Capra, Zukov, Gribbin are all over 80+ years old now…

Gary Zukov was in his late thirties when he wrote his Dancing Wu Li Masters. It further built on Fritjov Capra’s Tao of Physics. Both Zukov and Capra are still alive: 80+ years now. Both books still sell well, just like John Gribbin’s In Search of Schrödinger’s cat. I quote from Amazon’s sales headline for the latter:

“Quantum theory is so shocking that Einstein could not bring himself to accept it. It is so important that it provides the fundamental underpinning of all modern sciences. Without it, we’d have no nuclear power or nuclear weapons, no TV, no computers, no science of molecular biology, no understanding of DNA, no genetic engineering.”

Einstein could not bring himself to accept it, right? And TV or nuclear power or molecular biology would never have seen the light without Bohr and Heisenberg taking over from Einstein, Lorentz, or de Broglie, right? […] Plain nonsense. Einstein’s revolution is over. It is about time the likes of Zukov, Capra, Gribbin and their contemporaries – Hossenfelder, Lee Smolin, Sean Carroll, etcetera – accept it: Einstein was right along, and accusing Einstein of not having an open mind – he pioneered the true bedrock of physics: relativity theory, didn’t he? – sounds nuts to me.[1]

I am wondering if a book like the one I am thinking of – some kind of exchange between the wisdom that generations hand over – would ever make for a bestseller. Probably not. In any case, I want to write the first pages of such a book here.

Fields, charge, and energy concepts

Papa, I understand your particle theory now. It explains the diffraction pattern on the detector plate when you send electrons through a slit. I can also see why this two-slit interference pattern is just a superposition of two one-slit diffraction patterns. No mystery. Agreed. But photons?

What do you mean?

Your explanation of electron interference does away with interference. It explains this arriving of one electron – arriving as the lump it always one – when going through a slit or past the edge of a far more massive and complicated structure or system of charged oscillations. But in the one-photon Mach-Zehnder experiment – or when measuring radio signal strengths at a distance – we have photons – or half-photons (the linear components of circularly polarized photons – I am just quoting your own theory here) – coming together and vanishing (destructive interference) or – quite the opposite – combining into some new photon with twice the energy of the incoming full- or half-photons?

You are now fully grown up – a promising young adolescent with an MD degree – and so you should think for yourself now. The dominating Copenhagen interpretation of quantum mechanics tells us that Nature is just some kind of black box, and the best we can do is to think of some input-output relations to describe what goes in and what comes out. I have been fighting on many fronts, and I first wanted to get my matter-particle model right. I should now go back to these experiments demonstrating how light interference might or might not work. They all involve an apparatus which is referred to as an interferometer. There are various types around, but the Michelson-Morley interferometer still describes the basic components. We have a light source, some mirrors and one or more beam splitters – which are, basically, still simple half-silvered mirrors. The beam splitter splits the beam, and the mirrors are then adjusted so as to produce constructive or destructive interference.

The classical explanation is easy enough: the two beams arrive in phase or, alternatively, out of phase and we, therefore, have constructive or destructive interference when recombining them. However, when we want to analyze this in terms of one single photon, this classical picture becomes quite complicated. Physicists will tell you the photon cannot actually split itself, and they will start talking about amplitudes – based on which they will calculate probabilities of this or that happening – but they will never explain what is actually happening.

I always told you it should be possible to develop a classical picture of all of this, and that classical picture of what is happening in terms of photons would be pretty much like what is shown below. Photons arrive in lumps too, but a circularly polarized photon can be split into two linearly polarized half-photons – just like an electromagnetic wave that is circularly polarized. There is no mystery: the wave components – linear or circularly polarized photons – have the same properties as the wave. 😊

Papa, I do not get the recombination stuff when we are talking photons. Where is the energy going? These idealized experiments show that we always get a recombined beam with the same frequency – or one that vanishes – but, according to classical theory, we must have in-between realities. When the phase difference between the two incoming beams is small, its amplitude is going to be much larger. To be precise, it is going to be twice the amplitude of the incoming beams for Δ = 0. In contrast, if the two beams are out of phase, the amplitude is going to be much smaller, and it is going to be zero if the two waves are 180 degrees out of phase (Δ = π), as shown below. That does not make sense because twice the amplitude means four times the energy, and zero amplitude means zero energy. The energy conservation law is being violated: photons are being multiplied or, conversely, are being destroyed.

