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Saturday, October 17, 2015

Stonehenge and the Full Moon

In our modern age, we tell time largely by the passage of the sun and the solar day and that means that the sun and not the moon largely determines our modern time. However, people have always used the moon as a way to tell time along with the sun and the legacy of lunar time persists in the calendar month as one cycle of the moon and week as a moon quarter. As a result, lunar time is still deeply embedded into the consciousness of humanity along with solar time. 

Stonehenge is an ancient solar and lunar calendar in Wiltshire, England, that is an arrangement of stones called henges and holes for wooden henges that tell both solar and lunar times. Constructed around 2,600 BCE (over 4,600 years ago) and used for over 1,000 years, the main alignment of Stonehenge shows the directions of the summer and winter solstices as well as spring and autumn equinoxes as shown in the figure below. This alignment with the solstices tells a solar time of year by the sunrise and sunsets of solstices and equinoxes at right angles to the solstices, the four solar celebrations of the ancient Druids.

Stonehenge also tells lunar time with an inner circle of 30 Sarsen stone henges that represent the 29-30 days of the lunar period along with an outer circle of 56 Aubrey pits (wooden henges) that count moon periods and lunar years. Since there are 14 moons for each lunar year, the Aubrey circle counts 4 lunar years with its 56 pits. There are also 7 lunar years for every 8 solar years for the winter/summer solstices of the Stonehenge calendar and that product shows 7 x 8 = 56 lunar solar yrs.

The 56 Aubrey pits allowed Stonehenge to count both the 4 solar celebrations of solstices and equinoxes along with the four interspersed lunar celebrations for 14 solar years and 4 lunar years. The Stonehenge calendar included one lunar celebration as one of the full moons between each pair of solar celebration for a total 8 celebrations that are the same in the modern Druid wheel of 8. Today's modern holidays reflect the 8 celebrations from the ancients.

In principle, there are three full moons on average between each solar celebration, but since the full moon period shifts as much as one moon relative to the solar month, it is important to sometimes choose the first full moon and sometimes the second full moon. That meant that the lunar celebrations would better synchronize with the solar celebrations.
In addition to being a solar calendar of the 4 solar celebrations of solstices and equinoxes, Stonehenge also counted days in a moon period as well as moons in a lunar year in order to intercalate four lunar celebrations. A lunar calendar counts the 14 moons for each lunar year, which means 4 lunar years in the 56 Aubrey holes along with 14 solar years by counting 4 solar celebrations. Solar solstices and equinoxes along with full moons have all traditionally marked Druid ceremonies and that tradition continues today for many modern holidays. From the Chinese New Year’s to Easter and Yom Kippur, the cycles of the moon therefore continue to impact human behavior. Even today, knowledge of the full moon is further helpful for harvesting and hunting and other outdoor activities as well as prediction of the ocean tide.

Many people have proposed that the Stonehenge calendar also predicts solar and lunar eclipses. While it is certainly possible to use a Stonehenge solar-lunar calendar to predict lunar and solar eclipses, eclipse predictions need further knowledge of a third cycle, the Saros 18 yr cycle, and discerning the Saros cycle necessitates centuries of fairly accurate astronomical observations. The day of solar and lunar eclipses repeat every Saros cycle of 18 years and this period predicts both lunar and solar eclipses. During each 18 year Saros cycle, there are about 40 eclipses and so the Saros cycle requires not only a fairly accurate calendar, it requires several centuries of careful observation with reasonably clear skies.

It is not clear that the knowledge of the Saros cycle of eclipses was available to the ancients of Stonehenge and the less than optimum visibility of the sunrise, sunsets, moonrise, and moonsets in that climate would suggest that eclipse predictions would have been very unlikely. Since predicting the time of year and phase of the moon did offer distinct survival advantages, Stonehenge makes perfect sense as both a solar and lunar calendar. However, the precision of the Stonehenge calendar does not seem consistent with the long-term observations needed for eclipse predictions.

Humanity today adjusts our modern calendar month to the rhythm of the solar day and year and we have therefore lost much of the ancient lunar rhythms that tell time with the variable periods of the full moon. A solar calendar month averages 30.4 days each over a non-leap 365 day year, whereas the actual lunar month is 29.53 days for an average full moon period. And yet the periods of the full moon still affect things that happen to humanity. For example, the average female menstrual period is 29.1 days and is closer to the 29.5 days of the average full moon than to the 30.4 days of our average calendar month. In fact, the average gravity period of the lunar orbit is 27.6 days, which is also an important cycle for the changes of full moon periods.

There is a cyclic variation of the period of the full moon due to the coupling of both lunar and solar periods and it is that variation of the full moon period that affects the tides and weather patterns associated with those tidal flows. So the full moon period does have demonstrable affects on human behavior and there is a long history that associates phases of the moon with various behaviors. The word lunacy, after all, comes from the lunar root and the poetry and behavior of people has long association with the lunar phase.

The cycles of lunar full moon period or number of days, though, do not have the same popular following as does following the phases of the moon. The cycles of the lunar period are mainly due to a beating of the period of the full moon, 29.53 days, with the period of the gravity moon orbit, 27.55 days. These two lunar periods result in two beat cycles of 1.13 and 8.85 yrs and that means that there are roughly seven lunar years as cycles of moon periods for every eight solar years. This means that there are 56 moons in 4 lunar years along with 14 solar years with 4 solstices/equinoxes to make the 56 solar celebrations in 14 solar years. There are also 4 lunar celebrations to make up the 8 celebrations of each Druid year.

The Chinese lunar calendar is several thousand years old and places the winter solstice in the eleventh lunar month, which means the New Year is usually the second new moon after the winter solstice. The Christian Easter is the Sunday following the first full moon after the spring equinox, but as determined by the ancient Nicene and not a modern calendar. There are many other religious holidays that remain anchored to the full moon period and so continue to affect human behavior.

The fractional periods of the moon relative to the solar periods make moon predictions difficult. Lunar calendars are always therefore more complex than solar calendars and this was true for ancient peoples of the Stonehenge. Knowledge of the Saros eclipse period of 18.03 years predicts both lunar and solar eclipses, traditional harbingers of fortune, but the Saros period takes many years of observation. The Saros period comes from the moon period between when it crosses the sun's path, which is 27.2 days. This lunar cycle beats at 18.6 yrs and 18 yrs is the intersection of the three lunar periods.

The variability of the period of the full moon is quite well known and largely due to the beating of the full moon period of 29.53 days with the period of the lunar gravity orbit of 27.55 days. The beating of these two frequencies results in a variation of full moon periods with cycles of both 1.13 and 8.85 years as shown in the figure. The precise measurement of the earth-moon distance with a reflected laser pulse has shown that the earth-moon distance increases by 38 mm per year. Given the 384,400 km average earth-moon distance, 38 mm/yr means that the moon orbit period slows by 0.31 ppb/yr, very close to the expected 0.26 ppb/yr of classical aethertime decay, but far less than the variability due to other factors.

This figure shows the period of full moons as a function of fractional solstice year where each year begins on the winter solstice, Dec. 20th. The coincidence of the winter solstice with a peak in the full moon period occurs every 8 solar years, but only seven lunar years. This fundamental difference between solar and lunar periods is what the stone and wooden henges seems to represent.



Sunday, October 4, 2015

Quantum Aether Entanglement and Phase Coherence

Phase coherence is a property of quantum sources that classical sources do not seem to have, but in fact phase coherence affects all observers and sources in the universe, just in different ways. Instead of the single knowable state of a classical source, say a red color, two quantum sources with coherent phase can exist in a coherent superposition of states, say both red and blue. This entanglement can occur even though those the quantum sources might be located across the universe from each other.

The exact object color of one source is unknowable until an observer sees that source as red or blue. The observation of one of two coherent source superposition states as red then immediately determines the other source state as blue even across the universe. Before the measurement, though, the two sources existed as a superposition of both red and blue and so the exact state of both sources in the past is unknowable.

There is a knowable phase coherence that two classical objects also exhibit, but for classical objects in general relativity, all reality is determinate and therefore classical coherent states are knowable. A classical observer might not know which of two a classical sources is red or blue, but that classical knowledge is always knowable. That is, once an observer sees one classical source as red, they also immediately know that the other classical source is blue even if the other classical source lies across the universe. However, the colors for each of the two classical sources were always classically knowable and once an observer sees a classical source as red, they know that it was always red. There are no superposition states for classical sources nor is there any decay of the phase coherence between two classical sources except due to perturbations from other sources.

Classical determinate sources in general relativity do not appear to show quantum phase coherence, but really it is the decoherence of quantum phase that makes quantum sources different from classical sources, not really phase coherence per se. After all, two classical sources with coherent colors also remain perfectly coherent in a determinate classical universe in the absence of perturbations. Those two coherent colors represent determinate geodesic paths for general relativity as well.

On the one hand, correlated colors for two classical sources represent something that an observer can know about each source. Even though the observer might not know the color of either source to begin with, once seeing that a classical object is red, the classical observer also then immediately knows that classical sources was always red. The observer also then immediately knows that the source's coherent twin's color was blue even across the universe and that twin had its classical correlation for the same period of time.

Unlike two classical sources, two coherent quantum sources somehow oscillate between those coherent color states as a superposition of amplitudes and do not exist as either one or the other colors until an observation or some other action dephases them. In the quantum universe, dephasing is an inextricable part of seeing or measuring the color of a quantum source and immediately tells the observer the state of its coherent twin even across the universe. Since decoherence is an inextricable part of all sources in the universe, observers can never be absolutely certain about the natures of objects that they sense. That is because neither quantum twin existed as red nor blue prior to the measurement or action that dephased one of the sources into a red or blue state.

The mystery of quantum entanglement has to do not really with why a quantum source can be either of two colors or how two quantum sources can remain coherent with each other across time and space. The mystery of quantum entanglement has to do with even when an observer sees that an source is red, they still simply cannot know that that same source was always red before they observed it. As soon as the nearby quantum object is red for certain, the distant source decoheres to blue and stops its oscillation between red and blue. The distant quantum source can now only be blue even though before that time, it's state was not knowable.

