Posted on 08/13/2003 10:59:23 AM PDT by RightWhale
Time, Mechanics and Zeno Undergo Major Revision
by Brooke Jones, Wellington - Aug 11, 2003
A bold paper which has highly impressed some of the world's top physicists and been published in the August issue of Foundations of Physics Letters, seems set to change the way we think about the nature of time and its relationship to motion and classical and quantum mechanics.
Much to the science world's astonishment, the work also appears to provide solutions to Zeno of Elea's famous motion paradoxes, almost 2500 years after they were originally conceived by the ancient Greek philosopher. In doing so, its unlikely author who originally attended university for just 6 months, is drawing comparisons to Albert Einstein and beginning to field incredulous enquiries from some of the world's leading science media. This is contrast tospacedaily.com being sniggered at by local physicists when he originally approached them with the work, and once aware it had been accepted for publication, one informing the journal of the author's lack of formal qualification in an attempt to have them reject it.
In the paper, "Time and Classical and Quantum Mechanics: Indeterminacy vs. Discontinuity", Peter Lynds, a 27 year old broadcasting school tutor from Wellington, New Zealand, establishes that there is a necessary trade off of all precisely determined physical values at a time, for their continuity through time, and in doing so, appears to throw age old assumptions about determined instantaneous physical magnitude and time on their heads. A number of other outstanding issues to do with time in physics are also addressed, including cosmology and an argument against the theory of imaginary time by British theoretical physicist Stephen Hawking.
"Author's work resembles Einstein's 1905 special theory of relativity", said a referee of the paper, while Andrei Khrennikov, Prof. Of Applied Mathematics at Växjö University in Sweden and Director of ICMM, said, "I find this paper very interesting and important to clarify some fundamental aspects of classical and quantum physical formalisms. I think that the author of the paper did a very important investigation of the role of continuity of time in the standard physical models of dynamical processes." He then invited Lynds to take part in an international conference on the foundations of quantum theory in Sweden.
Another impressed with the work is Princeton physics great, and collaborator of both Albert Einstein and Richard Feynman, John Wheeler, who said he admired Lynds' "boldness", while noting that it had often been individuals Lynds' age that "had pushed the frontiers of physics forward in the past."
In contrast, an earlier referee had a different opinion of the controversial paper. "I have only read the first two sections as it is clear that the author's arguments are based on profound ignorance or misunderstanding of basic analysis and calculus. I'm afraid I am unwilling to waste any time reading further, and recommend terminal rejection."
Lynds' solution to the Achilles and the tortoise paradox, submitted to Philosophy of Science, helped explain the work. A tortoise challenges Achilles, the swift Greek warrior, to a race, gets a 10m head start, and says Achilles can never pass him. When Achilles has run 10m, the tortoise has moved a further metre. When Achilles has covered that metre, the tortoise has moved 10cm ... and so on.It is impossible for Achilles to pass him. The paradox is that in reality, Achilles would easily do so. A similar paradox, called the Dichotomy, stipulates that you can never reach your goal, as in order to get there, you must firstly travel half of the distance. But once you've done that, you must still traverse half the remaining distance, and half again, and so on. What's more, you can't even get started, as to travel a certain distance, you must firstly travel half of that distance, and so on.
According to both ancient and present day physics, objects in motion have determined relative positions. Indeed, the physics of motion from Zeno to Newton and through to today take this assumption as given. Lynds says that the paradoxes arose because people assumed wrongly that objects in motion had determined positions at any instant in time, thus freezing the bodies motion static at that instant and enabling the impossible situation of the paradoxes to be derived.
"There's no such thing as an instant in time or present moment in nature. It's something entirely subjective that we project onto the world around us. That is, it's the outcome of brain function and consciousness." Rather than the historical mathematical proof provided in the 19th century of summing an infinite series of numbers to provide a finite whole, or in the case of another paradox called the Arrow, usually thought to be solved through functional mathematics and Weierstrass' at-at theory, Lynds' solution to all of the paradoxes lay in the realisation of the absence of an instant in time underlying a body's motion and that its position was constantly changing over time and never determined.
He comments, "With some thought it should become clear that no matter how small the time interval, or how slowly an object moves during that interval, it is still in motion and it's position is constantly changing, so it can't have a determined relative position at any time, whether during a interval, however small, or at an instant. Indeed, if it did, it couldn't be in motion."
Lynds also points out that in all cases a time value represents an interval on time, rather than an instant. "For example, if two separate events are measured to take place at either 1 hour or 10.00 seconds, these two values indicate the events occurred during the time intervals of 1 and 1.99999 hours and 10.00 and 10.0099999 seconds respectively."
