Quantum Computer ( Information ) and Quantum Mechanical Behaviour - A Quid Pro Quo Model

Perception may not be what you think it is. Perception is not just a collection of inputs from our sensory system. Instead, it is the brain's interpretation (positive, negative or neutral-no signature case) of stimuli which is based on an individual's genetics and past experiences. Perception is therefore produced by (e) brain‘s interpretation of stimuli .The universe actually a giant quantum computer? According to Seth Lloyd--professor of quantum-mechanical engineering at MIT and originator of the first technologically feasible design for a working quantum computer--the answer is yes. Interactions between particles in the universe, Lloyd explains, convey not only (to+) energy but also information-In brief, a quantum is the smallest unit of a physical quantity expressing (anagrammatic expression and representation) a property of matter having both a particle and wave nature. On the scale of atoms and molecules, matter (e&eb) behaves in a quantum manner. The idea that computation might be performed more efficiently by making clever use (e) of the fascinating properties of quantum mechanics is nothing other than the quantum computer. In actuality, everything that happens (either positive or negative e&eb) in our daily lives conforms (one that does not break the rules) (e (e)) to the principles of quantum mechanics if we were to observe them on a microscopic scale, that is, on the scale of atoms and molecules. But because a great many degrees of freedom (such as a huge number of atomic movements) contribute to phenomena that we as human beings can perceive, this quantum mechanical behavior is normally hidden (not perceived-e(e)) by us. That it is not in the visible field; We cannot see it let alone decipher the progressive movements and dynamics of the system. Yet, if we were to look into the world of individual atoms, we would find that an electron (+) moving about the atomic nucleus can only take on (e) energy having specific (discrete) values. In other words, an electron may enter only a fixed number of set states. It is like I can build house in my site; not on somebody‘s site or on corporation designated area for public utility; This resembles the way in which strings on a guitar can only resonate at set frequencies, and(e some light&eb some light ) reflects the wave nature of quantum states. This electron, moreover, may take on a "superposition state" that combines (e&eb) different energy states simultaneously. Superposition state is important concept in quantum computing. Applying a strong electric field to an atom can also (eb) make the electrons circulating around it tunnel through a wall created (eb) by strong nuclear binding energy and (eb or=) become unbound. Although the tunneling of say a soccer ball through a wall does not occur in reality, this kind of phenomenon can occur in the microscopic world. Such quantum mechanical behavior must be artificially (e&eb) controlled and measured to achieve (eb) a quantum computer. Quantum computer thus utilizes (e) Quantum mechanical behaviour that is artificially controlled. Quantum mechanical behavior in state one controls (e&eb) Quantum Mechanical behviour in state two. R. Schilling, M. Selecky, W. Baltensperger studied the influence (e&eb) of the hyperfine interaction ∼ Sn. In between the ionic and the nuclear spins at the site n on the Eigenvaluesof a 2-domain Heisenberg ferromagnetic with a 180% -domain wall. A level splitting is obtained even when 〈Sn〉 = 0 due (e) to quantum fluctuations The idea quantum states used for a computer first came about in the 1980s. In 1985, David.tsch, a professor at Oxford University and a proponent of quantum computers, wrote a paper titled "Quantum theory, the Church-Turing principle, and the universal quantum computer" that touched upon the possibility of quantum computers. Frank Verstraete, Michael M. Wolf & J. Ignacio Cirac STUDIED THE EFFECTS OF QUANTUM MECHANICAL STATES ON QUANTUM