Although quantum charge is a local force with very fast decoherence, quantum gravity is a long range force that has a much slower decoherence. In aethertime, every quantum charge state like red and blue with very fast decoherence has a complementary quantum gravity state with much slower decoherence. In fact, quantum gravity states exist with the decoherence times of the universe. While quantum charge is a very local force, quantum phase is also part of the glue that holds the universe together.

The color of a red source is due to a large number of photons of light across a wide spectrum of light around that red color. When we see a classical source as red, we sense only a very small fraction of a very large number of photons emanating from that red source. For such large and macroscopic classical sources as red apples, a red color is a property of a very large number of particles at the surface of that source.

In contrast to the color of a classical source, the color of a quantum source may be due to just one photon of light interacting with a single particle. Since observer eyes are not sensitive to just one photon, observers must use spectrometers to know whether a single particle is red or blue. That single photon still represents a whole spectrum of frequencies superimposed as a single time pulse that bonds the observer to the particle for some period of decoherence. During that superposition between the observer and the particle, the observer oscillates along with the particle between the possible futures of red or blue. When the observer becomes decoherent from the particle, that leaves the observer in the red or blue state as well as the quantum gravity state that goes along with the color.

The phase coherence of a quantum source decays as a result of not only measurement, but also due to perturbations with other objects just like perturbations affect the classical spins of objects. The decay of phase coherence is due to the classical noise of chaos as well as quantum phase noise and there is simply no classical meaning for quantum phase noise.

The meandering decay of earth's spin period means that a day has varied from +1.4 to -1.5 ms every year over the last 43 years (see figure below) and there are many different factors that perturb Earth's spin by as much as 4 ms per day. In a determinate classical universe, all of these perturbations are knowable and even in a quantum universe, most of these perturbations are likewise knowable. However the quantum dephasing of the universe at 0.255 ppb/yr has no cause other than being simply a property of the universe. Quantum decoherence is an assumption Earth's spin decay that is an unconditioned axiom of the universe.

According to reports, the Earth day has lost from 1.7 ms [0.20 ppb/yr, McCarthy and Seidelmann, 2009] to 2.4 ms [0.28 ppb/yr, Stephenson and Morrison, 1984] over the last 100 years, both decays are consistent with the classical 0.26 ppb/yr decoherence of aethertime within the uncertainty of the measurements. The dephasing of the universe represents phase information that is lost to observers of that same universe since observers dephase along with all other sources in the universe. However, the local decoherence rate does show up in various decays of matter and force and those measurements do provide an absolute velocity relative to the aethertime universe boundary. The shrinking of the universe in this epoch is what defines the speed of light, c, in aethertime.

Therefore, quantum entanglement and decoherence both represent a loss of information as quantum phase noise and so observers cannot know all quantum phase perturbations. While classical entanglement represents knowable perturbations with a determinate universe of local cause and effect, quantum entanglement also involves decoherence of quantum phase commensurate with the universe decay.

Wednesday, September 2, 2015

Sources as Matter Waves in Our Spectral Reality

A source exists in two complementary representations; as an objective pulse of matter in time and as a subjective matter spectrum at a given moment. A source is a superposition of simpler sources and past matter actions that have all accreted smaller sources into a present moment and the present moment is therefore a superposition of those past actions. That superposition in time represents an objective Cartesian particle reality and corresponds to the material reality that we imagine exists outside of our minds.

However, the superposition in a matter spectrum represents how the source relates to the rest of the universe and to that source's many possible futures. A matter spectrum of wave-like phase and amplitude represents a source as a superposition of possible futures. That matter spectrum represents a relational wave-like reality and corresponds to the immaterial or ideal reality that we imagine exists within our minds. Consciousness is a matter spectrometer that measures the properties of an source at a given moment. Although a matter spectrum represents a source's fixed past, the evolution of that matter spectrum includes many possible futures and is not fixed.

The present moment of an source is both the known or at least knowable Cartesian representation along with the uncertainty of its relations with other sources. A Cartesian source comprises a knowable fossil record of its past matter spectrum while a relational source comprises the uncertainty of the many possible futures of what that source might become. All that we know about a source in the present moment, though, is its matter spectrum or color and one particular color is time delay.

A Cartesian source is made up of fossil matter moments in the present moment with only the actions of a chaotic past where that the source came into existence as in the above figure. A relational source is a superposition of all of its possible futures as a matter spectrum and there are many possible futures that equally well and uniquely describe each source. Even though a source will only ever realize one particular future, the totality of all of the source's other possible futures completely describes that source just as the superposition of its past actions also completely describe the source.

Each source is then equivalent to a superposition of matter wave amplitudes and phases over all time and when those matter waves constructively interfere, an source exists. When an source's matter waves all have a common phase and coherence, that property is the time delay of that source from an observer. Each source also exists in a present moment as a superposition of its possible futures, which are the many matter spectra that include source relations with the entire universe at the present moment. Matter waves will have different phases or possibilities that appear in more than one possible location in space from a source, but matter waves are tied to a common time delay from a source. An observer says that a source exists when they observe it in one place in space as a clump of mass or intensity with one common time delay. But before a source exists at that one time delay as intensity, it may have had coherent amplitudes and therefore other possible futures in more than one location.

Once an observer experiences a source's actual future as the present, all of its other possible futures then decay away. However, all of the other possible futures do not instantaneously dissipate and rather the other futures decay over finite times. The present moment is then a superposition of possible futures and a source can therefore exist in many states during some very short dephasing time.

Matter waves represent all of a source's possible futures and the possibilities of a source all exist before the realization of an source in just one place with just one phase and that one future becomes the present moment. Interactions with other sources in the past localize or dephase most sources that we experience, but there are some sources that continue to exist as superpositions of coherent phase and only localize or dephase when we personally experience or dephase them ourselves. Such matter waves comprise the time moments of a source and with its time moments frozen in the past, sources that we observe in the present have all existed as matter wave superpositions sometime in the past as well.

Observers are also sources and they are bound into a universe of matter and action. Observers exchange matter as waves of amplitude and phase with sources and that matter exchange binds observers to those other sources. What observers sense about a source comes from the light, sound, touch, taste, and smell of that source and from these subjective sensations observers imagine a Cartesian source in one location with one phase. This would be philosophy's source in and of itself, our objective reality, but what we call objective reality is just one of the many possible futures for spectral sources.

We can share and agree with others about measurements of sources with various instruments and techniques that discover all kinds of properties of objective reality, which essentially are the matter spectra of an source. Mass, time, spatial displacement, porosity, color, temperature, etc., are all properties that observers measure and those measurements form an objective reality for each source as a superposition of its matter spectra. Other observers can perform the same measurements and pretty much agree on the same objective properties of a source , its qualia, within some uncertainty. We further imagine that we exchange light and matter with all sources and that exchange is actually how we relate physically to the sources we imagine.

Instead of just our sensations, which are ours alone, we can also agree with other observers about the objective properties of a source, properties that we actually only know subjectively. Thus we imagine sources exist in the Cartesian space outside of our mind and yet we know that we only sense some very few of the many possible futures of those sources by exchange of matter and light and we are just part of one of those possible futures. What we sense are the time delays of a source along with any changes in time delays or matter.

We do not sense matter wave amplitude or phase, rather we sense matter wave intensity, which is the product of the matter wave amplitudes and typically no longer entangles phase coherence. Moreover, each sensation or measurement only represents a limited number of the total possible futures for the source's matter spectrum. While a matter wave that we sense only represents one possibility for an source, we still imagine a complete reality for that source despite the limitations of sensation.

However, we can infer what a single matter wave is like by repeated measurements of a portion of a coherent superposition of identical matter waves. If we were inside of a low frequency but high intensity superposition of coherent photons, we can know what the photon matter wave is like by repeated sampling of its identical superimposed photons. When we sense a potential as voltage, we absorb a small number of photons of the energy of that superposition and infer the nature of the rest of the superposition as a source. When we sense a photon at one Hz with an amplitude of one hundred thousand volts, the electric field that is a 100,000 volt amplitude polarizes in one direction, with plenty of sparks and charging, and later we feel no electric field, and then the electric field polarizes opposite with similar fireworks. So, have we sensed a photon wavefunction or just the collapse of a photon wavefunction?

Is the wavefunction of the photon real or just imaginary? The amplitude of a single photon at a frequency of 1 Hz is only 60e-9 volts, sixty billionths of a volt, and so there would be something like 6e13 coincident photons to make up the current of a 100,000 volt wavepacket. So we sense the details of this wavepacket by consuming some small fraction of its photons and presume that the rest of the wavepacket is made up of identical photons. Thus, we can actually measure the shape of a wavefunction by using scaling arguments and that makes it real.

The amplitude of earth's orbit is a gravity wave at 3.2e-8 Hz and that wave is a very small matter exchange. This gravity wave is the quadrupole photon pair whose exchange with the sun holds the earth to the sun and amounts to a matter wave exchange with the sun of 0.15 earth masses per year. While the earth and sun exchange a large number of dipole photons of lights, it is the excahnge of a very small fraction of quadrupole photon exchanges that we call gravity force.

As long as we can create a large number of coherent and identical photons, we can measure to arbitrary precision the form of the wavefunction for that photon using a scaling argument. It is in this sense that we can show that a wavefunction or matter wave exists as amplitude. Science uses imaginary numbers to help represent cyclic action of a matter wave since the real term represents an in-phase amplitude while the imaginary term represents an out-of-phase amplitude.

The nature of our quantum reality is a collection of oscillating matter waves and quantum action represents the in phase reality with real terms and the out of phase reality with imaginary terms. The real and imaginary terms simply represent the in and out of phase parts of reality that are both solutions to the Schrödinger equation. The reality of phase coherence for matter tends to confuse us because our sensation of a source, i.e. its mass, oscillates with periods that are far beyond sensation. We do sense many properties of light, however, that are due to its oscillation and so it seems like light and matter are very different sources when in fact light is just another manifestation of matter.


