibition during recruitment psychometric testing.^[2]

Creation

The 'Celalettin-Field Quantum Observation Tunnel', often referred to as the 'Celalettin Tunnel' was created and named after quantum physicist Dr Metin Celalettin^[4][6]. The 'Celalettin Tunnel' purportedly enables an incoming photon to penetrate an atomic ensemble of nuclear spin polarized particles with an applied anti-ferromagnetism^[7].

The incoming photon depolarizes orbital angular momentum (OAM) polarized particles, leaving a tunnel behind via Compton scattering^[1]. When the depolarized particles are considered as a single system rather than individual particles, evidence of sampling the photon exists in the form of imaging the tunnel's size; satisfying Heisenberg's definition of Quantum Observation^[2][8][1].

Celalettin-Field Quantum Observation Tunnel formulation

The 'Celalettin Tunnel' formulation runs several quantum and classical equations simultaneously. Specifically the wave function, Mathieu differential equation, Lagrangian plasma QED equation, the Lorentz quantum parameter causing OAM ‘existing with (∃)’ χ polarization (Spin-Spin Coupling), over Time (t) it takes an applied anti-ferromagnetism to re-polarize the atomic ensemble in which it is created^[2]. Such an arrangement enables both the 'Celalettin Tunnel' to be created and satisfies Heisenberg's criteria for quantum observation^[8][4].

Relevance to Quantum Theory

Theoretically, imaging the tunnel using advanced imaging techniques would provide information on the wavelength of the photon, thereby 'observing' it quantumly and subsequently causing wave function collapse^[9]. The 'Celalettin Tunnel' theoretically provides clarity to the Quantum Mechanics interpretation problem, as it proposes a chemically engineered atomic ensemble as its medium in which it causes wave function collapse^[3][4] via the 'Celalettin Tunnel'^[1].

Prior to the creation of the 'Celalettin Tunnel', quantum observation instruments were classically photodiode detectors as used in the double slit experiment^[7]. The interaction between the photon and the electrons in the 'Celalettin Tunnel's medium is similar to the Photoelectric effect in that energy is passed from photon to electron to cause the phenomena^[9].

References