Consequently there is no precise moment where a moving object is at a particular point. From this he is able to produce a fairly straightforward resolution of the Arrow paradox, and more elaborate ones for the others based on the same reasoning. A prominent Oxford mathematician commented, "It's as astonishing, as it is unexpected, but he's right." On the paradoxes Lynds said, "I guess one might infer that we've been a bit slow on the uptake, considering it's taken us so long to reach these conclusions. I don't think that's the case though.
"Rather that, in respect to an instant in time, I don't think it's surprising considering the obvious difficulty of seeing through something that you actually see and think with. Moreover, that with his deceivingly profound paradoxes, I think Zeno of Elea was a true visionary, and in a sense, 2500 years ahead of his time." According to Lynds, through the derivation of the rest of physics, the absence of an instant in time and determined relative position, and consequently also velocity, necessarily means the absence of all other precisely determined physical magnitudes and values at a time, including space and time itself.
He comments, "Naturally the parameter and boundary of their respective position and magnitude are naturally determinable up to the limits of possible measurement as stated by the general quantum hypothesis and Heisenberg's uncertainty principle, but this indeterminacy in precise value is not a consequence of quantum uncertainty. "What this illustrates is that in relation to indeterminacy in precise physical magnitude, the micro and macroscopic are inextricably linked, both being a part of the same parcel, rather than just a case of the former underlying and contributing to the latter."
Addressing the age old question of the reality of time, Lynds says the absence of an instant in time underlying a dynamical physical process also illustrates that there is no such thing as a physical progression or flow of time, as without a continuous progression through definite instants over an extended interval, there can be no progression. "This may seem somewhat counter-intuitive, but it's exactly what's required by nature to enable time (relative interval as indicated by a clock), motion and the continuity of a physical process to be possible." Intuition also seems to suggest that if there were not a physical progression of time, the entire universe would be frozen motionless at an instant, as though stuck on pause on a motion screen. But Lynds points out, "If the universe were frozen static at such an instant, this would be a precise static instant of time -- time would be a physical quantity." Consequently Lynds says that it's due to nature's very exclusion of a time as a fundamental physical quantity, that time as it is measured in physics, or relative interval, and as such, motion and physical continuity are possible in the first instance.
On the paper's cosmology content, Lynds says that it doesn't appear necessary for time to emerge or congeal out of the quantum foam and highly contorted space-time geometry's present preceding Planck scale just after the big bang, as has sometimes been hypothesized. "Continuity would be present and naturally inherent in practically all initial quantum states and configurations, rather than a specific few, or special one, regardless of how microscopic the scale."
Lynds continues that the cosmological proposal of imaginary time also isn't compatible with a consistent physical description, both as a consequence of this, and secondly, "because it's the relative order of events that's relevant, not the direction of time itself, as time doesn't go in any direction." Consequently it's meaningless for the order of a sequence of events to be imaginary, or at right angles, relative to another sequence of events. When approached about Lynds' arguments against his theory, Hawking failed to respond.
When asked how he had found academia and the challenge of following his ideas through, Lynds said it had been a struggle and that he'd sometimes found it extremely frustrating. "The work is somewhat unlikely, and that hasn't done me any favours. If someone has been aware of it, my seeming lack of qualification has sometimes been a hurdle too. I think quite a few physicists and philosophers have difficulty getting their heads around the topic of time properly as well.
"I'm not a big fan of quite a few aspects of academia, but I'd like to think that what's happened with the work is a good example of perseverance and a few other things eventually winning through. It's reassuring to know that happens." Lynds said he had initially had discussions with Wellington mathematical physicist Chris Grigson. Prof. Grigson, now retired, said he remembered Lynds as determined. "I must say I thought the idea was hard to understand. He is theorising in an area that most people think is settled. Most people believe there are a succession of moments and that objects in motion have determined positions." Although Lynds remembers being frustrated with Grigson, and once standing at a blackboard explaining how simple it was and telling him to "hurry up and get it". Lynds says that, unlike some others, Prof. Grigson was still encouraging and would always make time to talk to him, even taking him into the staff cafeteria so they could continue talking physics.
Like another now retired initial contact, the Australian philosopher of science and internationally respected authority on time, Jack Smart, who would write Lynds "long thoughtful letters", they have since become friends, and Prof. Grigson follows Lynds' progress with great interest. "Academia needs more Chris Grigsons and Jack Smarts", said Lynds. Although still controversial, judging by the response it has already received from some of science's leading lights, Lynds' work seems likely to establish him as a groundbreaking figure in respect to increasing our understanding of time in physics. It also seems likely to make his surname instantly associable with Zeno's paradoxes and their remarkably improbable solution almost 2500 years later.
Lynds' plans for the near future the publication of a paper on Zeno's paradoxes by themselves in the journal Philosophy of Science, and a paper relating time to consciousness. He also plans to explore his work further in connection to quantum mechanics and is hopeful others will do the same.