Any pair of gravity bodies can have superposition orbits at their Lagrange points, which are points in an orbit where forces are equal and opposite. Smaller sources on these Lagrange orbits A and B have two possible futures around either of the two large bodies like the earth and moon and such sources can then show coherence between orbits. Lagrange points appear to prepare matter into coherent gravitational states that show interference and exchange effects that quantum gravity generates.

Lost In Space was a 1960’s sitcom that was very popular and now lost in space is a metaphor for what is lacking with mainstream science’s approach to the cosmos. Einstein gave us two very important precepts that have greatly helped us to understand the nature of the universe, mass-energy equivalence and gravity delay of light. But Einstein's relativity also left science with a intractable determinism incommensurate with our quantum logic. Space and motion are simple incommensurate between relativity and quantum actions for the same source.

The foundation of general relativity is that energy is equivalent to matter as the mass-energy equivalence, E = mc2, or MEE. What MEE means is that source motion as kinetic energy in space is equivalent to an increase in the inertial mass of the source. Turning MEE around means that space and motion actually emerge from changes in the inertial mass of a source over time. So, a source’s action is then a result of a change in its mass and so mass-energy equivalence is not due to motion per se. Rather, motion and space are both the result of MEE and it is kinetic matter that represents kinetic energy and therefore motion in space emerges from kinetic matter. Correspondingly, space itself emerges from the different time delays that we sense for sources and their backgrounds. When the time delays do not change, the potential matter changes such as gravity represent potential energy from which emerges fields in space. While science normally imagines that fields exist a priori in an otherwise empty void of space, our notion of space actually emerges from the unchanging time delays among sources that represent all possible futures.

Mass-energy equivalence results in the dilation of time and with the Lorentz factor, spatial dilation emerges from MEE. Thus it is the very subtle changes in matter over time that describes all action and so motion in space is in some sense simply how we interpret the changes in time delays that we sense as the very subtle changes of matter in time that are action.

Continuous space and motion are two very important notions that represent reality very well. However, continuous space and motion are simply fundamentally incommensurate between gravity and quantum action. In order to fashion a nice quantum gravity, it is necessary to use the notions of discrete matter and time delay to make the quantum action of charge force consistent with a quantum gravity. This approach, called discrete matter and time delay, replaces the pivotal and intuitive role of continuous spatial displacement for action that is the basis of mainstream science. Action in matter time instead involves discrete exchanges of matter among sources over time and it is from those exchanges that the realities of space and motion emerge from how we imagine the cosmos. The simple axioms of matter and a two dimensional time are then consistent with the very powerful tools of quantum action to also define the realm of gravity action.

Gravity results in deflections as well as stable orbits of bodies in space, but gravity also compresses matter in sources and that compression heats the body. In stars, compression and heating results in quantum action of fusion of elements yielding large amounts of heat and light and neutrinos. Gravity compression is the increased bonding states between matter particles by the gravity action of other matter particles of a body. Gravity compression results in mass loss from the radiation of heat and a concomitant formation of potential matter in the compression of the bonds between electrons and protons.

It is somewhat ironic that it is the matter loss as the radiation of heat that leads to the nuclear bonds of fusion that then release even more heat and light and neutrinos. The heat generated by gravitational compression conducts to the surface of the body and radiates as light just as the heat of fusion also conducts to the surface and radiates, but that diffusion of heat can take tens of millions of years for a body like our sun. In other words, the heat of our sun today was the result of fusion that occurred tens of millions of years ago in the sun's center.

The radiation of photons into the universe as heat seems to be simply a byproduct of gravity compression of matter. Gravity compresses the matter of a body and that compression heats the body by pushing the electrons of atoms and molecules closer together. The nuclei of those atoms then move to the new minimum potential energy and that motion is the kinetic energy that we call heat. In reality, it is that radiation that causes gravity force compression, not the other way around. We can equally well imagine correlated pairs of quadrupole photons radiating from the surface of a body as causing the gravity action that compresses that body as vice versa. In other words, science tends to think of gravity action as heating a source by compression and the heat emitting from the surface as dipolar light. Even though this is largely true, it is also the action of photon quadrupole emission at the surface and the diffusion of heat to the surface that represents the bonding of potential matter that we think of as gravity action.

Charge force represents the bonding of electrons to nucleons and is due to the exchange of photons between electrons and nucleons. Each bonding photon in matter represents an exchange that has a complementary photon exchange that further bonds that matter to the universe as gravity force. Gravity force is the result of the bonding of the matter of the universe to both electrons and nucleons by the exchange of photons between the universe and the body. The basic decay of matter, mdot, is a dephasing decay of the universe boson matter that represents all force.

What this means is that the difference between a photon as a binding particle for quantum action and a photon as complementary binding particle for gravity action is in the ratio of electron to gaechron mass. A photon emitted to the universe creates a binding state with the universe that complements the photon bound state of charge force, which is a binding state of electron mass. This complementarity provides the logical connection between charge and gravity forces into the single unified theme of quantum action.

The time periods of quantum and gravity action are the two clocks that define our reality. While the atomic clock represents time as resonance of an electron-proton bond, the gravity clock of our cosmos ticks with the resonance of the billions of years of a universe pulse in time. Thus, the ratio of these two clock pulses represents the 1e39 difference between charge and gravity forces that bedevils science's imagination.

A two dimensional time represents the time of both our microscopic reality as well as the time of our macroscopic reality as the cosmos. While we live in what we call proper time, a time that is between atomic and cosmic times, each source action occurs with time as a dipole with both amplitude and phase and each pair of sources represent a time quadrupole and it is that time quadrupole that represents the time of both charge and gravity forces.



Monday, August 31, 2015

Quantum Aether Electromagnetism and Gravity

There are three related by still different descriptions for electromagnetism with the first being the through-space electric and magnetic fields of Maxwell equations at the top of the figure below. By far, the Maxwell equations are the most useful for predicting electromagnetism, but are limited for relativistic or quantum conditions. The second way to describe electromagnetism is with the four-vector potential of four-space of relativity, as the second figure, and the description helps define relativistic electromagnetism. For quantum conditions, a third description involves is a space filled with the virtual photons of quantum electrodynamics as the third figure shows. All three descriptions propagate electric and magnetic fields between objects and all three are useful in their limited realms.

However, none of these three explanations apply near or inside of the singularities of continuous space, motion, and time; black holes and event horizons. The event horizons of black holes, universe expansion, and the very small black hole that plagues continuous gravity at the center of every particle, all of these singularities have neither electromagnetic nor gravity according to mainstream science.

There is then a fourth explanation, aethertime, a discrete aether in time that can also be a quasi-continuum of aether in time. Instead of a photon being a fundamental virtual particle, a photon is a stationary aether excitation in a universe of decaying aether. It is all matter that is in motion relative to this photon rest state and that aether decay drives both charge and gravity actions.

Motion in continuous space involves the exchange of aether particles among objects while motion of charge involves the exchange of aether photons and photons carry both electric and magnetic fields. Thus it becomes quite straightforward to represent electromagnetic fields with aether exchange in the same way that virtual photon exchange with vacuum oscillators represent electromagnetic fields. However, instead of the infinity of vacuum oscillators that is QED, aethertime has a large but finite number of discrete aether.

Just as the principles of QED are not more useful than Maxwell’s equations for representing the vast majority of action in EM, aethertime likewise is not necessarily more useful than the three above tools. However, at the singularities of continuous space, motion, and time, the second dimension of time, aether decay time, keeps the clock running and the lights on. The event horizons of a black hole and the expanding universe both are transitions from fermion matter to boson aether. The only true event horizon in aethertime is where it belongs…defining the edge of the aethertime universe.

The tenets of aethertime represent the same reality as mainstream science for EM, quantum, and gravity. However, the notions of continuous space, motion, and time are limited by the event horizon singularities of mainstream science; very small scale, black holes, and the universe event horizon. Furthermore, the inner core of a neutron star also appears to have a boson singularity.


The CMB represents a very uniform light emission at 2.7 K from the creation of hydrogen and other light elements. In the shrinking aethertime universe, the CMB temperature is actually 0.64 K in its rest frame where the speed of light at the CMB is only 6% of c, the value in this epoch. The surface temperature of the CMB would then be related to the ionization energy of hydrogen in that epoch and a black hole today would therefore now be at the ionization energy of hydrogen, 13.6 eV or 158,000 K. At this temperature, the UV emission from hydrogen is called the Lyman series and the Lyman alpha band is a prominent feature of many active galactic nuclei with z > 2.

In fact, very large Lyman alpha blobs of hydrogen gas in the very early universe seem to be associated with new galaxy formation with a particularly large LAB called Himiko appearing at z = 6.6. The recent report of a galaxy at z = 8.7, EGS8p7, that shows Lyman alpha emission is further consistent with the very early formation of galaxies around black holes.

Saturday, August 22, 2015

Spacetime Emerges from Quantum Aether

The two bubbles of spacetime quantum and general relativity with their conjugates of momentum and position exist within the aethertime universe as shown in the figure below. Aethertime unifies charge and gravity as time-scaled versions of the same aether decay and so a shrinking aethertime universe is what unifies quantum charge and general relativity's gravity forces. Unification has eluded many very smart people for nearly a century, but aethertime unifies charge and gravity forces with the same time scaling that also unifies an antimatter antiverse with our matter universe into a the growth and decay of a single aether pulse in time. As a result, aether decay shows that it is the disparate notions of spacetime itself that precludes unification with a pernicious elusiveness that even very smart people simply have not yet been able to figure out. That does not mean that I am smarter than everyone else, just luckier...and grateful for the many very precise measurements of objects and time that show aether decay.
Einstein's general relativity (GR) describes motion with a continuous gravity force that moves objects along determinate paths called geodesics in the void of empty and continuous space and time. The green ellipse in the figure shows the predictions of GR. In contrast, quantum theory as the red ellipse moves objects with discrete expectation values of momentum and position with charge force mediated by photon exchange. Quantum excitations result in motion along uncertain paths in that same space, which is now full of vacuum oscillators, that space where gravity motion involves determinate paths.

