FREE ENERGY scifi science concept model of the "way things may appear to be " in the future.
DISCLOSURE
by Henryk Szubinski
cardboard cut out project .
Rotating hard paper types of effects that are harmonic with the light weight effect of the sun and it's energy that rotates bits of paper in some special way
similar to the flux field or the vacuum energy as closest to the zero gravity way a piece of paper would move in space. The solar effect of pushing the paper has very close zero gravity effects though the rotation is faster and generates as ZERO GRAVITY SURFACE ROTATION WITH THE SUNS ENERGY.
The holes on the model to the left may have crystal type lenses that focus the light through the disc and it's openings so that the rotation functions faster.The disc that projects the sun light may also be made into a smile hole, though upside down.
That the radius is reduced to the holes in the surface means that the diameter effect of Inertia has greatly increased by being positioned along the edges of the type
mass invertion of the radius and diameter. The mass invertion will function for the NON MASS present so that the rotation of this will simulate ZERO GRAVITY with no radius and no diameter.
Basis of the vacuum displacing the mass as zero mass by the motion of light along the edges of the internal radius openings by simulated weight of the light =m.
That the mass of rotation of zero gravity rotation and lite weights surfaces on Earth are similar, means that their FLUCTUATION of the Surface are similar.
The fluctuation may be defined by a variety of fluctuations such as,
from Wikipedia
date, 18,08,2016
time, 20:37
In quantum physics, a quantum fluctuation (or quantum vacuum fluctuation or vacuum fluctuation) is the temporary change in the amount of energy in a point in space,[1] as explained in Werner Heisenberg's uncertainty principle.
According to one formulation of the principle, energy and time can be related by the relation[2]
{\displaystyle \Delta E\Delta t\geq {h \over 4\pi }}This allows the creation of particle-antiparticle pairs of virtual particles. The effects of these particles are measurable, for example, in the effective charge of the electron, different from its "naked" charge.
In the modern view, energy is always conserved, but the eigenstates of the Hamiltonian (energy observable) are not the same as (i.e., the Hamiltonian does not commute with) the particle number operators.
Quantum fluctuations may have been very important in the origin of the structure of the universe: according to the model of inflation the ones that existed when inflation began were amplified and formed the seed of all current observed structure. Vacuum energy may also be responsible for the current accelerated expansion of the universe (cosmological constant).
Primordial fluctuations are density variations in the early universe which are considered the seeds of all structure in the universe. Currently, the most widely accepted explanation for their origin is in the context of cosmic inflation. According to the inflationary paradigm, the exponential growth of the scale factor during inflation caused quantum fluctuations of the inflaton field to be stretched to macroscopic scales, and, upon leaving the horizon, to "freeze in". At the later stages of radiation- and matter-domination, these fluctuations re-entered the horizon, and thus set the initial conditions for structure formation.
The statistical properties of the primordial fluctuations can be inferred from observations of anisotropies in the cosmic microwave background and from measurements of the distribution of matter, e.g., galaxy redshift surveys. Since the fluctuations are believed to arise from inflation, such measurements can also set constraints on parameters within inflationary theory.
Universal conductance fluctuations (UCF) in quantum physics is a phenomenon encountered in electrical transport experiments in mesoscopic species. The measured electrical conductance will vary from sample to sample, mainly due to inhomogeneous scattering sites. Fluctuations originate from coherence effects for electronic wavefunctions and thus the phase-coherence length {\displaystyle \textstyle l_{\phi }} needs be larger than the momentum relaxation length {\displaystyle \textstyle l_{m}}. UCF is more profound when electrical transport is in weak localization regime. {\displaystyle \textstyle l_{\phi }<l_{c}} where {\displaystyle l_{c}=M\times l_{m}} , {\displaystyle \textstyle M} is the number of conduction channels and {\displaystyle \textstyle l_{m}}is the momentum relaxation due to phonon scattering events length or mean free path. For weakly localized samples fluctuation in conductance is equal to fundamental conductance {\displaystyle \textstyle G_{o}=2e^{2}/h} regardless of the number of channels.
date , 18,08,2016
time , 20:39
In statistical mechanics, thermal fluctuations are random deviations of a system from its average state, that occur in a system at equilibrium.[1] All thermal fluctuations become larger and more frequent as the temperature increases, and likewise they decrease as temperature approaches absolute zero.
