ALEXIS KARPOUZOS NON DUALITY THE PARTICI (1)

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by Alekos Karpouzos


  7

  THE NEWTONIAN MECHANICS

  The Newtonian mechanics was the model of classical science. In the classical

  science all the natural laws had an absolutely deterministic and descriptive character

  and defined the course and development of every phenomenon. The knowledge of

  these laws assured the human – observer the ability to understand not only the

  present but also the past and the future. In a deterministic and timeless universe, the

  arrow of time is nothing but a human illusion. Only the vision of the universe from the

  perspective of eternity ensures the truth of physical theories.

  In the deterministic universe of the classical science, the order always creates

  disorder and never vice versa! The scientific dream of a united (applying on the

  microcosm as well as on the macrocosm) and objective (i.e. independent of the

  observer) description of the natural world, would become the nightmare of the

  contemporary physics in the beginning of the 20th century. The quantum description

  and interpretation of the microcosm, which is regarded as the fundamental level in

  which all the natural phenomena are raised and explained, requires a radical review

  of not only the classical description but also of the metaphysical preconditions of

  classical science.

  The classical ideal in physics was to be able to predict with certainty the future

  development of a physical system. Newton’s mechanics led to the triumph of the

  deterministic vision of the natural processes: if we know the initial conditions of a

  dynamical system, then the solution of the differential motion equations would allow

  us to know in certainty not only the past but also the future of that system.

  This, however, is not feasible for two reasons: a) it is not possible to have the initial

  conditions of the system in absolute accuracy and b) the analytical solution is not

  feasible for the great majority of the systems. As far as the first reason is concerned,

  we have to mention that after the discovery of the unstable systems, it became clear

  that very neighboring orbits (which, namely correspond to initial conditions and

  whose values may differ slightly) after a certain period of time are removed

  exponentially. In this notion, the orbit is actually an idealization, since it is never

  possible to know the initial conditions in “infinite” accuracy.

  8

  According to Heisenberg’s uncertainty principle and Bohr’s principle of

  correspondence, the neutral and deterministic description of the microcosm is

  impossible: discontinuity and indeterminacy are inherent characteristics of

  microphysical phenomena and in order to describe them we have to integrate the

  observer within his own observations!

  BEYOND THE SEPARATION: THE NEW COSOMOLOGICAL PARADIGM

  Science evolves through alternating phases of 'normal' science and radical shifts

  that create scientific revolutions. We saw this at the turn of the 20th century, when

  science shifted from a Newtonian worldview to Einstein's relativity paradigm, and

  again with the shift to the quantum paradigm. Now, as we recognize the non-local

  interconnection of all things in space and time, we find our scientific worldview

  shifting once again. The insight now emerging in the physical sciences, especially

  but not exclusively in quantum physics, highlights the role of interaction and

  interconnection in the diverse spheres of observation and experiment. He insight now

  emerging in the physical sciences, especially but not exclusively in quantum physics,

  highlights the role of interaction and interconnection in the diverse spheres of

  observation and experiment. The quantum theory holds that we live in a participatory

  universe - which is what we consider as an independent, external reality is linked to

  the way we observe. When making observations and measurements, the quanta

  which are everything in the universe, changing. It makes no sense to talk about the

  properties of quanta without an observer. The universe is connected by conscious

  observation instruments from the most elementary particles up to huge galaxies.

  Moreover, quantum theory gives prominence to the quantum vacuum, the vacuum

  that is prior to observable phenomena, such as atoms and molecules. Unlike the

  common sense notion of empty space, the quantum vacuum is full of potential

  prospects. The quantum vacuum is essential in all aspects of physics, the quantum

  vacuum is an infinite set of "space-time foam" beyond which time, space - and

  physical - come to an end itself. Quantum theory has reached the point where the

  source of all matter and energy is a vacuum, a nothingness that contains all the

  possibilities of everything that has ever existed or could exist.

  9

  These possibilities then emerge as probabilities before “col apsing” into localized

  quanta, manifesting as the particles in space and time that are the building blocks of

  atoms and molecules. The transcendental field of Cosmos is the total of all the

  possibilities that can occur in any part of the universal space-time.

  The quantum vacuum underlies the level of quanta and is a virtual-energy filled

  substrate rather than empty space) is the cosmic matrix in which the particles and

  systems that constitute the materials of the world arise. The quantum vacuum is an

  integration of what we used to think of as energy and information. It is a field of

  informed energy.