While the continuous spin of the earth tells a continuous gravity time with discrete aether decay, the discrete ticks of atomic clocks and the discrete spin of atomic matter tell a much more precise quantum time. Since there is not a quantum expectation value for time, quantum time is discrete and fully reversible even while gravity leads to a determinate and continuous expanding universe with a continuous gravity time.

In GR, space, motion, and time all become undefined at the event horizons of large matter accretions known as black holes and just beyond the CMB as well as at very small scale, the Planck scale. Spacetime has recognized these limitations for many years, but spacetime still does not show any other way to predict the futures of objects without continuous space, motion, and time. The very definition of space is odd since space is a void of nothing that we cannot sense in a continuum of time and space. Spacetime only assumes that space exists because all of the objects moving around need space as a way to be different from each other and so it is our sensations of objects that inform us about space.

The evidence that spacetime has for the nothing of empty space depends, then, on objects not changing and being constant. Objects may move from one place to another in spacetime and emit or absorb energy and mass, but total object mass and energy must always conserved in any action in empty space. Of course, if an object loses mass by emission, the motion of that mass involves kinetic energy, which increases the mass relative to the rest frame and so the accounting of constant relativistic mass must be done very carefully.

Both charge and gravity forces act through space, but while photons mediate charge force, gravity force simply cannot have a carrier particle since gravity is by its very nature continuous in a continuous space and time. Since there is only one time dimension in GR, atomic time, the continuum of gravity force means that space and time become undefined in the universe at both very small and very large mass accretions, including at beyond the CMB, which is now at 0.9991c. Once the CMB transitions to 1.0c, it will move beyond the event horizon of spacetime, which seems like a really unlikely universe.

Aethertime is an alternative way to keep track of objects with discrete aether and time delay and as a bonus, aether decay becomes the genesis of all force. Discrete aether, matter exchange, and time delay represent a more general aethertime reality that augments and wraps around spacetime's more limited continuous space, motion, and time and so aethertime does not suffer from the same limitations of spacetime. Aethertime predicts motion with discrete aether exchanges in a fully quantum action and discrete time delays for even very large and very small objects, and now aethertime augments the limitations of the continuous motion of continuous space and time with a complete universe.

Instead of predicting motion with fields of force in the vacuum of space, aethertime predicts motion with matter exchange and aether decay. The decay of discrete aether is now an inherent property of aethertime from which emerge the fields of force that are inherent properties of continuous space, motion, and time. Unlike the nothing of empty space which we never by definition measure or sense, there is plenty of evidence for discrete aether decay in the many measurements of object mass decays that show the same very slow decay over time, 0.26 ppb/yr. These measurements include the IPK primary mass standard, the earth spin, the earth-moon orbital period, milky-way to Andromeda time delay, and the average decay of several thousand neutron stars as millisecond pulsars.

While objects in spacetime appear to have constant mass over atomic time, all objects in aethertime decay along with the rest of the universe over the very long time scales of aethertime. And of course, the natures of both charge and gravity forces derive from the same decay of aether, which appears to act through space. However, aether does not exist in space and so space has zero density, but aether decay does result in a pressure for space. A pressure for space with zero density is equivalent to an incompressible aether.

The period of atomic time also decays over aether time as do c, h, and α, which really changes how we interpret the distant objects of deep space including the decays of millisecond pulsar neutron stars and the red shifts of distant galaxies. The decay of discrete aether mediates both charge and gravity forces in aether time, which for charge is by exchange of the dipolar photon while for gravity is by the exchange of mono/quadrupole photon pairs scaled by the time size of the universe. Therefore, charge and gravity forces are both mediated by the same aether exchange and decay with the scaling of the universe time size. In addition to atomic time, there is a second time dimension, aether time, and discrete aether and time now predict action for all of universe, including both very small and very large mass accretions.

Unlike the lonely void of empty space, objects are never alone in a universe of discrete aether. We exist as part of the discrete aether whose exchange connects us with all other objects. Discrete ether has both mass and spin and is the basic building block and aether decay is the binding force of the entire universe, not just for observable particles. Our notion of two particles in relative motion in continuous space emerges from the discrete aether exchange between those particles and their time delays. While neither atomic time nor continuous space have meaning at the event horizon of a black hole, aether time represents an event horizon as simply a transition from fermion matter and atomic time to discrete boson matter and time delay.

Sunday, August 9, 2015

Quantumology

Quantumology is the belief that quantum action describes all force and that gravity is a discrete quantum force. Quantumology necessarily begins with some kind of universal particle, like a discrete aether, and the decay of discrete aether then defines all force. What this means is that the photon diploe exchange that defines charge force also then defines a photon pair as the monopole-quadrupole force of gravity. Photon pairs as monopole-quadrupoles then bond neutral matter particles for quantum gravity and are scaled versions of the photon dipole emissions that bond charged particles.

A very simple way to scale gravity force from charge dipole force is to wrap the universe onto itself and let the ratio of the time delay of the atom to the time delay of the universe scale gravity. In other words, the charge dipole force acts locally between the charges of an atom as well as globally as a monopole-quadrupole force when the universe wraps onto itself in time. Gravity force is simply charge force scaled by the ratio of the time delay of an atom with the time delay of the universe as a pulse in time. This simple statement of unification is completely consistent with mass-energy equivalence, Lorentz invariance, gravitational radiation, and many of the other precepts of general relativity. This simple way of unifying gravity and charge force is not yet accepted by mainstream science.

However, the notions of discrete aether, matter exchange, and time delay are much more general that the notions of continuous space, motion, and time as axioms. Continuous space and motion are not congruent between gravity and charge forces and that incongruence precludes unification within the limits of continuous space and time. Instead of continuous space and motion, unification necessitates a pair of conjugates that are congruent and compatible for both charge and gravity forces.

Even though continuous space and motion are very intuitive and deeply embedded into our consciousness, the notions of continuous space and motion are not a priori axioms for all action. Discrete matter and time delay as the proper conjugate quantum operators apply even beyond the current limits of continuous space and motion, which bound more typical conjugates of space and momentum. Space and momentum still have the same meanings and utility for many predictions of action, but for both very large and very small scales, there are no expectation values for space and momentum. Time, for example, has a fundamental two dimensional representation instead of a single continuous dimension of spacetime and time reflects the nature of the boson aether pulse that is the universe.

Things happen to objects of matter in the universe because of the actions of both gravity and charge and we think of gravity and charge as being very different, but in fact they are simply different manifestations of the same force of aether decay at much different scale. The scale ranges from the time delay of the atom to the overall time delay the universe aether pulse. While charge force is a result of the boson matter decay of the universe, gravity force is a result of the fermion decay of microscopic matter. While the universe is mostly boson aether, it is fermion matter that makes up common objects.

The action of the earth's gravity creates stone from cooling inner molten magma and it is the microscopic charges of stone's atoms and molecules that hold those stones together. The much weaker action of gravity is only evident in holding those stones and us to earth's surface, but gravity is what makes earth earth. Someone building a stone wall depends on gravity not only to keep them and the stone wall bound to earth, that gravity also compresses and slightly heats stones in the actions of building a stone wall. That very slight heating of the stone is part of the gravity force of earth and leads to much greater heating of the inner earth.

Action is both what forms objects like stones from atoms and action is how we form objects like stone walls from stone. In both cases, smaller moments of matter come together to form larger objects. The heat and pressure of earth's gravity makes stone while people gather those stones and make stone walls on earth’s surface for some purpose. The gravitational bond between the stones in the wall and the earth heats the stones up very slightly on earth's surface and it is that radiative and conductive cooling that results in the bonding that we call gravitational compression.

Gravity describes how most things of common experience happen and simply depends on mass action, like the action of a deterministic path of an apple falling from a tree. Gravity results in a very deterministic cause and effect universe where it appears that all action results in only local effects. Our notions of space and momentum emerge from the actions of gravity on objects that we sense.

Charge describes how the microscopic actions of atoms and molecules of matter objects happen with quantum matter with both phase and amplitude. Quantum charge is how the apple grew on the tree in the first place and quantum charge released the apple from the tree into gravity mass action. Charge results in a wavelike and probabilistic universe that allows the matter wave amplitude of one object to affect the matter wave amplitude of another object instantaneously across the universe. As a result, both philosophy and science therefore have very different interpretations of the very different natures of gravity and charge actions.

Quantumology is the belief that gravity is just a scaled version of charge force and that quantum of gravity force is a coherent photon pair as a monopole-quadrupole. Although mainstream science and general relativity are not consistent with this view of quantum gravity, the decay of discrete aether and time delay are consistent with quantum gravity.

Charge bonds involve matter exchange between objects while gravity bonds also involve matter exchange between objects and the universe. Motion in the universe emerges from a change in an object’s inertial mass as equivalent energy and it is that exchange of aether that we call object momentum. Changes in an object’s inertial mass or kinetic energy define an object’s action for a given frame of reference while gains and losses of mass as impulse change object momentum. Although motion is a very common way to define momentum in space, the dimensionless ratio of velocity squared to the speed of light squared in ppb is embodied in the dimensionless Lorentz factor.

The equivalence of matter and energy means that velocity and acceleration are equivalent to changes in inertial mass. The dimensionless Lorentz factor impacts space, matter, and time even while most object action involves gains and loses of ordinary matter as impulsive momentum, which typically overwhelm changes in inertial mass. What we call the fields of charge or gravity force are actually matter exchanges among objects that result in acceleration and changes in object velocities. Charge and gravity fields are potential matter, which is the rate of change of inertial matter in time and is that proper matter that comes into existence as velocity or kinetic matter from an inertial frame. In matter time, fields in space are simply a manifestation of the exchange of matter between objects and those matter exchanges are the forces or accelerations of potential matter.