Darling, you must remember light-particles are fundamentally different from matter-particles. There is no kinetic energy: no physical charge in a weird dance. Field energy is like the field itself: we are talking a force without a charge to act upon. The superposition principle in physics applies to fields in a very different way than it applies to charged particles. Bose-Einstein versus Fermi-Dirac statistics. Photons – light-particles in general – ‘occupy’ space very differently than matter-particles: they can literally be on top of each other if they are all in phase or – conversely – out of phase. In the first case, they combine to produce twice the energy. Because photon frequencies and amplitudes do not change, it looks like the number of photons must double. Conversely, field energies combine to make photons with opposite phase vanish into nothing. It is a weird thing, perhaps – but it makes sense to me. All that I know is that we should not substitute this coherent world view for the guru-like models that have been perpetuated by Heisenberg and Bohr. [I explicitly exclude Born, because I think his interpretation of the wavefunction as a hardcore probability distribution function based on energy densities made sense.]

You should read Lamb’s Anti-Photon article once more. It has (almost) all of the answers. Fields exchange energy with matter-particles in quantized units only. It is all very marvelous but not mysterious.[2]

Are fields potential energy?

Not quite. The physical dimension of an electric or magnetic field, a potential, energy itself (kinetic or potential energy), are all different, and you need to keep track of those dimensions when analyzing interference or how the superposition principle comes into play. But I would be rewriting a lot of what I wrote already to convey the deeper understanding you need.

Fritjov Capra started off the right footing when he wrote out his motivation: “Science does not need mysticism and mysticism does not need science. But man needs both.” That is about all we have in common. Too bad he didn’t do more with it. But modern-day physicists do not do much more, either.

What do you mean?

Einstein never got a Nobel Prize for his relativity theory. This Stockholm Royal Academy of Sciences makes weird decisions. Just last year, they gave a Nobel Prize to a climate change denier. There is something rotten in academia, but it will take a while before academia (or the Stockholm Royal Academy of Sciences) recognizes that. In the meanwhile, Alfred Nobel must be turning around in his grave. I cannot imagine Einstein would worry about it. 😊

Brussels, 12 September 2023

[1] I warmly recommend reading Einstein’s articles directly. His 1905 article on special relativity theory toys and plays with ideas (such as the idea of an electron having some lateral mass in its motion – which I subscribe to: too bad Einstein did not explore Schrödinger’s Zitterbewegung hypothesis) like no one else can. Accusing Einstein of a lack of imagination – which is what is implied here – is utterly nonsensical.

[2] Pages 148-153 of my manuscript have the basic explanation of one-photon Mach-Zehnder interference. Go have a look. I should write it all out, but I was born lazy. 😊

The End of Physics

I wrote a post with this title already, but this time I mean it in a rather personal way: my last paper – with the same title – on ResearchGate sums up rather well whatever I achieved, and also whatever I did not explore any further because time and energy are lacking: I must pay more attention to my day job nowadays. 🙂

I am happy with the RG score all of my writing generated, the rare but heartfelt compliments I got from researchers with far more credentials than myself (such as, for example, Dr. Emmanouil Markoulakis of Nikolaos, which led me to put a paper on RG with a classical explanation of the Lamb shift), various friendly but not necessarily always agreeing commentators (one of them commenting here on this post: a good man!), and, yes, the interaction on my YouTube channel. But so… Well… That is it, then! 🙂

As a farewell, I will just quote from the mentioned paper – The End of Physics (only as a science, of course) – hereunder, and I hope that will help you to do what all great scientists would want you to do, and that is to think things through for yourself. 🙂

Brussels, 22 July 2023

Bohr, Heisenberg, and other famous quantum physicists – think of Richard Feynman, John Stewart Bell, Murray Gell-Mann, and quite a few other Nobel Prize winning theorists[1] – have led us astray. They swapped a rational world view – based on classical electromagnetic theory and statistical determinism – for a mystery world in which anything is possible, but nothing is real.

They invented ‘spooky action at a distance’ (as Einstein derogatorily referred to it), for example. So, what actually explains that long-distance interaction, then? It is quite simple. There is no interaction, and so there is nothing spooky or imaginary or unreal about it: if by measuring the spin state of one photon, we also know the spin state of its twin far away, then it is – quite simply – because physical quantities such as energy and momentum (linear or angular) will be conserved if no other interference is there after the two matter- or light-particles were separated.

