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Should creationists accept quantum mechanics?

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First published: 25 Nov 2011; Last updated 26 Apr 2021

Spectrum rainbow
The spectrum in a rainbow
Credit: Wikipedia

Quantum mechanics is one of the brand new ideas to emerge in physics in the 20th century. But is it something creationists should believe? I argue “yes” for two reasons:

  1. The evidence supports it: QM solved problems that baffled classical physics, and has passed numerous scientific tests.
  2. Fighting against an operational science idea would mean fighting a battle on two fronts. So there is nothing to be gained by diverting our energies, in an area that does nothing to further the creation cause.

Although quantum mechanics is rather outside the scope of our ministry, since it concerns operational science rather than origins, we do receive questions about QM quite often. And we also sometimes receive requests to sponsor various critics of this field. This paper tries to summarize, with as little technical detail as possible, why QM was developed, the overwhelming evidence for it, as well as the lack of any viable alternative. Finally, the pragmatic issue: jumping on an anti-QM bandwagon would just make our job harder and provide not the least benefit to the creation cause.


Backdrop: Classical (Newtonian) physics

Sir Isaac Newton (1642/3–1727) was probably the greatest scientist of all time, discovering the spectrum of light as well as the laws of motion, gravity, and cooling; and also inventing the reflecting telescope and jointly inventing calculus. Yet he wrote more about the Bible than science, and was a creationist1 (and nothing discovered after Darwin would change that).2

Newton’s prowess in science was such that English poet Alexander Pope (1688–1744) wrote the famous epitaph:

The Creation/Fall/Flood is a historical framework taught by the Bible; classical physics is at best just a model to explain how God upholds His creation, not a direct teaching of Scripture. So disagreements with classical physics are in no way like the contradictions of biblical history by uniformitarian geologists and evolutionary biologists.

Nature and nature’s laws lay hid in night;

God said “Let Newton be” and all was light.

Such was his influence that Albert Michelson (1852–1931), the first American to win the Nobel Prize in physics, asserted:

The more important fundamental laws and facts of physical science have all been discovered, and these are so firmly established that the possibility of their ever being supplanted in consequence of new discoveries is exceedingly remote.3

Rather, all that remained, he thought, was more and more precise measurements. He quoted the creationist physicist William Thomson, 1st Baron Kelvin (1824–1907): “the future truths of physical science are to be looked for in the sixth place of decimals.”

Now such statements mainly produce mirth. Even Kelvin himself recognized two “dark clouds” hanging over classical physics, which known theories could not explain:

  1. The experiment of Michelson and Morley (1838–1923) that showed effectively no difference in the measured speed of light regardless of direction—to be solved by Einstein’s theory of special relativity, which is outside the scope of this article. Suffice it to say, Einstein made it clear that he deduced many of his ideas from the electromagnetism equations of the great James Clerk Maxwell, a great creationist classical physicist.4 Furthermore, Relativity hasn’t the slightest thing to do with moral relativism: Relativity replaces absolute time and space with another absolute: the speed of light in a vacuum. To underscore this point, Einstein himself preferred the term ‘Invariance Theory’. Finally, creationist physicist Dr Russell Humphreys showed that relativity was an ally of creation, not a foe, and most creationist physicists since then have agreed.
  2. Black body radiation, which as will be shown, was one of the mysteries to be solved by quantum mechanics.

Three clouds

Actually, there were three main problems that stumped Newtonian ‘classical’ physics, and quantum mechanics solved them. Despite what some claim, QM is totally unlike Darwinian evolution: QM was driven by unsolved problems and supported by the evidence, and not with any hidden agenda against a Creator. Furthermore, most of the pioneers were reluctant to abandon classical physics.

Another point which seems to be forgotten by some QM critics: the Creation/Fall/Flood is a historical framework taught by the Bible; classical physics is at best just a model to explain how God upholds His creation, not a direct teaching of Scripture. So disagreements with classical physics are in no way like the contradictions of biblical history by uniformitarian geologists and evolutionary biologists.