The decay of all universe matter with time, mdot, is in fact a fundamental principle of matter time and is the determinant of both gravity and charge actions, just at very different scales. This decay constant is simply a restatement of charge and gravity forces as cross sections and is equivalent to the dimensionless universal decay of all matter, αdot, at 0.255 ppb/yr. For charge force, αdot applies to the electron mass as the fundamental fermion while for gravity force, αdot applies to the gaechron mass as the fundamental boson, which is some 1e-39 times less than the electron mass.

Currently science uses two somewhat inconsistent theorets to separately predict the gravity and quantum futures of objects in time. This patchwork approach actually works very well for predictions of action within certain scales, but mainstream science yearns to describe gravity as part of a unified quantum action that includes both charge and gravity.

Gravity action is what holds us to the earth as well as what holds the earth in orbit around the sun and gravity action holds the rest of the greater universe together as well. So, gravity action is the way that we predict how objects move for much of our very deterministic and causal and chaotic reality here on earth and gravity action is how we measure the billions of years of our universe time delay. We have come to know gravity action as general relativity but still gravity action scales with the mass distribution of objects and gravity does not depend on exactly what the matter is.

Gravity action in matter time is very simply related to the binding of objects to the boson matter of the universe. Just like the quantum bonds of electrons to nuclei, the quantum bonds of atoms to the universe boson matter result in the attraction between neutral objects that we call gravity. Gravity is a quantum excitation that involves correlated pairs of photons as a mono-quadrupole time and for most common gravity action, quadrupole time is equivalent to proper time, Ï„. This approximation does not account for any quantum exchange effects, where the exchange of identical particles leads to an additional quantum gravity binding energy.

Our microscopic reality, though, is bound with charge and quantum action and, unless an object is very massive, gravity action is not much of a factor at all. In contrast to gravity action, quantum action is very dependent on the exact nature of matter amplitude and phase. Matter amplitude and phase are part of the quantum action that determines the nature of the bonds that hold an object’s matter together.

For example, an atom of hydrogen bonds much differently with another hydrogen atom as compared to a different element like oxygen. Oxygen bonds to two hydrogens and forms the water of our earth and comets. In contrast to charge action, the predictions of gravity action do not really need the details of atoms and bonds and amplitude and phase as long as we know a object's density and mass. However, at larger and smaller scale, the natures of quantum amplitude and phase do indeed impact gravity bonds.

Gravity and quantum actions represent somewhat inconsistent theorets or realities for science, but somehow we know that there is a relationship. General relativity is basically the gravity action that is what holds us to the earth and holds the sun in the galaxy and all galaxies to the universe and is very intuitive and deterministic. Each effect of gravity has a cause and that cause is local to that effect. In contrast to gravity action, quantum action depends on both matter amplitude and phase and not just mass. An extra phase coherence between objects links not only local object actions, but also correlates nonlocal object actions as well.

One of the more notable aspects of relativity is the statement of equivalence of energy and mass, E = mc2, with the proportionality of the speed of light squared and indeed quantum action has adopted that same principle as well. Just this simple matter-energy equivalence (MEE) explains much about both gravity and quantum action since all motion increases the inertial mass for each object proportional to its velocity squared, which is the kinetic energy of motion. Somehow an object gains and loses extremely small amounts of matter simply by changing its velocity.

Another notable result of relativity is the fact that the speed of light for an object does not depend on object velocity, which is a direct result of the equivalence of mass and energy and further results in a dilations of space and time associated with any motion as velocity and acceleration. When it comes to explaining the anomalous precession of Mercury about the sun or the bending of starlight by sol, the proportionality of energy and matter explains about one-half of such observations and the dilation of space and time explains the other half.

While the mass-energy equivalence principle is completely consistent with the formulation of a quantum gravity in matter time, the distortion of a continuous space by velocity and acceleration represents a little bit of a problem for any discrete quantum gravity. This is because dilation of continuous space is a result of gravity and so a particle that carries gravity force would therefore dilate space and alter the particle, which further dilates space, and so on. With discrete matter and time delay, spatial dilation is the result of action in discrete matter and time delay and not a result of gravity per se. While the distortion of continuous space and time with motion is definitely a part of our reality, this distortion is where there is a strain between gravity and quantum actions.

The question comes down to whether or not there is a continuous deterministic and predictable path for an object through space time. In general relativity, gravity distorts space and time and that is what results in a continuous deterministic path as a straight line in continuous 4-D space time. However, it is possible with mass-energy equivalence to have the same dilation of time and along with discrete changes in inertial matter, have the same path emerge for that object. In this reinterpretation, spatial dilation then emerges from the action of discrete matter and time delay and the result is what we call motion. What we imagine as action in space is really first of all an action or change of discrete matter with time delays and then only secondarily do continuous motions and dilations of continuous space emerge.

With discrete matter and time delay, a continuous spatial dilation emerges from the gravity action of an object in discrete matter time and spatial dilation therefore does not therefore cause action or motion in space. With this approach, quantum gravity becomes a straightforward result of action in matter time. While charge force is the exchange of photon dipoles between electrons and nuclei, gravity force is exchange of complementary photon pairs as mono-quadrupoles between the neutral matter and the boson matter of the universe.

The stress-energy tensor of GR then more properly emerges from a mono-quadrupole time and is not an a priori axiom. In quantum gravity, it is the mono-quadrupole time operator and its tensors that provide a proper time for each action from the two time dipoles of the rest and moving frames. For most common actions, the quantum time quadrupole is largely identical to proper time. However, for certain very massive and very small objects, there is a quantum exchange that enhances the gravitational bond. Gravity objects bind to each other by means of exchange of time quadrupoles.

Quantum action is largely about the behavior of coherent microscopic matter and is much less intuitive than gravity action at all scales. Quantum action depends on matter or mass just like gravity but quantum action also depends on something called phase and coherence and charge amplitude, properties of matter that have no relevance in general relativity. The interference effects of light are due to light’s phase and amplitude and so light shows polarization and partial reflection as a result. Yet these coherent effects occur for all objects of matter, not just for light. Neutral matter can show polarization and neutral matter can show partial reflection as well.

The basic equation of motion for quantum action is the Schrödinger equation for discrete matter,
,

which is a proportionality between the amplitude and phase for a matter wave of the future,

,

and the amplitude and phase of a matter wave of the present,

.

This is what is called a differential equation in time and is an action equation that describes how a matter wave changes over time, both in mass and phase. In this equation, mR represents the photon exchange energy that binds an electron to a proton to make hydrogen and is the mass equivalent of the Rydberg energy. There is an infinity of excited states for hydrogen whose energies emerge as spectral lines that converge to a finite ionization energy, which is called the Rydberg energy.

The integral form of the Schrödinger equation for discrete matter is


and shows that matter waves are also proportional to their integration over time, which is their action over time. That proportionality is the ratio of a binding energy, mR, and Planck’s constant and of course a phase factor, -i, which means that the action of an object is somehow orthogonal to its matter in time.

There is an infinity of excited states for hydrogen whose energies as discrete spectral lines converge to a finite value that is the hydrogen ionization or Rydberg energy. There are two solutions to each Schrödinger equation; an inner charge solution involving the charged electron along with an outer gravity solution involving discrete aether. The inner solution has photon dipole exchange that binds electrons to the nuclei of atoms and the outer solution involves pairs of complementary emitted photons that bind neutral atoms to the outer boson aether of the universe.

Matter waves scale with the square root of mass in matter time while the more typical wavefunctions of quantum mechanics are just dimensionless phase as probability amplitude. This means that the integral of a matter wave over all time is an action that results in the measurable property that we call mass. Matter waves are the moments of matter that make up all objects and sensation is the exchange of the matter waves of our senses with the matter waves of an object being sensed. In the parlance of quantum action, a matter wave or wavefunction collapses as a product of each exchange between us and an object and that collapse is the sensation that we imagine as the mass or some other property of an object.

We might see light from an object, feel the object, hear it, smell it, or even taste it. What we sense of an object alone is not the matter wave itself, but the product of the object matter wave with our own sensory matter waves. Sensation is an exchange of both amplitude and phase with objects in a bonding action that we imagine as reality. The discrete exchange of matter actually bonds us to objects with a quantum action that necessarily occurs in discrete quantum steps with discrete quantum states. This bonding action involves our whole body and not just our sensory organs.

A journey from point A to point B involves a series of steps or quantum jumps as an object exchanges discrete aether with other objects in order to get around the universe, successively bonding and conflicting with the matter waves of objects in order to move. Matter waves show action under the influence of operators and those actions result in discrete changes in object matter over time.

Time delay waves also show action, but now as a function of a quasi-continuum of matter. A journey from matter state A to matter state B involves a series of quantum jumps as an object exchanges time delays with other objects. While objects exists with discrete time delays, time is a quasi-continuum that depends on the very large number of quantum jumps of matter particles.

A continuum force like gravity in general relativity does not show the discrete states of quantum gravity but rather shows continuous motion from point A to point B. Continuous motion in space is a very natural and intuitive concept that is not how objects move in discrete matter and time delay. In fact, motion in continuous space results in serious conundrums like the Zeno’s paradox of an infinity of points and quantum action of whole particles resolves Zeno’s paradox but at the expense of a different interpretation for continuous macroscopic gravity action in the universe.

Gravity in matter time is a quantum action that binds atom pairs to the boson aether of the universe, which is discrete gaechron. The complementary photon pairs emitted from the charge actions of electron bonds for two atoms are the light that objects emit from charge and are the gravity force bonds between atoms and molecules as well. Emitted light represents the complementary outer state for the inner binding states of each atom and molecule and emitted light is the exchange that binds the matter waves of atoms and molecules with each other as the matter waves of the universe. Because we see light, we imagine emitted photons on trajectories through the void of space. In fact, emitted photons represent complementary changes in matter states that we call charge and gravity action.