Well, you really need to read the paper itself I would imagine. Even then it might not make much sense, at least at first. Most quantum mechanics literature is also pretty obtuse. I recently attended some internal corporate "classes", really more like a seminar, on some aspects of QM, and I'll freely admit that while I could follow the math, kinda sorta, the whole thing didn't make much sense to me either.
It's been mainstream. This guy just missed it like the one reviewer that rejected his paper said. He doesn't have a grasp of limits, calculus as the reviewer mentioned. The series of "half the times left" converges to the time it takes for the arrow to get there, because the remaining terms added in are essentially zero.
Of course time doesn't flow, time is a dimentional coordinate. All that matters are time differences measured with the appropriate references.
The universe seems unaltered to me!
Well, sure the universe is unaltered. But it helps to recall the effects of another theory -- relativity -- which also represented a demise of some mathematico-physic concepts.
If this analysis of (non-existent) time and motion is correct, it's likely to result in some really strange and interesting stuff.
An instant is a point on the time coordinate axis. dt is the limit as delta t ->0. All that matters is time differences, that's why dt is used. dt is not equal to zero, but represents an infinitesimally small delta t.
Time is a dimension. The points on it's axis are instants. Points are infinitesimally small as is dt, a time difference. Instants are not mathematical artifact. These are concepts that enable the mind to grasp reality. The points <=> instants are representations and names for well defined concepts, not the actual reality.
Zeno's paradox is only a paradox, because it fails to recognize the fact that the series of "1/2 times" converges to the time it takes the arrow to hit the line. All the other terms amount to adding essentially zero magnitude corrections beyond the appropriate significant figures. So it's Zeno's concepts that don't represent reality, not the math guys.
That's right, and also Peter Lynds "point." Points, like instants, are conceptual fictions, useful in geometry and mathematics as methods, but without onotological existence.
Ontologically, no segment of anything is "infinitesimal," which is the equivalent of zero. The calculus is nothing more than a clever scheme that allows division by zero, by pretending that zero is just an infinitely small fraction. Like the imaginary roots of negative numbers, the "infinitesimal" is a very useful method, but to conclude that these fictions have actual existence is madness, a common condition of hatters and mathematicians. It was mecury vapor that caused the condition in hatters, it is reification that causes the condition in mathematicians.
Hank
Garde la Foi, mes amis! Nous nous sommes les sauveurs de la République! Maintenant et Toujours!
(Keep the Faith, my friends! We are the saviors of the Republic! Now and Forever!)
LonePalm, le Républicain du verre cassé (The Broken Glass Republican)
Peter Lynds1
Time, Classical Mechanics, Quantum Mechanics, Indeterminacy, Discontinuity, Relativity, Cosmology, Imaginary Time, Chronons, Zeno's Paradoxes.
It is postulated there is not a precise static instant in time underlying a dynamical physical process at which the relative position of a body in relative motion or a specific physical magnitude would theoretically be precisely determined. It is concluded it is exactly because of this that time (relative interval as indicated by a clock) and the continuity of a physical process is possible, with there being a necessary trade off of all precisely determined physical values at a time, for their continuity through time. This explanation is also shown to be the correct solution to the motion and infinity paradoxes, excluding the Stadium, originally conceived by the ancient Greek mathematician Zeno of Elea. Quantum Cosmology, Imaginary Time and Chronons are also then discussed, with the latter two appearing to be superseded on a theoretical basis.
1. Introduction
Time enters mechanics as a measure of interval, relative to the clock completing the measurement. Conversely, although it is generally not realized, in all cases a time value indicates an interval of time, rather than a precise static instant in time at which the relative position of a body in relative motion or a specific physical magnitude would theoretically be precisely determined. For example, if two separate events are measured to take place at either 1 hour or 10.00 seconds, these two values indicate the events occurred during the time intervals of 1 and 1.99999.hours and 10.00 and 10.0099999.seconds, respectively.
If a time measurement is made smaller and more accurate, the value comes closer to an accurate measure of an interval in time and the corresponding parameter and boundary of a specific physical magnitudes potential measurement during that interval, whether it be relative position, momentum, energy or other. Regardless of how small and accurate the value is made however, it cannot indicate a precise static instant in time at which a value would theoretically be precisely determined, because there is not a precise static instant in time underlying a dynamical physical process. If there were, all physical continuity, including motion and variation in all physical magnitudes would not be possible, as they would be frozen static at that precise instant, remaining that way. Subsequently, at no time is the relative position of a body in relative motion or a physical magnitude precisely determined, whether during a measured time interval, however small, or at a precise static instant in time, as at no time is it not constantly changing and undetermined. Thus, it is exactly due to there not being a precise static instant in time underlying a dynamical physical process, and the relative motion of body in relative motion or a physical magnitude not being precisely determined at any time, that motion and variation in physical magnitudes is possible: there is a necessary trade off of all precisely determined physical values at a time, for their continuity through time.