Thermal fluctuations are a basic manifestation of the temperature of systems: A system at nonzero temperature does not stay in its equilibrium microscopic state, but instead randomly samples all possible states, with probabilities given by the Boltzmann distribution.
Thermal fluctuations generally affect all the degrees of freedom of a system: There can be random vibrations (phonons), random rotations (rotons), random electronic excitations, and so forth.
Thermodynamic variables, such as pressure, temperature, or entropy, likewise undergo thermal fluctuations. For example, for a system that has an equilibrium pressure, the system pressure fluctuates to some extent about the equilibrium value.
Only the 'control variables' of statistical ensembles (such as N, V and E in the microcanonical ensemble) do not fluctuate.
Thermal fluctuations are a source of noise in many systems. The random forces that give rise to thermal fluctuations are a source of both diffusion and dissipation (includingdamping and viscosity). The competing effects of random drift and resistance to drift are related by the fluctuation-dissipation theorem. Thermal fluctuations play a major role inphase transitions and chemical kinetics.
the shaking of atoms as in a crystal would define the shaking of the lens openings of the above mentioned FREE ENERGY device as they displace through the openings, through the secondary openings and then into the light cast on the lower surface , as shaking in 3 directions.
mass invertion of the radius and diameter. The mass invertion will function for the NON MASS present so that the rotation of this will simulate ZERO GRAVITY with no radius and no diameter.
Basis of the vacuum displacing the mass as zero mass by the motion of light along the edges of the internal radius openings by simulated weight of the light =m.
That the mass of rotation of zero gravity rotation and lite weights surfaces on Earth are similar, means that their FLUCTUATION of the Surface are similar.
The fluctuation may be defined by a variety of fluctuations such as,
from Wikipedia
date, 18,08,2016
time, 20:37
In quantum physics, a quantum fluctuation (or quantum vacuum fluctuation or vacuum fluctuation) is the temporary change in the amount of energy in a point in space,[1] as explained in Werner Heisenberg's uncertainty principle.
According to one formulation of the principle, energy and time can be related by the relation[2]
{\displaystyle \Delta E\Delta t\geq {h \over 4\pi }}This allows the creation of particle-antiparticle pairs of virtual particles. The effects of these particles are measurable, for example, in the effective charge of the electron, different from its "naked" charge.
In the modern view, energy is always conserved, but the eigenstates of the Hamiltonian (energy observable) are not the same as (i.e., the Hamiltonian does not commute with) the particle number operators.
Quantum fluctuations may have been very important in the origin of the structure of the universe: according to the model of inflation the ones that existed when inflation began were amplified and formed the seed of all current observed structure. Vacuum energy may also be responsible for the current accelerated expansion of the universe (cosmological constant).
Primordial fluctuations are density variations in the early universe which are considered the seeds of all structure in the universe. Currently, the most widely accepted explanation for their origin is in the context of cosmic inflation. According to the inflationary paradigm, the exponential growth of the scale factor during inflation caused quantum fluctuations of the inflaton field to be stretched to macroscopic scales, and, upon leaving the horizon, to "freeze in". At the later stages of radiation- and matter-domination, these fluctuations re-entered the horizon, and thus set the initial conditions for structure formation.
The statistical properties of the primordial fluctuations can be inferred from observations of anisotropies in the cosmic microwave background and from measurements of the distribution of matter, e.g., galaxy redshift surveys. Since the fluctuations are believed to arise from inflation, such measurements can also set constraints on parameters within inflationary theory.