There is a photon dipole exchange that binds an electron to a proton to form a hydrogen atom and such a mass defect is the Rydberg energy for hydrogen as well as binding atoms to each other with further energies and further shared electrons. That same charge force defect represents an equivalent photon pair exchange with the boson aether of the universe that is the gravity force that binds the hydrogen atom to the universe. The dephasing of discrete aether results in what we call gravity force and by scaling discrete aether exchange by the ratio of electron mass to discrete aeither, discrete aether decay is then what we call charge force as well. The light that we see from the stars at night represents a discrete aether exchange that binds the electrons and protons as well as atoms into stars and stars into the galaxy as well as the galaxy into the very fabric of the cosmos.

Although science expects a new particle called a graviton to be the exchange particle of gravity force, with the scaling of photon pairs in discrete matter, there is no new gravity particle. Rather, it is the universal dephasing of discrete boson aether that determines both gravity and charge forces and the photon is the basic exchange particle for both gravity and charge forces. Whereas photon exchange between the electron and proton represents charge force, photon pairs exchange between the electron and discrete aether represents gravity force. Thus, the ratio of the gaechron particle of discrete aether to the electron mass represents the 1e39 scaling between gravity and charge force cross sections.

Quantum action is often called odd although quantum action has been extraordinarily successful for virtually all predictions of action. However, quantum predictions are always probabilistic and uncertain and sometimes matter waves show correlated and coherent effects that entangle different locations in space. Even for a highly local matter wave action there is still some quantum uncertainty, which bothers many people. Since quantum phase can persist between two objects across the universe, the observation of one object phase seems to determine the other object phase instantaneously. So when that quantum uncertainty involves locations across the universe, people get even more uncomfortable and bothered.

And yet quantum action does not violate any causal principles, rather quantum action simply refines those causal principles to include matter wave phase, amplitude, and coherence as well as mass as the product of two matter waves. The phase or coherence of a matter wave is a property of an object that we do not directly experience and so it is less intuitive than just the mass of an object, which is the square of its amplitude and does not carry phase information.

There are many different ways of describing the issues of quantum nonlocality and entanglement, but basically it comes down to a set of fundamental differences between quantum and gravity notions of space and motion. Quantum motion involves both the wave amplitude and phase of an object, while gravity motion involves only the mass of an object, i.e. the product of two matter waves, and so gravity action for mainstream science does not involve or entangle matter wave phase and amplitudes between objects at all.

Objects follow certain action principles where action is the integral or sum total of an object’s matter over time. Any macroscopic object is the product of a very large number of actions over time and objects continually gain and lose discrete aether as a part of their existence in the universe. Our intuition typically represents action as some kind of spatial displacement of an object, but it is the discrete aether exchanges of an object in time that better represent quantum action instead of motion. Discrete matter exchanges occur as quantum action and are the action we see as motion for an object in space.

Einstein first recognized that both event and action times are equivalent to spatial displacements and his general relativity shows how gravity action dilates matter, space, and time in a continuous four dimensional spacetime. Objects that gain inertial mass from their potential matter we interpret as a relative motion in space and that mass gain affects the space and action time between objects as well.

There are, however, different ways to interpret the dilation of matter, space, and time, with quantum gravity and therefore with a pure quantum action. Objects are in constant discrete aether exchange with other objects and it is from the gained inertial mass from other objects that object motion in space emerges. However, in general relativity the trajectory of an object follows a determinate geodesic path determined by gravity. If rather the distortion of space is a result of the gravity actions of that object, the same principles apply but now with a complementary quantum action for both gravity and charge.

An object like a rocket ship gains velocity and momentum by ejecting matter with the mass impulse of some kind of burning fuel and the action of the burning fuel propels the rocket in the opposite direction by its equivalent momentum. However, the relative motions of both ship and fuel actually are a result of much smaller gains in inertial masses, discrete aether, as equivalent kinetic energy by the matter-energy equivalence principle.

In other words, even while we imagine that the total rest mass of rocket and fuel does not change due to exchange of equivalent and opposite momentum, in fact, it is the the very small changes in the inertial masses of both rocket and ejected fuel that results in their respective motions. In a strict sense, then, what causes motion in space is the increase in inertial masses of two objects with equal and opposite momentum by exchange of discrete aether. Both objects increase in mass proportionately with their velocities squared relative to a rest frame and this matter increase comes from the potential matter as energy that was embedded into the chemical and gravity and nuclear bonds of the fuel.

The quantum action of discrete matter and time delay, which along with action, are the three axioms that close our universe. An action equation predicts the future of an object as discrete exchanges of matter with other objects over time. Quantum gravity predicts a large number of possible futures for macroscopic objects, but quantum action for macroscopic objects involves much greater scale than the local actions of gravity.

While there are a large number of possible futures for an object undergoing quantum action, including nonlocal futures, under gravity action of mainstream science, there is only one possible future for an object. This difference of action principles goes for the same object and the same reality and leads to interminable scientific and philosophical discourse about which action actually better describes an object’s possible future. Gravity and quantum actions are largely consistent with each other in common experience, but the two actions can represent irreconcilable futures for certain very large or very small objects. For example, until science reconciles gravity with quantum action, there is simply no way to definitively address the mystery of quantum gravity nonlocality.

The single future of gravity action in GR is consistent with a reality that is deterministic and local. Local effects always have local causes and this is the reality that we normally experience with gravity. Gravity is a continuous and infinitesimal force with a pesky microscopic singularity centered on each particle of matter and so there is no coherence for an object between two different locations in space. Since gravity action is the basis of our intuition for macroscopic objects in everyday life, we therefore have a very strong expectation that local actions only correlate to other local effects. We know that two ballistic particles from a source can arrive simultaneously at very different locations along separate paths A and B. However, a single matter wave can propagate along both paths A and B and yet only appear as a single particle at A or B. Note the appearance at A is coherent and correlated with no appearance at B, but neither causes one nor the other to occur.

Our intuition and experience, after all, are both largely based on an intuition of gravity action and so we greatly favor gravity action and mass as bases for predictions. Gravity action is usually very predictable since after all, what goes up, must come down. For gravity force, there is no allowance for the coherence of a single matter wave across the time delay of the universe.

Phase coherence can make it seem like the appearance of an object in one place causes its absence in another place, or that the absence of an object in another place causes the object appearance in the one place. Coherence has many effects, but quantum action does not violate any causal principle. Quantum action simply includes phase along with amplitude and a source and so better represents the actions of the entire universe, including actions at very small and very large scales.

A quantum universe consists of objects simultaneously located everywhere in the universe as amplitudes of matter waves. What provides us with the sensation of an object in one place and on one path is the time and phase that separates that object from other objects. It is an object’s incoherence with all of its other possibilities as a matter wave that we sense as a local object in time and space. While some of the many possible futures of an object from quantum action are nonlocal, the issues with quantum nonlocality and entanglement are fundamentally related to the many very different possible futures or phases for quantum action.

Quantum action is perfectly causal, but unfortunately quantum action is just sometimes not very intuitive since quantum can involve phase and coherence among objects in different places. We find it hard to accept how a perfectly real and observable ballistic object could ever be a matter wave that has both an amplitude and phase and magically disappears from one place due to destructive interference and then equally magically reappears in a completely different place due to constructive interference of those same amplitudes.

Worse yet, objects as matter waves can actually exist as a possibility in more than one Cartesian location until it finally interacts with another object at one place or the other, i.e., the matter wave collapses or dephases. And yet our quantum reality shows that matter has both amplitude and phase and therefore matter will show the many nonintuitive effects of coherency and interference.

It is particularly confusing when explanations of quantum action give macroscopic objects like people and cats the coherent attributes of microscopic matter. Coherent matter behaves so differently from incoherent matter that comparisons between coherent and incoherent macroscopic matter can result in very confusing allegories. Although it is possible for macroscopic matter to show coherence, the dephasing times for any macroscopic object are typically very short unless the objects are very massive neutron stars or black holes.

Until science unites charge and gravity into a common quantum action for all objects, there will continue to be confusion and strong differences of opinion about the nature of quantum action versus gravity action. For example, given similar charge and gravity forces for a coherent object, quantum action shows interference effects due to superposition but gravity only predicts ballistic collisions between objects. We have an intuition and life experience with macroscopic matter and gravity action that is very difficult to reconcile with the reality of microscopic matter and quantum action.

Light is a rather unusual form of matter and a photon of light on a trajectory in space is also the exchange particle that binds charged particles together. An exchange of a photon dipole between an electron and proton represents the dipolar charge force that stabilizes a hydrogen atom dipole, which is the basis of quantum electrodynamics and is well accepted by science.



That emitted photon pair is then the binding force for gravity, but this is not a common understanding. For one thing, charge is a dipole force while gravity is a mono-quadrupole force and so it is not clear how a dipolar photon with spin = 1 and plus/minus amplitudes can result in mono-quadrupole gravity with spin = {2, 0, -2} and quadrupolar amplitudes. The radiative cooling of hydrogen at the CMB created photon pairs that are a quadrupole attractive force called gravity. Since there is a pair of photons for every two neutral atoms to the universe, it is that mono-quadrupole pair that is responsible for gravity force.

In order for a neutral atom to form from charged electrons and protons, the neutral atom must emit or otherwise radiate its dipole charge binding energy as a complementary photon. That emitted photon is equal to the atom’s binding energy, which is the Rydberg energy for hydrogen, for example. There actually can be and are many photon emissions and absorptions of various energies and so this description just simplifies that complexity into one single event pair.

Each pair of neutral atoms emits a pair of photons at creation and those photon matter waves have complementary spin and polarization. While the dipole force between these particles and the photons progressively cancels out over time, the mono/quadrupole force persists as a tensor. Thus gravity force behaves as the quadrupole tensor of a coherent photon pair with spin = 0 and is a single particle with physical dimensions that literally define the age of the universe.