In the present report this simple but very counter-intuitive conclusion is developed and explored in further detail and its general implications have important significance to time and its relationship to classical and quantum mechanics, while also providing an insight into the reason and purpose for indeterminacy and uncertainty in nature. An overview of the main theoretical results reported, presented in the numerical order in which they later appear follows: (3) A body (micro and macroscopic) in relative motion does not have a precisely determined relative position at any time, and all physical magnitudes are not precisely determined at any time, although with the parameter and boundary of their respective position and magnitude being determinable up to the limits of possible measurement as stated by the general quantum hypothesis and Heisenberg.s uncertainty principle(1), but with this indeterminacy in precise value not being a consequence of h and quantum uncertainty. This illustrates that in relation to indeterminacy in precise physical magnitude, the micro and macroscopic are inextricably linked, both being a part of the same parcel, rather than just a case of the former underlying and contributing to the latter. (3.1)
The explanation provided is then also shown to be the correct solution to the motion and infinity paradoxes, excluding the Stadium, originally conceived by the ancient Greek mathematician Zeno of Elea. (4) It is not necessary for time to "emerge" and "congeal" out of the "quantum foam" and highly
1 C/- 21 Oak Avenue, Paremata, Wellington, New Zealand. Email: PeterLynds@xtra.co.nz 2
contorted space-time geometry's present preceding Planck scale (Gh/c3)1/2 just after the big bang (new inflationary model), as has often previously been tentatively hypothesized.(2-7)
Continuity would be present and naturally inherent in practically all initial quantum states and configurations, rather than a specific few, or special one, regardless of how microscopic the scale. (4.1) Furthermore, the cosmological proposal of "Imaginary Time",(2, 3, 5-7) is not compatible with a consistent physical description, both, as a consequence of the above consideration, and secondly, because it is the relative order of events that is relevant, not the direction of time itself. <>As a consequence, it is not possible for the order of a sequence of events to be imaginary (at right angles) relative to another sequence of events. (5) Lastly, "Chronons", proposed particles of indivisible intervals of time,(2, 8) also appear to be superseded on a theoretical basis, as their possible existence is incompatible with the simple conclusion that the very reason physical continuity is possible in the first instance is due to there not being a quantum or atom of time.
Before proceeding further however, I think it is important to stress that although I have attempted to be as quantitative and rigorous as possible, the subject of time does not readily lend itself to such a description, particularly in the context in which it is treated here, and readers may initially find that they will need to really grapple with the contents before they are able to achieve a clear and genuine understanding. I apologize for this, but I can find no other way of conveying the same information and laying the initial foundations for the physics that subsequently follow, of which, in relation to importance, I consider to quite easily outweigh any undesirable, although unavoidable and necessary aspects of this paper.
2 . Motion and Continuity
We begin by considering the simple and innocuous postulate: 'there is not a precise static instant in time underlying a dynamical physical process'. If there were, the relative position of a body in relative motion or a specific physical magnitude, although precisely determined at such a precise static instant, would also by way of logical necessity be frozen static at that precise static instant. Furthermore, events and all physical magnitudes would remain frozen static, as such a precise static instant in time would remain frozen static at the same precise static instant.
(Incidentally, the same outcome would also result if such a precise static instant were hypothetically followed by a continuous sequence of further precise static instants in time, as by their very nature a precise static instant in time does not have duration over interval in time, so neither could a further succession of them. This scenario is not plausible however in the first instance, as the notion of a continuous progression of precise static instants in time is obviously not possible for the same reason). Rather than facilitating motion and physical continuity, this would perpetuate a constant precise static instant in time, and as is the very nature of this ethereal notion i.e. a physical process frozen static at an 'instant', as though stuck on pause or freeze frame on a motion screen, physical continuity is not possible if such a discontinuous chronological feature is an intrinsic and inherent property of a dynamical physical process, and as such, a meaningful (and actual physical) indicator of a time at which the relative position of a body in relative motion or a certain physical magnitude is precisely determined, as has historically been assumed. That is, it is the human observer who subjectively projects, imposes and assigns a precise instant in time upon a physical process, for example, in order to gain a meaningful subjective picture or 'mental snapshot' of the relative position of a body in relative motion.
As a natural consequence of this, if there is not a precise static instant in time underlying a dynamical physical process, there is no physical progression or flow of time, as without a continuous and chronological progression through definite indivisible instants of time over an extended interval in time, there can be no progression. This may seem somewhat counter-intuitive, but it is exactly what is required by nature to enable time (relative interval as indicated by a clock), motion and the continuity of a physical process to be possible. Intuition also seems to suggest that if there were not a physical progression of time, the entire universe would be frozen motionless at an instant, again as though stuck on pause on a motion screen. But if the universe were frozen static at such a static instant, this would be a precise static instant of time: time would be a physical quantity. Thus, it is then due to natures very exclusion of a time as a fundamental physical quantity, that time as it is measured in physics (relative interval), and as such, motion and physical continuity are indeed possible.