Universal conductance fluctuations (UCF) in quantum physics is a phenomenon encountered in electrical transport experiments in mesoscopic species. The measured electrical conductance will vary from sample to sample, mainly due to inhomogeneous scattering sites. Fluctuations originate from coherence effects for electronic wavefunctions and thus the phase-coherence length {\displaystyle \textstyle l_{\phi }} needs be larger than the momentum relaxation length {\displaystyle \textstyle l_{m}}. UCF is more profound when electrical transport is in weak localization regime. {\displaystyle \textstyle l_{\phi }<l_{c}} where {\displaystyle l_{c}=M\times l_{m}} , {\displaystyle \textstyle M} is the number of conduction channels and {\displaystyle \textstyle l_{m}}is the momentum relaxation due to phonon scattering events length or mean free path. For weakly localized samples fluctuation in conductance is equal to fundamental conductance {\displaystyle \textstyle G_{o}=2e^{2}/h} regardless of the number of channels.
date , 18,08,2016
time , 20:39
In statistical mechanics, thermal fluctuations are random deviations of a system from its average state, that occur in a system at equilibrium.[1] All thermal fluctuations become larger and more frequent as the temperature increases, and likewise they decrease as temperature approaches absolute zero.
Thermal fluctuations are a basic manifestation of the temperature of systems: A system at nonzero temperature does not stay in its equilibrium microscopic state, but instead randomly samples all possible states, with probabilities given by the Boltzmann distribution.
Thermal fluctuations generally affect all the degrees of freedom of a system: There can be random vibrations (phonons), random rotations (rotons), random electronic excitations, and so forth.
Thermodynamic variables, such as pressure, temperature, or entropy, likewise undergo thermal fluctuations. For example, for a system that has an equilibrium pressure, the system pressure fluctuates to some extent about the equilibrium value.
Only the 'control variables' of statistical ensembles (such as N, V and E in the microcanonical ensemble) do not fluctuate.
Thermal fluctuations are a source of noise in many systems. The random forces that give rise to thermal fluctuations are a source of both diffusion and dissipation (includingdamping and viscosity). The competing effects of random drift and resistance to drift are related by the fluctuation-dissipation theorem. Thermal fluctuations play a major role inphase transitions and chemical kinetics.
the shaking of atoms as in a crystal would define the shaking of the lens openings of the above mentioned FREE ENERGY device as they displace through the openings, through the secondary openings and then into the light cast on the lower surface , as shaking in 3 directions.
Atomic diffusion on the surface of a crystal. The shaking of the atoms is an example of thermal fluctuations. Likewise, thermal fluctuations provide the energy necessary for the atoms to occasionally hop from one site to a neighboring one. For simplicity, the thermal fluctuations of the blue atoms are not shown.
the structure of the cardboard may be ,also , some flimsy matterial, that has lite weight value.
Here are some flimsy references;as their functions will be also shown.
Likely to bend or break under pressure; weak, shaky, flexible, or fragile.
from Wikipedia
date, 19,08,2016
time, 12:09
bend energy=
Elastic energy is the potential mechanical energy stored in the configuration of a material or physical system as work is performed to distort its volume or shape.[citation needed]Elastic energy occurs when objects are compressed and stretched, or generally deformed in any manner. Elasticity theory primarily develops formalisms for the mechanics of solid bodies and materials.[1] (Note however, the work done by a stretched rubber band is not an example of elastic energy. It is an example of entropic elasticity.) The elastic potential energy equation is used in calculations of positions of mechanical equilibrium.
break energy=
Dynamic braking is the use of the electric traction motors of a vehicle as generators when slowing. It is termed rheostatic if the generated electrical power is dissipated as heat in brake grid resistors, and regenerative if the power is returned to the supply line. Dynamic braking lowers the wear of friction-based braking components, and additionally regeneration reduces energy consumption.
pressure energy=
In fluid dynamics, Bernoulli's principle states that an increase in the speed of a fluid occurs simultaneously with a decrease in pressureor a decrease in the fluid's potential energy.[1][2] The principle is named after Daniel Bernoulli who published it in his book Hydrodynamicain 1738.[3]
Bernoulli's principle can be applied to various types of fluid flow, resulting in various forms of Bernoulli's equation; there are different forms of Bernoulli's equation for different types of flow. The simple form of Bernoulli's equation is valid for incompressible flows (e.g. mostliquid flows and gases moving at low Mach number). More advanced forms may be applied to compressible flows at higher Mach numbers(see the derivations of the Bernoulli equation).