There is just one future for gravity action in general relativity and that one future is still consistent with our deterministic intuition. General relativity dilates or distorts continuous matter, space, and time with gravity action and there are many strange results of general relativity having to do with time dilation, simultaneity, and frames of reference. But while distant objects far away from a gravity action do not affect a local gravity action very much, the ratio of hydrogen’s time dipole to the time dipole of the universe is the scaling between gravity and charge forces.

In contrast to the determinism of gravity action in GR, there are actually a large number of possible futures for the same action as a quantum time quadrupole. The Rydberg photon emitted from hydrogen at creation is the exchange with the universe that binds each hydrogen atom to the boson matter of the universe. The time delay of that bond is coherent with that of the electron around the proton. The photon exchange between the universe and each pair of such atoms binds each atom to the universe matter and therefore to each other as well. It is then the shrinkage of the universe about those atom’s center of mass that represents what we interpret as the binding force of gravity between these two hydrogens.

Therefore the binding energy for hydrogen is the sum of the binding energy of the electron and proton along with a second term that is the binding energy of the atom with the discrete aether of the universe. In a strict sense, the binding matter of the electron and proton of an atom scales to the binding matter of that atom to the universe. Since they are equal and opposite in sign, their sum is zero and that result is an example of the Taylor-DeWitt equation. Even though their energies are equal and opposite, charge and gravity matter waves are quite different.

Whatever future actions occur for atoms in their many possible futures, their center’s of action and the gravity action that goes along with these centers persists. As matter evolves into heavier elements in star fusion engines, there are additional light and energy exchanges between those heavier elements and the universe and this additional action matter means that matter bonds in more complex ways to the universe just as matter bonds in more complex ways with different elements. The nature of gravity force actually increases over time just as the universe of matter shrinks or dephases and it is the overall shrinkage of the universe that is the origin of all force.

Quantum mechanics represents matter as the two dimensions of amplitude and phase. Thus a particle on a trajectory in space represents the matter of an object as a wave in a spectrum of matter waves across all space and time. A classic example of the wave nature of light is a series of strong and weak intensities, fringes, that is an interference pattern. An equally classic example of the particle nature of light as photons is the photoelectric effect where a photon of some minimum energy results in ejection of an electron from a metal surface.

The wave nature of light results in a pattern of light and dark fringes due to a coherent action from a single source between two or more possible paths for a source’s photons. This coherence can be the result of any number of means but the typical experiment is with two slits and the resultant diffraction of a light source.

However, each peak of intensity of the fringe pattern comprises a large number of measurable single photon events from the source. We want very badly that each of those photons journeyed ballistically along straight line paths from the source to the pattern and are disappointed to learn that there is not a single ballistic path for any single photon. Rather, each photon journeys as a matter wave with a wavelike trajectory on multiple paths to the interference pattern.

We are further disappointed to learn that this fringe pattern could persist over the dimensions of the universe. That is, the photon that we detect right here right now that come to us from a source may have also possibly been on a different path, somewhere very far away connecting some other object to the same source at the same time distance away. Since the photon wave journeyed across the universe somehow on its way to us right here we presume that its journey was ballistic as a particle.

When we record the photon right here, right now, we know for certain that the photon was here now and therefore not ever anywhere else. But the moment before we measured the photon here now, there had been a possibility that that same photon as a wave would have occurred somewhere else in the universe and therefore not here. Our intuition, though, tells us that photons that emanate from a source do so in a continuous ballistic manner and those photons are on continuous ballistic paths. The quantum truth is that it is photon matter waves that emanate from a source, and a photon matter wave is not yet a ballistic photon localized in space.

This seems like a funny result since when we see a photon, we know that the photon came from the image of a source that we imagine behind the photon and so we imagine a ballistic Cartesian journey in a more or less straight line from the source to our eye. If the source is incoherent, we imagine that it shines equivalently in all directions, but still imagine each light wave as a ballistic photon particle.

This is how we imagine objects in our Cartesian minds and a quantum action as a wave goes against the deterministic intuition of our ballistic gravity action. This does not mean that the photon did not exist before its wave dephased from the source, rather it means that the photon existed as a matter wave with both amplitude and phase and not as a ballistic particle.

What gives? Why can an object appear to be in more than one place as a matter wave prior to its interaction with another object at a different location? And what about the recoil momentum of the source? The ballistic action of a photon leaving a source means a recoil of equal and opposite momentum of the source since that is our experience with the ballistics of firing a bullet from a gun. A gun immediately recoils with the bullet momentum and does not wait until the bullet hits a target. In other words, the bullet does not remain coherent with the gun from which it discharged for very long and so the ballistic path of the bullet is a single path from the source.

However, a bullet is really not an apt analogy for a photon as a matter wave.

A different perspective provides different information about an object and while that information from a different perspective is in principle knowable, we cannot ever know about an object from every possible perspective. We can never observe all of the different perspectives of an object, but still that lack of knowledge does not represent anything that is fundamentally unknowable.

The path of a photon through space, however, can represent information that is fundamentally unknowable. A matter wave is necessarily a superposition of states and so we can only know the result from say two possibilities, A and B, by seeing the photon along path A. However, we can only then conclude that the photon’s amplitude wave included path A and we cannot know that the photon was ballistic on path A. The photon may or may not have existed as a matter wave superposition on A and B even though we can still use the photon location at A or B to know the direction of the source.

A single photon event does not tell us very much about a source and we typically depend on many more than thousands of photons to locate a source image with any precision.

A photon and its source can remain coherent with each other and that coherency will persist until some kind of dephasing action occurs with another object. An action with another object can dephase either the photon or the source and if that happens, the photon becomes ballistic. A subsequent action between an object and the photon, such as reflection, polarization, diffraction, refraction, etc., in effect creates a new source and a new phase relationship with the photon.

Actually we readily accept some degree of time and spatial uncertainty for events as long as the uncertainites are local to an object or action. But it really distresses our causal nature when there are large spatial gaps between an object’s possibilities, i.e., when the fringe patterns of quantum interference are really large. It simply is not possible to assign ballistic trajectories to photons with anything more than a probability.

We as quantum beings are in a quantum universe and only have relational experiences with objects by exchange of matter. Yet we imagine from those limited relations a ballistic Cartesian existence outside of our quantum mind with well-defined objects that we recognize from past experience. While a Cartesian object has a single ballistic trajectory in space and time, there are many possible futures for a relational object with which we are in direct contact and so we exchange our own matter waves with that of an object. Quantum events and actions reveal that there is a relational dimension in our quantum existence, even though we normally only imagine a Cartesian world of objects from our relational experiences with those objects.

It is from our relational experience with an object that we project its Cartesian or ballistic reality and so that is the dilemma of existence. It is only possible for us to experience an object through our relations with an object’s matter waves, but we then imagine a ballistic Cartesian existence in our mind that represents that object on a trajectory in the space outside of our mind.

We can prepare a coherent state that represents a particle’s matter wave amplitude at two places across the universe from each other with different phases. However, once the particle interacts with an object in one place or the other, that action can dephase or collapse that matter wave and therefore localize the matter wave to a particle in that one place.

The background matter of the universe, whatever you want to call it, is mostly what defines the universe and there is necessarily a coherence in time for any matter action. The phase of an action of a particle defines the location and direction of the particle journey and so a particle reality occurs in just one location. A particle amplitude, though, goes into and out of existence as its matter wave oscillates in time, in principle for the whole time of the universe. And a particle as a matter wave at a given moment also varies in the matter spectrum of the universe, in principle involving all of the matter in the universe.

One way to unite gravity and charge force is by the principles of discrete matter and time delay. In discrete matter time, light is the exchange particle that is responsible for both charge and gravity forces. Light binds charges together into an atom with a single photon and light also binds atoms to the universe with photon pairs as an exchange that binds atoms to each other with gravity.

In much of our experience, particles are well localized and that means particles are dephased and incoherent and ballistic in both the time and matter of the universe. In quantum parlance, this is what we know as our Cartesian reality, where particles and objects all seem to behave ballistically and independently. If a particle is on a trajectory through space, that trajectory represents a continuum of displacements along that trajectory.

However, a particle as a coherent matter wave manifests itself with additional possible futures in both proper and action times of the universe. While charge force is a local exchange on the dimensions of an atom, gravity force is the stabilization of that atom with a photon exchange that occurs on the dimensions of the universe. A coherent charge state binds each atom with a coherent gravity state due to an emitted photon wave, a wave that has 2Ï€ symmetry. Gravity force, though, is a result of two complementary photon waves, which are the exchanges of photons on the much larger time and matter dimensions of the universe and therefore have a 4Ï€ symmetry.

In effect, gravity force is therefore coherent with charge force and the action of light scales both gravity and charge forces by the matter and time dimensions of the universe. The photon, electron, and proton of each atom are in an action that binds the atom together while a complementary emitted photon wave exchanges with discrete aether and binds atoms to each other through the universe of matter.

Coherent gravitational states are therefore possible, but only with very simple gravitational matter. The boson accretion that we call a black hole, for example, is an example of highly coherent gravitational matter.



In principle, a gravity beamsplitter as shown in the figure at right prepares small objects like atoms or molecules into a superposition of coherent gravity states. Two identical massive bodies like the earth and moon orbit each other around a center of mass as in the figure. Two much smaller and identical objects, A and B, are in orbits that intersect at a gravitational Lagrange point between the earth and moon.

It appears that any gravitational Lagrange point can result in generating coherent gravity matter states for small objects on different orbits. Moreover, two stars that are equidistant from a third star result in a similar degeneracy that results in a coherent matter wave resonance that affects all three stars. Such matter waves perturb the underlying discrete boson aether of the universe and so matter waves affect both charge and gravity actions in complementary ways.

Coherent matter states in the universe have the same proper times relative to a source event, even though they are widely separated in action time. While a matter wave can remain coherent with a source for a very long time, that does not mean that a particle’s existence is uncertain; it does mean that a particle’s state or future is uncertain.

There is a conflict between the ballistic Cartesian existence for an object that we typically project with our mind and the relational existence that actually binds us to the matter waves of objects with matter exchange. These two dimensions of existence represent the dual aspects of our quantum reality as well as the duality of Descartes’ and other philosophies. In our ballistic Cartesian experience, existence has one meaning; an object that exists does so right here and right now as part of a proper existence.