We also should notice how many of the discoveries that led to QM were rewarded with a Nobel Prize for Physics. By contrast, one gripe of evolutionists is the lack of an award for evolutionary biology;5 Nobel Prizes are awarded only for practical, testable science.6

1. Blackbody radiation

A blackbody is an idealized perfect absorber of all radiation, and as a consequence, is also a perfect emitter. The best approximation to this is a material called super-black, with tiny cavities, actually modeled on the wing rims of certain butterflies.7

Max Planck
Max Planck (1858–1947)

Classical physics predicted that the black body would be a ‘vibrator’ with certain modes, which had different frequencies. And it also predicted that every mode would have the same energy, proportional to temperature (called the Equipartition Theorem). The problem is that there would be more modes at short wavelengths, thus high frequencies, so these modes would have most of the energy. Classical physics led to the Rayleigh–Jeans Law,8 which stated that the energy emitted at a given frequency was proportional to the fourth power of that frequency.

This worked well for low frequencies, but predicted that the radiation would be more and more intense at higher frequencies, i.e. the ultraviolet region of the spectrum and beyond. In fact, it would tend towards infinite energy—clearly this is impossible, hence the term ‘ultraviolet catastrophe’.

Max Planck (1858–1947) solved this problem. Instead of the classical idea, that any mode of oscillation could have any energy, he proposed that they could have only discrete amounts—packets of energy proportional to the frequency. That is, E = hν, where E is energy, ν (Greek letter nu) is frequency, and h is now called Planck’s constant.9 This meant that a mode could not be activated unless it had this minimum amount of energy. The new Planck’s Law matched the observations extremely well at both high and low frequencies. He won the 1919 physics Nobel “in recognition of the services he rendered to the advancement of Physics by his discovery of energy quanta.”10

Actually, Planck himself was not thinking that he had solved a catastrophe, just that his idea fitted the data well. Rather, he rightly realized that the equipartition theorem was not applicable.11 Interestingly enough, he was sympathetic to Christianity and critical of atheism.12

2. Photo-electric effect

We all know about solar cells now, but over a century ago, the photo-electric effect behind them was a mystery. It was discovered that light could knock electrons out of a material, but the electron energy had nothing to do with intensity of the light, but rather with the frequency. Furthermore, light below a certain threshold frequency had no effect. Very curiously: bright red light (low-frequency) would not work, while faint ultraviolet light (high-frequency) would, even though the energy of the red light was far greater in such cases.

Einstein solved this by proposing that light itself was quantized: came in packets of energy:

According to the assumption to be contemplated here, when a light ray is spreading from a point, the energy is not distributed continuously over ever-increasing spaces, but consists of a finite number of energy quanta that are localized in points in space, move without dividing, and can be absorbed or generated only as a whole.13

Only if the energy packet were greater than the binding energy of the electron would it be emitted. The resulting electron energy would be the difference of the light packet energy and binding energy. So while Planck proposed quantized oscillators, Einstein proposed that electromagnetic radiation was quantized.

It was explicitly for this discovery, not relativity, that Einstein was awarded the 1921 Nobel Prize for Physics:

… for his services to Theoretical Physics, and especially for his discovery of the law of the photoelectric effect.14

Einstein called this Lichtquant or light quantum, but the American physical chemist Gilbert Newton Lewis (1875–1946) coined the term photon15 which stuck.

Ironically, like Planck, Einstein didn’t conceive himself as anything more than a classicist. He later vocally opposed the prevailing quantum mechanical interpretations by the Dane Niels Bohr (1885–1962), now called the Copenhagen Interpretation.

3. Atoms

Newton’s discoveries in the spectrum of light presumed that colour was continuous. But when the spectra of individual atoms were measured, they emitted light at discrete frequencies (or absorbed it—dark lines in a “white light” spectrum).

