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What is Quantum Mechanics? What is the Quantum Scale? What is Resonance on the Quantum Scale? What it means for music? Quantum Mechanics What is it? • Quantum mechanics is the science of the very small. Quantum mechanics explains the behavior of matter and its interactions with energy on the scale of atoms and subatomic particles. • In contrast, classical physics only explains matter and energy on a scale familiar to human experience, including the behavior of astronomical bodies such as the Moon. Classical physics is still used in much of modern science and technology. However, towards the end of the 19th century, scientists discovered phenomena in both the large (macro) and the small (micro) worlds that classical physics could not explain. • The reason for this difference comes from the treatment of matter in quantum mechanics as having properties of waves and particles. One interpretation of this duality involves the Heisenberg uncertainty principle, which defines a limit on how precisely the position and the momentum of a particle can be known at the same time.[4] • What the uncertainty principle tells us is that no matter how careful we are, no matter how precise our instrumentation, we can never pin down both the particle-like and the wave-like properties of a quantum entity, whether it be a photon or an electron, a quark or a neutrino(that’s everything). The uncertainty principle is a statement that is fundamental to nature, to the universe, whether we are there to measure it or not. • Quantum Entanglement: sub atomic particles are entangled which means they subtlety and instantaneously influence each other across space. • Quantum tunneling refers to the quantum mechanical phenomenon where a particle tunnels through a barrier that it classically could not surmount Quantum Entanglement: Quantum entanglement is a physical phenomenon that occurs when pairs or groups of particles are generated or interact in ways such that the quantum state of each particle cannot be described independently — instead, a quantum state must be described for the system as a whole. Measurements of physical properties such as position, momentum, spin, polarization, etc., performed on entangled particles are found to be appropriately correlated. However, this behavior gives rise to paradoxical effects: any measurement of a property of a particle can be seen as acting on that particle and will change the original quantum property by some unknown amount; and in the case of entangled particles, such a measurement will be on the entangled system as a whole. It thus appears that one particle of an entangled pair "knows" what measurement has been performed on the other, and with what outcome, even though there is no known means for such information to be communicated between the particles, which at the time of measurement may be separated by arbitrarily large distances. Quantum Entanglement: sub atomic particles are entangled which means they subtlety and instantaneously influence each other across space. Quantum Tunneling/Communication Quantum tunneling refers to the quantum mechanical phenomenon where a particle tunnels through a barrier that it classically could not surmount. This plays an essential role in several physical phenomena, such as the nuclear fusion that occurs in main sequence stars like the Sun.[1] It has important applications to modern devices such as the tunnel diode,[2] quantum computing, and the scanning tunnelling microscope. The effect was predicted in the early 20th century and its acceptance as a general physical phenomenon came midcentury.[3] Tunneling is often explained using the Heisenberg uncertainty principle and the wave–particle duality of matter. Pure quantum mechanical concepts are central to the phenomenon, so quantum tunneling is one of the novel implications of quantum mechanics. Quantum Realm/Scale The quantum realm, also called the quantum scale, is a term of art in physics referring to scales where quantum mechanical takes effects. Typically, this means distances of 100 nanometers (10−9 meters) or less or at very low temperature. In physics, a quantum (plural: quanta) is the minimum amount of any physical entity involved in an interaction. This means that the magnitude of the physical property can take on only certain discrete values. For example, a photon is a single quantum of (visible) light as well as a single quantum of all other forms of electromagnetic radiation, and can be referred to as a "light quantum". The energy of an electron bound to an atom is also quantized, and thus can only exist in certain discrete values. As a result, atoms are stable, and hence matter in general is stable. As incorporated into the theory of quantum mechanics, this quantization of the energy of electrons and the resulting implications are regarded by physicists as