Plain conservation laws explain many other things that are being described as ‘plain mysteries’ in quantum physics. The truth is this: there are no miracles or mysteries: everything has a physical cause and can be explained.[2] For example, there is also nothing mysterious about the interference pattern and the trajectory of an electron going through a slit, or one of two nearby slits. An electron is pointlike, but it is not infinitesimally small: it has an internal structure which explains its wave-like properties. Likewise, Mach-Zehnder one-photon interference can easily be explained when thinking of its polarization structure: a circularly polarized photon can be split in two linearly polarized electromagnetic waves, which are photons in their own right. Everything that you have been reading about mainstream quantum physics is, perhaps, not wrong, but it is highly misleading because it is all couched in guru language and mathematical gibberish.

Why is that mainstream physicists keep covering up? I am not sure: it is a strange mix of historical accident and, most probably, the human desire to be original or special, or the need to mobilize money for so-called fundamental research. I also suspect there is a rather deceitful intention to hide truths about what nuclear science should be all about, and that is to understand the enormous energies packed into elementary particles.[3]

The worst of all is that none of the explanations in mainstream quantum physics actually works: mainstream theory does not have a sound theory of signal propagation, for example (click the link to my paper on that or – better, perhaps – this link to our paper on signal propagation), and Schrödinger’s hydrogen model is a model of a hypothetical atom modelling orbitals of equally hypothetical zero-spin electron pairs. Zero-spin electrons do not exist, and real-life hydrogen only has one proton at its center, and one electron orbiting around it. Schrödinger’s equation is relativistically correct – even if all mainstream physicists think it is not – but the equation includes two mistakes that cancel each other out: it confuses the effective mass of an electron in motion with its total mass[4], and the 1/2 factor which is introduced by the m = 2m_eff substitution also takes care of the doubling of the potential that is needed to make the electron orbitals come out alright.

The worst thing of all is that mainstream quantum physicists never accurately modeled what they should have modeled: the hydrogen atom as a system of a real proton and a real electron (no hypothetical infinitesimally and structureless spin-zero particles). If they had done that, they would also be able to explain why hydrogen atoms come in molecular H₂ pairs, and they would have a better theory of why two protons need a neutron to hold together in a helium nucleus. Moreover, they would have been able to explain what a neutron actually is.[5]

[1] James Stewart Bell was nominated for a Nobel Prize, but died from a brain hemorrhage before he could accept the prize for his theorem.

[2] The world of physics – at the micro-scale – is already fascinating enough: why should we invent mysteries?

[3] We do not think these energies can be exploited any time soon. Even nuclear energy is just binding energy between protons and neutrons: a nuclear bomb does not release the energy that is packed into protons. These elementary particles survive the blast: they are the true ‘atoms’ of this world (in the Greek sense of ‘a-tom’, which means indivisible).

[4] Mass is a measure of the inertia to a change in the state of motion of an oscillating charge. We showed how this works by explaining Einstein’s mass-energy equivalence relation and clearly distinguishing the kinetic and potential energy of an electron. Feynman first models an electron in motion correctly, with an equally correct interpretation of the effective mass of an electron in motion, but then substitutes this effective mass by half the electron mass (m_eff = m/2) in an erroneous reasoning process based on the non-relativistic kinetic energy concept. The latter reasoning also leads to the widespread misconception that Schrödinger’s equation would not be relativistically correct (see the Annexes to my paper on the matter-wave). For the trick it has to do, Schrödinger’s wave equation is correct – and then I mean also relativistically correct. 🙂

[5] A neutron is unstable outside of its nucleus. We, therefore, think it acts as the glue between protons, and it must be a composite particle.

The self-appointed science gurus

Sean Carroll recently tweeted this:

Sean Caroll

I could ‘t help giving him a straight answer. I actually like Sean Carroll, but I hate how he and others – think of John Gribbins, for example – self-appoint themselves as the only ‘gurus’ who are entitled to say something about grand theories or other ‘big ideas’: everyone else (read: all non-believers in QFT) are casually dismissed as ‘crackpot scientists’.

In fact, a few weeks before he had sent out a tweet promoting his ideas on the next ‘big ideas’, so I couldn’t help reminding him of the tweet above. 🙂

Sean Caroll next tweet

This is funny, and then it isn’t. The facts are this:

The ‘new physics’ – the quantum revolution – started almost 100 years ago but doesn’t answer many fundamental questions (simply think about explaining spin and other intrinsic properties of matter-particles here).
Geniuses like Einstein, Lorentz, Dirac and even Bell had serious doubts about the approach.
Historical research shows theories and scientists were severely biased: see Dr. Consa’s review of quantum field theory in this regard.

I am very sorry, Dr. Carroll. You are much smarter than most – and surely much smarter than me – but here you show you are also plain arrogant. It’s this arrogance that has prevented a creative way out of the mess that fundamental physics finds itself in today. If you find yourself in a hole, stop digging !