In our relational experience, the matter waves we exchange with objects only represent possible futures. When we exchange discrete aether waves, we in essence share or exchange both matter and phase with objects in the wavelike realm of quantum exchange, and existence of quantum matter waves means something more than Cartesian ballistic existence. The relational aether wave exchange that binds us to an object means that the object becomes a part of us and we become a part of the object, even though we only sense some small fraction of that matter wave exchange.

When we exchange matter waves with an object, we call that experience, and there is always a period of both matter exchange as well as phase coherence between two objects. Any residual coherence between us and the object can result in a further relational component beyond a mass change and is a quantum entanglement that is beyond the typical ballistic Cartesian experience of action and reaction that we imagine. Note that Cartesian and relational dimensions of experience are really both part of a dual quantum reality.

We can and do imagine and know that there are other possible futures for any event that we experience. In particular, an action can dephase a photon from its source in which case the photon becomes ballistic. But as long as a photon remains coherent with its source, a matter wave binds not only the photon to the source, but to other objects as well at the same time distance from the source.

The photon could have a single ballistic future or it could have the many possible matter wave futures that entangle it with other objects. It is the other possible nonlocal and unknowable futures that somehow bother our causal ballistic natures. We want to place each object that we experience on a single ballistic Cartesian trajectory that is continuous from an origin to a destiny. Our intuition does not have much patience for the seemingly endless waves of quantum coherency that entangle local aether waves with other aether waves on other trajectories in the universe.

A photon that remains coherent with the action of its source has different possible futures from a photon that has dephased from its source. A photon that has dephased from its source has a single ballistic future much like any macroscopic object. All macroscopic objects, though, continually emit and absorb light and particles with incoherent phases and so a macroscopic objects’ decoherence times can be quite short. Simple quantum objects like photons, though, can retain coherence with their sources across the universe.

We are very comfortable with the causal notion of directional coherence and expect that a single point of an object emits photons in a single direction. When we see a photon from such a point on an object, we know the direction from which it came and our quantum logic does not change that truth. Where we have trouble is in imagining a single photon event that also has a transverse phase coherence as a matter wave that is perpendicular to the photon direction from a source. Transverse phase coherence means that a photon amplitude travels as a coherent wave in different possible directions at the same time even though the photon will only be absorbed by another matter wave in one particular location or phase.

There are actually two dimensions to time and our two dimensional time along with two dimensional matter represents a total of four dimensions in matter time. Given a Ï€/2 or perpendicular phase relationship between matter and time, these four matter time dimensions reduce to three; matter, time, and phase. Time’s two dimensions include a proper time and an action time and matter’s two dimensions likewise include proper matter and action matter.

Our proper time is relative to the CMB in our 371 km/s velocity inertial frame. Action time is that associated with velocities of common experience, perhaps all of several meters per second and so action time represents displacements that are orders of magnitude less than the displacement of proper time.

Proper matter describes our galaxy as it moves at 550 km/s with respect to the CMB and rotates at 200 km/s, while our sun moves at 220 km/s, about 20 km/s faster than the galaxy rotates. These actions all make up the proper matter that results from our 371 km/s proper motion with respect to the CMB while our action matter is what occurs at lower scale.

Earth rotates about the sun at 30 km/s and spins about its axis at 0.47 km/s while we travel down the freeway at 0.027 km/s and walk around at about 0.001 km/s. Matter is likewise two dimensional with one dimension being the proper matter of our comoving frame of reference in the universe. The second matter dimension is the action matter of common experience that we call kinetic and potential energies.

Each atom of the universe forms as bound charges in a quantum exchange of light and other bosons that complements a gravitational quantum exchange orbit of that atom with the gaechron matter of the universe. We like to imagine a ballistic orbit for gaechron around an atom through space just as we like to imagine an electron in a ballistic orbit around a proton. But the atom-gaechron orbit is through time and quantum phase and not through space just as the electron orbit is through time and quantum phase as well.

While continuous space and motion are very useful ways to imagine the universe, continuous space and motion do not always represent either electron-proton states or atom-aether states very well. In addition to the time of this atom-aether orbit, there is a quantum phase angle between time and matter and for typical action, and it is from matter and time and from that phase angle that we project what we call space.

For any pair of atom-universe bonds, the shrinkage of the universe aether is the gravity force by which atoms appear to attract each other. In fact, the shrinkage of the universe is responsible for both charge and gravity force, just at very different scale. Eventually, these gravitational accretions of fermionic matter evolve from hydrogen into other elements in stars and that nucleosynthesis releases more action matter. A portion of the total energy and luminosity or action matter of each galaxy derives from nucleosynthesis and that action matter eventually ends up as large boson accretions known as black holes.

The formation of protons and electrons from the aether of the early universe results in a light that is the integrated CMB luminosity at 2.7 K, very much colder than the 70-80 F that people prefer. Once stars begin to fuse hydrogen into other elements, there is enough action matter to reionize hydrogen as well as to begin to fuse matter into excited states of the universe. And this reionization is an additional source of energy that then contributes to an overall universe energy balance.

Suppose you see an object along path A, if the object was at some incremental displacement as A – ds the previous moment, then the object was ballistic and its action was local. There are objects that exist in a superposition of quantum states, {A, B, C, …} and such an object can distribute around the universe according to some prior coherent quantum action. Note that a ballistic object actually also follows that same quantum logic, but a ballistic object has dephased and no longer coherent with its source.

The action of a beamsplitter creates coherency between the two paths A and B and some kind of magic occurs at the beamsplitter that makes 50% of photons disappear by destructive interference at both A and B. The ballistic Cartesian interpretation is that the beamsplitter reflects 50% of the photons as particles to A and transmits 50% to B and although this answer is technically wrong, it is good enough for many applications. If all you need is a one-way mirror or a grayed window or sunglasses to block sunlight, you really do not need to know much about single photon coherence. Thus our ballistic Cartesian reality does work fairly well for most predictions of action, even for those quantum actions with quantum devices like sunglasses.

We often lack knowledge about the appearance of an object even though that object exists as a single state and its appearance is in principle knowable. We can also lack knowledge about the state of an object, but if the object does exist in a single state, that single state is in principle knowable as well and not subject to quantum entanglement. When an object or image is a superposition of two coherent amplitudes, though, a single state is not yet realized and therefore not even knowable in principle. The object or image will not appear until we or other objects dephase the amplitudes from each other and a single state occurs.

Using logic to test quantumology tries to get a more graphic description of nonlocality. Remember, though, that quantum logic is already quite rigorous since it is based on math. It is rather the word descriptions of quantum logic that somehow fail to convince our common ballistic intuition of the principle of coherency. Our language is full of loopholes and conundrums and logic itself is often thwarted by the words that confuse meaning.

You say A is B or A is not B, but of course, we have a lot of examples of words that provide ambiguous meaning even to simple logic statements. Nothing is true, but if that is correct, it means that nothing is not true as well. The universe is finite, and if that is true, it would mean that the universe is not finite as well. Everything is finite and if that is true, nothing is finite since nothing is a part of everything. If there is anything that is really true, it is that nothing is really true. But if nothing is true, then anything is not true as well.

Is matter real? Is time real? Is action real? What is matter and why is matter the way that it is? What is time and why is time the way that it is? What is action and why is action the way that it is? Why does the world exist?

Thinking is being, but thinking is in our mind and being is not in our mind, and if that is all true, thinking is not being.

One very significant issue with quantum versus gravity actions is in the definition of consciousness. Unless there is a way to express conscious choice in the context of quantum action, there will always be those who believe that conscious choice is an illusion of the chaos of a ballistic determinism. Usually the reasoning goes that all action in the world is actually deterministic, but the world it is also just really, really very complicated and so we can never hope to know all of that complexity and chaos.

In a world of chaotic determinism, while it seems like we have free choice, this is just an illusion and the truth is that we just have more choices that we can ever possibly know about. However, philosophers who take this position then need to stipulate that there is still a need for personal responsibility and morality. In a deterministic universe, it is not clear that anyone is really responsible for their actions. After all, action and behavior are simply the some total of their genes and experiences up until that point.

All choice comes down to a binary decision between action and inaction at some threshold of a neural action potential and since quantum probability determines the neural action potential as it does all action of the universe, quantum probability also governs choice. Circumstances at the time of a choice predetermine most choices that we make and so in that sense, even binary decisions are not random. Each set of circumstances determines the threshold of action, but at the threshold of each action/inaction there is a distribution of quantum possibilities and a superposition of action and inaction states. In particular, there are a number of even odds choices that we make that may still substantially change the path of our lives. Every action, then, is a quantum action and involves some superposition of states for some period after the action.

An aware matter algorithm is part of our consciousness is therefore an important part of what makes us us. While most actions have fairly predictable results, there are no perfectly predictable results of action, especially for the results of human actions. Given the free choice that is quantum action, we do have a responsibility for choosing moral action since we freely choose our path in life as part of our purpose.

What we know of as right and wrong and just and unjust is part of the purpose with which we journey in life from our origin to a destiny. We are not programmed to be good or evil, but we are free to choose our destiny despite any experience of our past.

Some of what happened in the past involved objects that persisted as amplitudes and never collapsed into intensities. What this means is not that these objects do not exist as one phase, rather it means that the objects persist with more than one possibility as matter amplitudes that still project into more than one spatial location in the present moment.

Continuous space and motion are really just the results of discrete matter and action and so space exists only as a result of discrete matter, time delay, and the action of matter exchange. What this means is that while space is a convenient and necessary way to imagine discrete matter and action, the notions of continuous space and motion are limited. Although we find it useful to remember space as an object of the past that contains objects of action, the universe exists as an object of matter and its matter spectrum is what actually exists. While we get confused by objects that appear to simultaneously exist in different places in space, the state of the universe matter spectrum at any past time is knowable.