weak energy=
In particle physics, the weak interaction, the weak force or weak nuclear force, is one of the four known fundamental interactions of nature, alongside the strong interaction, electromagnetism, and gravitation. The weak interaction is responsible for radioactive decay, which plays an essential role in nuclear fission. The theory of the weak interaction is sometimes called quantum flavordynamics (QFD), in analogy with the terms QCD and QED, but the term is rarely used because the weak force is best understood in terms of electro-weak theory (EWT).[1]
shaky energy=as related to the film surface with the hole in it for the animation of the function to generate free energy.
Handheld camera,[1] shaky cam,[2] queasy cam,[3] queasicam, hand-held camera or free camera[4] is a cinematographic technique where stable-image techniques are purposely dispensed with. The camera is held in the hand, or given the appearance of being hand-held, and in many cases shots are limited to what one photographer could have accomplished with one camera. Shaky cam is often employed to give a film sequence an ad hoc, electronic news-gathering, or documentary film feel. It suggests unprepared, unrehearsed filming of reality, and can provide a sense of dynamics, immersion, instability or nervousness.[4] The technique can be used to give a pseudo-documentary or cinéma vérité appearance to a film.[5]
flexible energy=
Variable renewable energy (VRE) is a renewable energy source that is non-dispatchable due to its fluctuating nature, like wind powerand solar power, as opposed to a controllable renewable energy source such as hydroelectricity, or biomass, or a relatively constant source such as geothermal power or run-of-the-river hydroelectricity. Skeptics of wind and solar power warn of their variable output, but many studies have shown that the grid can cope, and it is doing so in Denmark, Germany, and Spain.
from Wikipedia
date 19,08,2016
time, 12:12
fragile energy=
In glass physics, fragility characterizes how rapidly the dynamics of a material slow down as it is cooled toward the glass transition: materials with a higher fragility have a relatively narrow glass transition temperature range, while those with low fragility have a relatively broad glass transition temperature range. Physically, fragility may be related to the presence of dynamical heterogeneity in glasses, as well as to the breakdown of the usual Stokes-Einstein relationship between viscosity and diffusion.
Here are some more inventions from me.
free to try to build it with paper cardboard, and wire and a circular mirror .
from the concept of FUSED HORIZONS by the 17 th century king, Leszczynski (Poland) and his SON IN LAW "the SUn king " as the inspiration for the SOLAR usage , as the inspiration for the universal type minimal need to make a concept that defines the
flimsy type light weight use of paper where the universal expression may let you translate any shape you want for the holes.
The holes in the section 2 are parallel to the main disc that lets the light in (the higher holes).
The use of metal FOIL for the discs may also be used together with magnetic input into the wire.
the structure of the cardboard may be ,also , some flimsy matterial, that has lite weight value.
Here are some flimsy references;as their functions will be also shown.
Likely to bend or break under pressure; weak, shaky, flexible, or fragile.
from Wikipedia
date, 19,08,2016
time, 12:09
bend energy=
Elastic energy is the potential mechanical energy stored in the configuration of a material or physical system as work is performed to distort its volume or shape.[citation needed]Elastic energy occurs when objects are compressed and stretched, or generally deformed in any manner. Elasticity theory primarily develops formalisms for the mechanics of solid bodies and materials.[1] (Note however, the work done by a stretched rubber band is not an example of elastic energy. It is an example of entropic elasticity.) The elastic potential energy equation is used in calculations of positions of mechanical equilibrium.
break energy=
Dynamic braking is the use of the electric traction motors of a vehicle as generators when slowing. It is termed rheostatic if the generated electrical power is dissipated as heat in brake grid resistors, and regenerative if the power is returned to the supply line. Dynamic braking lowers the wear of friction-based braking components, and additionally regeneration reduces energy consumption.