It might also be argued in a more philosophical sense that a general definition of static would entitle a certain physical magnitude as being unchanging for an extended interval of time. But if this is so, how then could time itself be said to be frozen static at a precise instant if to do so also demands it must be 3 unchanging for an extended interval of time? As a general and sensible definition this is no doubt correct, as we live in a world where indeed there is interval in time, and so for a certain physical magnitude to be static and unchanging it would naturally also have to remain so for an extended duration, however short.
There is something of a paradox here however. If there were a precise static instant underlying a dynamical physical process, everything, including clocks and watches would also be frozen static and discontinuous, and as such, interval in time would not be possible either. There could be no interval in time for a certain physical magnitude to remain unchanging. Thus this general definition of static breaks down when the notion of static is applied to time itself.
We are so then forced to search for a revised definition of static for this special temporal case. This is done by qualifying the use of stasis in this particular circumstance by noting static and unchanging, with static and unchanging as not being over interval, as there could be no interval and nothing could change in the first instance. At the same time however, it should also be enough just to be able to recognize and acknowledge the fault and paradox in the definition when applied to time.
It might also be argued by analogy with the claim by some people that the so-called 'block universe model., i.e. a 4-dimensional model of physical reality, incorporating time as well as space, is static or unchanging. This claim however involves the common mistake of failing to recognize that unless there is another time dimension, it simply doesn't make sense to say that the block universe is static, for there is no 'external' time interval over which it remains the same.
If we then apply the same line of reasoning to the hypothetical case being discussed presently, we could say: It doesn't make sense to say that everything would be static at an instant, (with physical continuity and interval in time not being possible), as there would be no time interval for such an assertion to be relative to, referenced from, or over which such an instant would remain the same etc. This objection is valid. However, as it applies to the hypothetical case under investigation, it should also be clear that it is not any more applicable or relevant than being a semantical problem of the words one employs to best try to put across a point and as being a contradiction in terms, rather than pertaining to any contradiction in the actual (in this case, hypothetical) physics involved. One could certainly also assert that there were no interval in time, and so if one wishes, there were a precise static instant underlying a physical process, without it being dependent on there actually being interval: as is the case with the hypothetical absence of mass and energy, and the resulting absence of 3 spatial dimensions.
It is also important to note this conclusion is compatible with the dynamical manner in which time enters the equations, geometry and description of the universe in Albert Einstein's theories, special and general relativity.(9) It is relative interval as measured by all clocks (whether digital, atomic, light, biological or other) that is warped and mutable at relativistic velocities and in the spatial vicinity of gravity, not any physical progression of time. Indeed, it could be said it is due to there not being a physical instant and physical progression of time, that the continuity, propagation and constant relative velocity of electromagnetic radiation, and thus, a warping of relative duration is possible in the first instance. Subsequently, this conclusion is also consistent and compatible with Minkowski space-time: time as a dimensional representation applies to the universe: the universe is not in time. Likewise, space is in the universe: the universe is not in a region of space. Time (the dimension) takes space, and space (the dimensions) take time, and space-time is independent and unaffected by the absence of a physical instant and physical progression of time. To the contrary, as many readers will be aware, Minkowski space-time also illustrates time to be a derivative notion, not actually "flowing" as our subjective conscious perceptions often seem to suggest.
3. Time and Classical and Quantum Mechanics: Indeterminacy vs. Discontinuity
The absence of a precise static instant in time underlying a dynamical physical process means that a body (micro and macroscopic) in relative motion does not have a precisely determined relative position at any time, and that all physical magnitudes are not precisely determined at any time, although with the parameter and boundary of their respective position and magnitude being determinable up to the limits of possible measurement as stated by the quantum hypothesis(1), but with this indeterminacy in precise value not being a consequence of h and quantum uncertainty. The reason why can be demonstrated by employing Albert Einstein.s famous 1905 train and the other theoretical device it is associated with, the thought experiment. An observer is watching a train traveling by containing a young Albert Einstein. At any given time as measured by a clock held by the observer, Einstein.s train is in motion. If the observer measures the train to pass a precisely designated point on the track at 10.00 seconds, this value indicates 4 the train passes this point during the measured time interval of 10.00 and 10.00999.seconds. As Einstein.s train is in motion at all measured times, regardless of how great or small its velocity and how small the measured time interval (i.e. 10.0000000-10.0000000999...seconds), Einstein.s train does not have a precisely determined relative position to the track at any time, because it is not stationary at any time while in motion, for to have a precisely determined relative position at any time, the train would also need to be stationary relative to the track at that time. Conversely, the train does not have a precisely determined relative position at an ethereal precise static instant in time, because there is not a precise static instant in time underlying the train's motion. If there were, Einstein.s trains motion would not be possible.