part of the fundamental framework for understanding and describing nature. Examples of Quantum Scale: natural self-assembly bottom-up technological self-assembly UV lithography electron-beam lithography top-down nano-imprint lithography scanning probe lithography 3' animal cells viruses proteins, antibodies 5' small molecules ribosomes human hair genes bacteria chromosomes atoms DNA bases 0.1 nm crystalline lattices 1 nm carbon nanotubes 10 nm quantum dots 100 nm gates of transistors 1 µm 10 µm electromechanical, fluidic, optical, magnetic microsystems 100 µm 1 mm DNA microarrays Graphics by https://guillaumepaumier.com/ The Centrosome, in most animal cells, acts as a Microtubule Organizing Center. Most Centrosomes contain a pair of Centrioles arranged at right angles to each other in an L-shaped configuration. A Centriole is about 200 nm wide and 400 nm long. Its wall is made up of 9 groups of 3 microtubles. Each microtubule is a hollow cylindrical tube with about 25 nm outside diameter and 14 nm inside diameter, made up of 13 columns of Tubulin Dimers. Each Tubulin Dimer is about 8 nm x 4 nm x 4 nm, consists of two parts, alpha-tubulin and beta-tubulin (each made up of about 450 Amino Acids, each of which contains roughly 20 Atoms), and can exist in (at least) 2 different geometrical configurations, or conformations, involving the position of a single Electron. ( The two preceding illustrations are from Molecular Biology of the Cell, 2nd ed, by Alberts, Bray, Lewis, Raff, Roberts, and Watson (Garland 1989) Resonance: at the Quantum Scale is the key that binds us to music • Resonance is the means through which vibrational energy can get transferred from one physical entity to another with great efficiency. Instruments are designed to resonate at a discrete set of frequencies- The Jazz of Physics, Stephon Alexander • The term resonance originates from the field of acoustics, particularly observed in musical instruments, e.g., when strings started to vibrate and to produce sound without direct excitation by the player. • Resonance phenomena occur with all types of vibrations or waves: there is mechanical resonance, acoustic resonance, electromagnetic resonance, nuclear magnetic resonance (NMR), electron spin resonance (ESR) and resonance of quantum wave functions. • Acoustic resonance is an important consideration for instrument builders, as most acoustic instruments use resonators, such as the strings and body of a violin, the length of tube in a flute, and the shape of a drum membrane. Acoustic resonance is also important for hearing. For example, resonance of a stiff structural element, called the basilar membrane within the cochlea of the inner ear allows hair cells on the membrane to detect sound. (For mammals the membrane has tapering resonances across its length so that high frequencies are concentrated on one end and low frequencies on the other.) • Resonance in particle physics appears in similar circumstances to classical physics at the level of quantum mechanics and quantum field theory. • Sound, music and many of the wonders of the quantum universe would not be possible without resonance The physics of resonance governs why a saxophone plays a particular note. • The physics of baryogengesis is resonance. Quantum fields are like extended material and like a string, can vibrate with many resonant frequencies…Quantum fields can interact each other. Particles are resonant vibrations of quantum fields can be realized similar to how musical notes are created by plucking a guitar string • Robin’s chemical compass (navigation) based on QM / Quantum Entanglement: a photon entering their eye creates an entangled pair of electrons, each electron has two possible states, but note until it is measured the electron exists in the two possible states at the same time. As the robin flies it chemical compass is making changes in their flight pattern as it corresponds to logistics of the earth’s magnetic north pole. I theorize just as a robin’s sensitivity to the earth’s magnetic wave/frequency; humans/living cells also have similar sensitivity to the heartbeat frequency/wave; this the quantum resonance of music-the reason that music is so compelling for humans ! • Conga & drums • Saxophone & drums • Piano & drums • Quantum Septet Now lets show how the heartbeat resonates the music! Acknowledgements/Reference Materials The Jazz of Physics-Stephon Alexander, 2016 Music and the Making of Modern Science-Peter Pesic, 2014 PhiloPhysics BANNED BY CORNELL-Frank Dodd (Tony) Smith Jr., 2004 The Fabric of the Cosmos-Brian Greene, 2004 The Hidden Reality-Brian Greene, 2011 Drumming at the Edge of Magic-Mickey Hart, 1990 L’Opera-Bill Dixon, 1986 An Objective Psychology of Music-Robert W. Lundin, 1953 Secrets Of Quantum Physics-Quantum Biology Theory, 2016 https://youtu.be/KhZXJsCKXvc Wikipedia, https://en.wikipedia.org/wiki/Portal:Science