pressure energy=
In fluid dynamics, Bernoulli's principle states that an increase in the speed of a fluid occurs simultaneously with a decrease in pressureor a decrease in the fluid's potential energy.[1][2] The principle is named after Daniel Bernoulli who published it in his book Hydrodynamicain 1738.[3]
Bernoulli's principle can be applied to various types of fluid flow, resulting in various forms of Bernoulli's equation; there are different forms of Bernoulli's equation for different types of flow. The simple form of Bernoulli's equation is valid for incompressible flows (e.g. mostliquid flows and gases moving at low Mach number). More advanced forms may be applied to compressible flows at higher Mach numbers(see the derivations of the Bernoulli equation).
weak energy=
In particle physics, the weak interaction, the weak force or weak nuclear force, is one of the four known fundamental interactions of nature, alongside the strong interaction, electromagnetism, and gravitation. The weak interaction is responsible for radioactive decay, which plays an essential role in nuclear fission. The theory of the weak interaction is sometimes called quantum flavordynamics (QFD), in analogy with the terms QCD and QED, but the term is rarely used because the weak force is best understood in terms of electro-weak theory (EWT).[1]
shaky energy=as related to the film surface with the hole in it for the animation of the function to generate free energy.
Handheld camera,[1] shaky cam,[2] queasy cam,[3] queasicam, hand-held camera or free camera[4] is a cinematographic technique where stable-image techniques are purposely dispensed with. The camera is held in the hand, or given the appearance of being hand-held, and in many cases shots are limited to what one photographer could have accomplished with one camera. Shaky cam is often employed to give a film sequence an ad hoc, electronic news-gathering, or documentary film feel. It suggests unprepared, unrehearsed filming of reality, and can provide a sense of dynamics, immersion, instability or nervousness.[4] The technique can be used to give a pseudo-documentary or cinéma vérité appearance to a film.[5]
flexible energy=
Variable renewable energy (VRE) is a renewable energy source that is non-dispatchable due to its fluctuating nature, like wind powerand solar power, as opposed to a controllable renewable energy source such as hydroelectricity, or biomass, or a relatively constant source such as geothermal power or run-of-the-river hydroelectricity. Skeptics of wind and solar power warn of their variable output, but many studies have shown that the grid can cope, and it is doing so in Denmark, Germany, and Spain.
from Wikipedia
date 19,08,2016
time, 12:12
fragile energy=
In glass physics, fragility characterizes how rapidly the dynamics of a material slow down as it is cooled toward the glass transition: materials with a higher fragility have a relatively narrow glass transition temperature range, while those with low fragility have a relatively broad glass transition temperature range. Physically, fragility may be related to the presence of dynamical heterogeneity in glasses, as well as to the breakdown of the usual Stokes-Einstein relationship between viscosity and diffusion.
Here are some more inventions from me.
free to try to build it with paper cardboard, and wire and a circular mirror .
from the concept of FUSED HORIZONS by the 17 th century king, Leszczynski (Poland) and his SON IN LAW "the SUn king " as the inspiration for the SOLAR usage , as the inspiration for the universal type minimal need to make a concept that defines the
flimsy type light weight use of paper where the universal expression may let you translate any shape you want for the holes.
The holes in the section 2 are parallel to the main disc that lets the light in (the higher holes).
The use of metal FOIL for the discs may also be used together with magnetic input into the wire.
As im thinking I'm not ready to give this concept up. There are some clues long the way.
That the Rutherford glass sphere and the vacuum inside it would discharge blue electricity when the hand touches it, may indicate that LIGHT could touch the same way the hand does. So that in place of the hand "the light makes contact" and the double slit could be used as the filtration of the light so that it displaces through the disc nr 2 in the above experiment and it's double slits inside the glass sphere where the vacuum exists and the probability that the light would continue through the 2 double slits and make a light impression on the other side of the spherical surface.
from
Physics.stackexchange.com
date , 19,08,2016
time, 14:00
3down votefavoriteI'm reading on the history of the discovery of electricity and the electron, and I've went from reading about Rutherford's gold leaf experiment all the way back to Francis Hauksbee's spinning glass machine.