As the time interval measurement is made smaller and more accurate, the corresponding position the train can be said to 'occupy' during that interval can also be made smaller and more accurate. Momentarily forgetting LP, TP and time keeping restrictions, these measurements could hypothetically be made almost infinitesimally small, but the train does not have a precisely determined position at any time as it is in motion at all times, regardless of how small the time interval. For example, at 100km/hr, during the interval of 10.25s Einstein's train traverses the distance of 2.7-21cm. Thus, it is exactly due to the train not having a precisely determined relative position to the track at any time, whether during a time interval, however small, or at a precise static instant in time, that enables Einstein.s train to be in motion. Moreover, this is not associated with the preciseness of the measurement, a question of re-normalizing infinitesimals or the result of quantum uncertainty, as the trains precise relative position is not to be gained by applying infinitely small measurements, nor is it smeared away by quantum considerations. It simply does not have one. There is a very significant and important difference.
If a photograph is taken (or any other method is employed) to provide a precise measurement of the trains relative position to the track, in this case it does appear to have a precisely determined relative position to the track in the picture, and although it may also be an extremely accurate measure of the time interval during which the train passes this position or a designated point on the track, the imposed time measurement itself is in a sense arbitrary (i.e. 0.000000001 second, 1 second, 1 hour etc), as it is impossible to provide a time at which the train is precisely in such a position, as it is not precisely in that or any other precise position at any time. If it were, Einstein.s train would not, and could not be in motion.
On a microscopic scale, due to inherent molecular, atomic and subatomic motion and resulting kinetic energy, the particles that constitute the photograph, the train, the tracks, the light radiation that propagates from the train to the camera, as well as any measuring apparatus e.g. electron microscope, clock, yardstick etc, also do not have precisely determined relative position.s at any time.
Naturally, bodies at rest in a given inertial reference frame, which are not constituted by further smaller particles in relative motion, have a precisely defined relative position at all measured times. However, as this hypothetical special case is relevant to only indivisible and the most fundamental of particles, whose existence as independent .massive. objects is presently discredited by quantum physics and the intrinsic 'smearing' effects of wave-particle duality and quantum entanglement, if consistent with these considerations, this special subatomic case would not appear to be applicable.
Furthermore, and crucially, as we shall see shortly, because once granted indeterminacy in precise relative position of a body in relative motion, also subsequently means indeterminacy in all precise physical magnitudes, including gravity, this also applies to the very structure of space-time, the dynamic framework in which all inertial spatial and temporal judgments of relative position are based. As such, the previously mentioned possible special case, isn.t actually one, and the very same applies.
Consequently, the absence of a precise static instant in time underlying a dynamical physical process and the resulting lack of a precisely determined relative position at all times, but with the parameter and boundary of the position 'occupied' being determinable up to the limits of the time interval and the corresponding position measurement, similarly applies to all physical magnitudes and values at all times: if displacement (relative position) d of a body in relative motion is not precisely determined at time t, neither is a velocity v=dx/dt, so neither is momentum p=mv, acceleration a=dv/dt, g, all rotational and angular kinematic magnitudes e.g. angular momentum, L=Iw etc, wave speed c, frequency , wavelength ë, period T, kinetic energy Ek=1/2mv2, Schrodinger.s wave equation (- h 2/2m . 2+v) ø=ih . ø/.t, current I=Qt, and so, charge Q=I/t, voltage V=E/Q etc, time dilation t=ãto, length contraction L=Lo/ã, relativistic mass and relativistic momentum p=ãmv. Likewise, if p is not precisely determined, neither is de Broglie.s matter wave ë=h/p. If Ek, relativistic mass and c are not precisely determined, according to E=mc2, neither is rest mass and energy. If . is not precisely determined, neither is radiation energy per quantum E=h.. If m, a and r are not precisely determined, neither is Newton.s universal gravitation F=G 5 (M1m2/r2), force F=ma, so neither is pressure p=F/A, electric field strength E=F/Q, impulse F.t=m.v, torque T=Fx, work W=Fs, Fd, so neither is power P=W/t, E/t, Fv, VI etc. If m, g and relative position h are not precisely determined, neither is gravitational potential energy Ep=mgh, and in conjunction with ., according to Einstein.s general theory of relativity, neither is a precise interval of time as indicated by a clock under the influence of gravity, relative to another clock. Moreover, if v, ., E and m are not precisely determined, neither is any physical magnitude, and as this includes gravity, this also applies to the very structure of space-time. Crucially however, this universal indeterminacy in precise physical magnitude is not a consequence of h and quantum uncertainty.