  The particles that appear as the material of the universe are entangled excitations of

  the ground state of this cosmic matrix. The systems that appear as objects

  composed of material particles are locally manifest yet intrinsically entangled

  configurations of excitations in that matrix. The particles and systems we observe

  emerged in the course of evolution in the cosmos. Following the Big Bang (which

  appears to have been a Big Bounce, a phase-change in the sequence of local

  universes in the multiverse) the first entities to emerge were photons, protons,

  neutrons and electrons, and other, more short-lived exchange particles. In processes

  of galactic and stellar evolution the higher-order configurations we know as the atoms

  of the elements had emerged.

  The current material of spacetime are superordinate configurations of the excitations

  of the cosmic matrix. Galaxies are composed of stars and stellar systems, and stars

  are composed of atoms and particles. All these systems are composed of particles,

  and particles are entangled excitations of the matrix. Atoms, molecules, cells,

  organisms—and on the macroscale planets, stars, stellar systems and galaxies—are

  in the final count superordinate quantum systems: various-level configurations of

  informed energy.

  On suitable planetary surfaces higher-order configurations of informed energy made

  their appearance. We call the self-maintaining and self-reproducing variety of these

  configurations living organisms. Life is not accidental or extraneous phenomena in

  the universe: the latest observations in astrophysics show that the basic building

  elements of life, including glycine (which is an amino acid), and ethylene gycol (a

  compound associated with the formation of sugars in organisms) are synthesized in

  the course of the physicochemical evolution of sta
rs.

  10

  The surface of planets associated with active stars are templates for the further

  complexification of these elements, building sequentially higher order configurations

  of informed-energy.

  Information is a paramount factor in the emergence and persistence of informed-

  energy configurations. In the absence of information the energies present in the

  universe would be a random concourse of excitations of its ground state. Information

  structures the energy-sea of the cosmic matrix, and coordinates interaction among

  the structures.

  QUANTUM THEORY

  Quantum theory arose from the scientific attempt to describe the behavior of atoms

  and their components. Therefore, it concerns primarily the microcosm. Physicists

  have long known that certain procedures, such as radioactivity, seemed random and

  unpredictable. While a large number of radioactive atoms obey the laws of statistics,

  it is impossible to predict the exact time at which a specific atomic nucleus will split.

  This fundamental uncertainty is extended to all individual and subatomic phenomena.

  The word "quantum" by itself means a small energy package, i.e a very small

  package (from the Latin word quandum). Thus, quantum mechanics, as quantum

  theory is called, has to do with the basic keystones of matter. These are the basic

  elementary particles which build up everything in nature. These particles include

  atoms, molecules, neutrons, protons, electrons, quark, and also photons (the basic

  light units). All these objects - if we can really describe them as such - are much-

  much smaller than anything that can be seen and observed by the human eye.

  In the dreamy quantum world: the particles are waves and the waves are particles.

  That is, a beam light is both an electromagnetic wave propagating in the universe,

  and a flow of tiny particles directed with speed towards the observer. This arises from

  the fact that some quantum experiments or phenomena reveal the wave nature of

  light, whereas others reveal the particulate nature the same light. Note though that

  never both aspects of light are revealed simultaneously. Nevertheless, we suggest

  that before we observe a beam of light it is both a wave and a particle flow at the

  same time.

  11

  In the realm of quantum physics everything is ambiguous: a feature of uncertainty

  dominates on all its entities, whether it is light, electrons, atoms or quarks. This

  uncertainty is known as the uncertainty principle and it states that we can only predict

  the most probable position of a particle and not the exact location. Moreover, we are

  never able to determine with exact precision nor the position or the momentum of a

  particle. Therefore, the scientific predictions on the results have a statistical and

  probabilistic nature. Moreover, there are no "hidden variables" (as Einstein would

  like), which, if were made known, would dispel the fog that surrounds the quantum

  world. Therefore, the magical, the obscure, and the hidden, are the integral features

  of the quantum structure of the universe.

  For the interpretation of quantum mechanics there is a need for an ontological

  investigation and reflection: Because what explanation can be given for the

  mysterious superposition of the states of the quantum systems?

  A photon (a quantum of light) or an electron (a negatively charged elementary

  particle) can be found in a superposition of two or more states. We can no longer talk

  about "here" OR "there". In the strange quantum world we can talk about "here" AND

  "there." A photon, a part of a flow of light, that falls on a film screen with two holes,

  instead of choosing one or the other hole as normally expected, can pass through

  both of the two holes at the same time. An electron that follows a curved path around

  a nucleus can be possibly located in multiple positions simultaneously.