Hauksbee was essentially the first person to preform scientific study on the effects of electrostatics in vacuum. He observed that when spinning a glass orb evacuated of air (vacuum inside the orb) and while placing his hand on the spinning orb, a charge was created such that blueish glow was seen inside the orb, where his hands were placed, and on the opposite side of the orb.
That the Rutherford glass sphere and the vacuum inside it would discharge blue electricity when the hand touches it, may indicate that LIGHT could touch the same way the hand does. So that in place of the hand "the light makes contact" and the double slit could be used as the filtration of the light so that it displaces through the disc nr 2 in the above experiment and it's double slits inside the glass sphere where the vacuum exists and the probability that the light would continue through the 2 double slits and make a light impression on the other side of the spherical surface.
from
Physics.stackexchange.com
date , 19,08,2016
time, 14:00
3down votefavoriteI'm reading on the history of the discovery of electricity and the electron, and I've went from reading about Rutherford's gold leaf experiment all the way back to Francis Hauksbee's spinning glass machine.
Hauksbee was essentially the first person to preform scientific study on the effects of electrostatics in vacuum. He observed that when spinning a glass orb evacuated of air (vacuum inside the orb) and while placing his hand on the spinning orb, a charge was created such that blueish glow was seen inside the orb, where his hands were placed, and on the opposite side of the orb.
down voteI have a guess, although I don't know if it is correct.
If you model the globe as a simple insulating circular glass shell with a constant spatial charge density embedded in the glass in the immediate vicinity of the finger and solve Maxwell's equations numerically for the potential, you observe something like this:
The rationale for placing a nontrivial static charge density in the vicinity of the finger in contact with the spinning globe is simply because glass, the so-called "vitreous" static source, dislodges surface charges during mechanical abrasion, and the charges have nowhere to go, since glass is mostly nonconducting.
As you can see, on the inside and outside of the glass in the immediate vicinity of the finger, there is a potential gradient. As such, dielectric breakdown becomes a possibility. By Paschen's Law, dielectric breakdown is orders of magnitude more likely in the partially-evacuated interior of the globe; as such, surface charge in the vicinity of the finger on the interior of the globe are accelerated through the vacuum and redistribute themselves on the lower-potential walls of the globe farther away from the finger. The electron collisions with nitrogen and other rarefied molecules in the vicinity of this transient current generate the blue glow near the finger.
Since the globe is spinning and the finger continually moves across the globe, there is no need to worry about a net nonphysical change in the interior surface charge density during each traversal of the loop, since they are constantly being "spatially recycled" during the spinning cycle.
For this reason, I am willing to bet that a similar experiment conducted with a finger rubbing the same spot on an evacuated glass bulb will NOT produce a continual glow discharge in the vicinity of the finger, despite the mechanical similarity of the processes.
Finally, assuming my mechanism is correct, there should be no visible glow discharge if the glass bulb is near-perfectly evacuated. Vacuum techniques in Hauksbee's time were, of course, far from this degree of rarefaction.
I continued to work on it. Here then the way that the static may cycle back on itself by using slit openings on either side so that the first static touch would continue to discharge some energy of free energy when placed among vegetation in nature so that the bio energy would sustain the energy flow back into nature as a cycle of free energy.
from Wikipedia
date ,19,08,2016
time 15:34
Static electricity is an imbalance of electric charges within or on the surface of a material. The charge remains until it is able to move away by means of an electric current or electrical discharge. Static electricity is named in contrast with current electricity, which flows through wires or other conductors and transmits energy.[1]
A static electric charge can be created whenever two surfaces contact and separate, and at least one of the surfaces has a high resistance to electric current (and is therefore an electrical insulator). The effects of static electricity are familiar to most people because people can feel, hear, and even see the spark as the excess charge is neutralized when brought close to a large electrical conductor (for example, a path to ground), or a region with an excess charge of the opposite polarity (positive or negative). The familiar phenomenon of a static shock–more specifically, an electrostatic discharge–is caused by the neutralization of charge.
as such the double slit experiment for static and the human touch that links the static ionic energy could be made on the reference to a double slit experiment but one that is an alternate type of the usual Faraday's double slit.