3.1 Newton and Zeno of Elea's Motion and Infinity Paradoxes
The only situation in which a physical magnitude would be precisely determined was if there were a precise static instant in time underlying a dynamical physical process and as a consequence a physical system were frozen static at that instant. In such a system an indivisible mathematical time value, e.g. 2s, would correctly represent a precise static instant in time, rather than an interval in time (as it is generally assumed to in the context of calculus, and traceable back to the likes of Galileo, and more specifically, Newton, thus guaranteeing absolute preciseness in theoretical calculations before the fact i.e. .d/.t=v). Fortunately this is not the case, as this static frame would include the entire universe. Moreover, the universe.s initial existence and progression through time would not be possible.
Thankfully, it seems nature has wisely traded certainty for continuity. 2
Another way to look at this is if a physical value were precisely determined at a precise instant in time, it could never change, as it would firstly have to proceed to another precise value. But before it could do this, it would firstly have to proceed to half of that value. But before it could do this, it would have to proceed to half of that value again, and so on, and so on, to infinitum. Thus, in this manner it can be demonstrated that if a physical value were precisely determined, it could never change. There is a necessary trade off of between certainty at a time, for continuity through time.
Please note that the explanation provided here and previously throughout this paper is also the correct solution to the motion and infinity paradoxes the Dichotomy, Achilles and the Tortoise, the Arrow, and their other more modern variations, originally conceived by the Greek mathematician, Zeno of Elea.(10) That is, they all have the same general solution through such reasoning as has been discussed here, and are not distinct and different problems requiring different and distinct proposed solutions as has historically been assumed. 3
3.2 A Consistent Classical and Quantum Mechanical Description
In relation to quantum mechanics then, this conclusion illustrates that the relationship between h, wave-particle duality, quantum entanglement etc, and the constant indeterminacy in all precise physical values due to the absence of a precise static instant in time, although indistinguishable for all practical purposes when quantifying the overall state of a physical system at a microscopic level, are in fact separate and distinct variables, playing quite separate and distinct roles. As such, a revised and seemingly more appropriate description is: all physical magnitudes are not ever precisely determined due to the absence of a precise static instant in time underlying a dynamically physical process, although with the parameter and boundary of the their respective value being determinable up to the limits of possible measurement as stated by the quantum hypothesis and Heisenberg.s uncertainty principle,(1) but with this indeterminacy in precise magnitude not being a consequence of h and quantum uncertainty. Following with the introduction of uncertainty and/or statistics in quantum values due to h, wave-particle duality, quantum entanglement etc. This illustrates that in relation to indeterminacy in precise physical magnitude, there is not a distinction between the large and macroscopic and the microscopic realm of quantum mechanics, in the sense that both, the micro and macroscopic, are directly subject to inherent indeterminacy, rather than just a case of the former underlying and contributing to the latter. In this regard, they are both actually a part of the same parcel, being inextricably linked.
2 Please note that there is obviously no fault in the actual mathematics here, but rather in the historical assumption underlying them regarding determined physical magnitudes at a time and/or instant.
3 For a detailed explanation of Zeno.s paradoxes and their resolution, please see, Lynds, P. Zeno.s Paradoxes: A Timely Solution. Presently under consideration with Philosophy of Science.
6 I would suggest that there is possibly much more to be gleaned from the connection between quantum physics and the inherent need for physical continuity, and even go as far to speculate that the dependent relationship may be the underlying explanation for quantum jumping and with static indivisible mathematical time values directly related to the process of quantum collapse. Time will tell.4
4. Time and Quantum Cosmology
Detailed calculations have been completed in the theoretical field of quantum cosmology in an attempt to elucidate how time may have .emerged. and .congealed. out of the .quantum foam. and highly contorted space-time geometry.s and chaotic conditions preceding Planck scale (Gh/c3)1/2 just after the big bang (new inflationary model).(2-7) More specifically, it has been tentatively hypothesized that it would require particularly special initial quantum configurations for the .crystallization. of time and the emergence of macroscopic (non-quantum) phenomena to be possible.(2-7) This conclusion however, illustrates that temporality wouldn.t need to .emerge. at all, but would be present and naturally inherent in practically all initial quantum states and configurations, rather than a specific few, or special one, and regardless of how microscopic the scale.
As soon as there is any magnitude of space (as a property of mass-energy), you naturally get the time dimension by default. If there is no mass-energy, there is no space-time. Because the reason continuity is possible is due to there not being a physical instant and physical progression of time, it is not necessary for time to .emerge. in the first instance. The more appropriate question remains: how can mass-energy, and as such, space-time emerge?, simultaneously bringing continuity with it due to the absence of a physical instant and physical progression of time, i.e. temporality or continuity would only be required to emerge from possible initial quantum configurations, states or histories in which time were a physical quantity.