  The phenomenon that creates the greatest wonder in the dreamy world of quanta is

  the phenomenon called Quantum Entanglement. Two particles that may be too far

  away from each other, even millions or billions of kilometers away, are strangely

  linked. The slightest variation that may occur in one of them immediately causes a

  change in the other.

  The quantum theory is primarily a practical field of physics. The quantum theory

  helped to achieve brilliant technological developments such as nuclear power,

  transistors, electron microscopy, lasers, and superconductors. Also, it explained the

  structure of atoms and nuclei, the chemical bonds, the mechanical and thermal

  properties of solids, the electrical conductivity, the iciness of collapsed stars, and

  many other important natural phenomena.

  12

  The quantum theory has been proven by a vast majority of evidences that arise not

  only by the relevant devices found in trade, but also by carefully designed scientific

  experiment. Thus, most of the theoretical physicists simply perform their tasks

  without reflecting on the bizarre philosophical implications of quantum theory. This is

  proof that the ideology of common sense and positivism dominates on the western

  civilization’s "cosmic theory of knowledge."

  On the other hand, the mathematical theory of Hilbert space, the abstract algebra,

  and the probability theory – which are the mathematical tools used for the

  explanation of quantum phenomena - allow the prediction of highly-precise results

  from the experiments, although they do not make us understand the processes

  behind this phenomenon.

  It looks like that the mysterious box of a quantum system is beyond the human limits

  of genuine understanding. According to one of the interpretations of quantum

  mechanics, we can only use the box to predict results, which are simply statistical in

  nature.

  The understanding of modern physics and mathematics does not arise from their

  "language" or their equations but from the importance expressed through this

  language. This means a shift the effort to interpret the phenomena using the

  horizontal mathematical formalism of epistemology to the vertical mathematical

  structuralism of ontology. In other words, a shift from scientism to the philosophical

  science.

  13

  THE END OF CERTAINTY

  CHAOS, COMPLEXITY AND SELF-ORGANIZED SYSTEMS

  The Newtonian mechanics was the model of classical science. In the classical

  science all the natural laws had an absolutely deterministic and descriptive character

  and defined the course and development of every phenomenon. The knowledge of

  these laws assured the human – observer the ability to understand not only the

  present but also the past and the future. In a deterministic and timeless universe, the

  arrow of time is nothing but a human illusion. Only the vision of the universe from the

  perspective of eternity ensures the truth of physical theories. In the deterministic

  universe of the classical science, the order always creates disorder and never vice

  versa! The scientific dream of a united (applying on the microcosm as well as on the

  macrocosm) and objective (i.e. independent of the observer) description of the

  natural world, would become the nightmare of the contemporary physics in the

  beginning of the 20th century. The quant
um description and interpretation of the

  microcosm, which is regarded as the fundamental level in which all the natural

  phenomena are raised and explained, requires a radical review of not only the

  classical description but also of the metaphysical preconditions of classical science.

  The classical ideal in physics was to be able to predict with certainty the future

  development of a physical system. Newton’s mechanics led to the triumph of the

  deterministic vision of the natural processes: if we know the initial conditions of a

  dynamical system, then the solution of the differential motion equations would allow

  us to know in certainty not only the past but also the future of that system. This,

  however, is not feasible for two reasons: a) it is not possible to have the initial

  conditions of the system in absolute accuracy and b) the analytical solution is not

  feasible for the great majority of the systems. As far as the first reason is concerned,

  we have to mention that after the discovery of the unstable systems, it became clear

  that very neighboring orbits (which, namely correspond to initial conditions and

  whose values may differ slightly) after a certain period of time are removed

  exponentially. In this notion, the orbit is actually an idealization, since it is never

  possible to know the initial conditions in “infinite” accuracy.

  14

  According to Heisenberg’s uncertainty principle and Bohr’s principle of

  correspondence, the neutral and deterministic description of the microcosm is

  impossible: discontinuity and indeterminacy are inherent characteristics of

  microphysical phenomena and in order to describe them we have to integrate the

  observer within his own observations!

  Ρrigozine believed that the laws of nature and those of physics are not given apriori,

  nor are they entailed logically. They evolve in the same way the various species

  evolve. Since things are becoming more multiple, bifurcations and aids occur and

  new laws appear. “How can you be talking about the laws of biology if there are no

  living systems?” This proves the creativity of life. Each level of organization produces

 

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