4.1 Imaginary Time This conclusion is also not consistent with the cosmological proposal of "Imaginary Time" and "no boundary condition",(2, 3, 5-7) both, as a consequence of the above consideration, and secondly, because it is the relative order of events that is relevant, not the direction of time itself. It is not possible to assert using a model of the universe that includes a description of the sum over histories or path integrals of the actual structure of space-time, that time goes in any direction, let alone at 90 degrees to real time or linear time and takes on some of the properties, or is identical to that of spatial dimensions at approximately Planck scale (Gh/c3)1/2 ~ 10-33cm, 10-43s, while still being bounded by the big bang (or possible big crunch, in a now seemingly obsolete closed universe) singularities in real or linear time, but having no boundaries in imaginary time. Neither real nor imaginary time exist in a consistent physical description, as time does not go in any direction.
It is the relative order of events that is relevant, not the direction of time itself. The order of a sequence of events can take place in either one order relative to its reverse order, or in the reverse order, relative to the first. It is not possible for the order of a sequence of events to be imaginary in the mathematical sense as it is logically contradictory and meaningless to describe the order of a sequence of events as being at right angles relative to that of another sequence of events. The opposite to this could be posited for the
4 Considerations to do with time discontinuity presented in this paper also have relation to similar investigations performed in the framework of p-adic mathematical physics. By using p-adic numbers, instead of continuous real numbers, we can get models (with p-adic noncontinuous time) that have both classical and quantum features. Please refer to:
A. Y. Khrennikov, Non-Archimedean analysis:quantum paradoxes, dynamical systems and biological models. Kluwer Acad. Publishers, Dordreht, (1997). Especially Chapter 4. and pg. 164-166 on Heisenberg uncertainty relation.
S. Albeverio and A. Y. Khrennikov, Representation of the Weyl group in spaces of square integrable functions with respect to p-adic valued Gaussian distributions. J. of Phys. A, v. 29, pg. 5515-5527, (1996).
A. Y. Khrennikov, Ultrametric Hilbert space representation of quantum mechanics with a finite exactness. Found. of Physics, 26, No. 8, 1033-1054, (1996).
7 relative spatial direction of events, but events take place at right angles relative to others on a regular basis, and this has nothing to do with their direction, or the direction of time becoming imaginary.
The fact that imaginary numbers appear when computing space-time intervals and path integrals does not facilitate that when multiplied by i, that time intervals become basically identical to dimensions of space. Imaginary numbers show up in space-time intervals when space and time separations are combined at near the speed of light, and spatial separations are small relative to time intervals. What this illustrates is that although space and time are interwoven in Minkowski space-time, and time is the fourth dimension, time is not a spatial dimension: time is always time, and space is always space, as those i.s keep showing us. There is always a difference. If there is any degree of space, regardless of how microscopic, there would appear to be inherent continuity i.e. interval in time.
5. Chronons
"Chronons", proposed theoretical particles or atoms of indivisible intervals of time,(2, 8) are also not compatible with a consistent physical description. There is not a need for quantum or atomic indivisible time operators to stitch microscopic events together to facilitate physical continuity, as this overall conclusion illustrates that the very reason events are continuous in the first instance is due to there not being an atom or quantum of time. Simply, if there were, physical continuity, motion and time (relative interval) would not be possible.
6. Conclusion
In summary, it was shown there is a necessary trade off of all precisely determined physical magnitudes and values at a time, for their continuity through time, although with the parameter and boundary of their respective magnitude and value being determinable up to the limits of possible measurement as described by the quantum hypothesis,(1) but with this indeterminacy in precise value not being a consequence of h and quantum uncertainty. This illustrated that in relation to indeterminacy in precise physical magnitude, the macro and microscopic are inextricably linked, rather than being a variable only directly associated with the quantum world. The explanation provided was also shown to be the correct solution to the motion and infinity paradoxes, excluding the Stadium, originally conceived by the ancient Greek mathematician, Zeno of Elea.(9) It is not necessary for time to .emerge. from the .quantum foam. present just after the big bang at approximately (Gh/c3)1/2 scale,(2-7) and the proposals of "Imaginary Time",(2, 3, 5-7) and "Chronons",(2, 8) have been shown to be incompatible with a consistent physical description, and would appear to be superseded on a theoretical basis.
Conversations and correspondence with, and encouraging words received from J. A. Wheeler of Princeton, J. J. C. Smart and H. Price of Australia, C. Grigson of New Zealand, A. P. French of MIT, and W. B. Yigitoz of Canada, as well as from the two very helpful unanimous referees of this paper, are most gratefully acknowledged.
References
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4. H. D. Zeh, The Physical Basis of the Direction of Time. Springer-Verlag. Berlin, 1989.
5. J. B. Hartle and S. W. Hawking, Wave function of the universe. Phys. Rev, D28, 2960, (1983). 6. S. W. Hawking, Black holes and baby universes. Bantam Press, UK, (1993).
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