Furthermore, the New Zealander physicist Ernst Rutherford (1871–1937) showed that most of the mass of the atoms was concentrated in a tiny positively charged nucleus, and proposed that electrons orbited like the planets around the sun. The Rutherford model is iconic—it’s what most people imagine when they think of atoms, and is even used in the logo of the United States Atomic Energy Commission and the flag of the International Atomic Energy Agency. Rutherford inexplicably missed out on the Nobel Prize for Physics—instead, the Nobel Prize committee magically transformed him into a chemist, awarding him the Chemistry Prize instead, “for his investigations into the disintegration of the elements, and the chemistry of radioactive substances.”16

However, classical physics predicted that orbiting charged particles like electrons would lose energy to electromagnetic radiation. So their orbits would decay. This, of course, is not what is observed.

To solve this problem, Bohr proposed in 1913 that electrons could only move in discrete orbits, and that these orbits were stable indefinitely. Energy was gained or lost only when the electrons changed orbits, absorbing or emitting electromagnetic radiation—photons of frequency ν = E/h, where E is the energy difference between the states. For electrons in higher energy or ‘excited’ states, this transition would mostly be spontaneous.

Stimulated emission and lasers

In 1917, Einstein realized that a photon with the same energy as the energy difference could increase the probability of this transition.17 Such stimulated emission would produce another photon with the same energy, phase, polarization and direction of travel as the incident photon. This was the first paper to show that atomic transitions would obey simple statistical laws, so was very important for the development of QM. On the practical side, it is immensely valuable, because it is also the basis for masers and lasers. These words were acronyms for Microwave/Light Amplification by Stimulated Emission of Radiation. As a result:

The Nobel Prize in Physics 1964 was divided, one half awarded to Charles Hard Townes, the other half jointly to Nicolay Gennadiyevich Basov and Aleksandr Mikhailovich Prokhorov “for fundamental work in the field of quantum electronics, which has led to the construction of oscillators and amplifiers based on the maser-laser principle.”18

My own green laser pointer relies on an additional QM effect called “second harmonic generation” or “frequency doubling”. Here, two photons are absorbed in certain materials with non-linear optics, and a photon with the combined energy is emitted. In this case, an infrared source with a wavelength of 808 nm pumps an infrared laser with a lower energy of 1064 nm, and this frequency is doubled to produce a green laser beam of 532 nm.

Bohr mocel
Rutherford–Bohr model of the hydrogen atom. Credit: Wikipedia

Bohr’s model strictly applied only to one-electron atoms such as H, He+, Li2+ etc., but he extended it to multi-electron atoms. He proposed that these discrete energy levels could hold only a certain number of electrons—electron shells. This explains the relative inertness of the ‘noble gases’: they already have full shells, so no need to chemically react with another atom to achieve them. It also explains the highly reactive alkali metals: they have one electron over, so can lose it relatively easily to achieve the all-full shell configuration; and the halogens are one electron short, so vigorously try to acquire that one remaining electron from another atom. An illustration of both is the alkali metal halide sodium chloride.

High-school chemistry typically doesn’t go past the Bohr model approach. University chemistry tends to go deeper into more modern quantum mechanics (atomic and molecular orbital theory), of which the Bohr model was a pioneering attempt. Bohr won the physics Nobel in 1922 “for his services in the investigation of the structure of atoms and of the radiation emanating from them.”19

Like Heisenberg and Einstein, Bohr was not happy with aspects of quantum mechanics. In Bohr’s case, for a long time, he was a determined opponent of the existence of photons, trying to preserve continuity in electromagnetic radiation. Bohr also introduced the ‘correspondence principle’: that the new quantum theory must approach classical physics in its predictions when the quantum numbers are large (similarly, relativity theory collapses to ordinary Newtonian physics with velocities that are much smaller than that of light).

Wave-particle duality

The French historian-turned-physicist Louis-Victor-Pierre-Raymond, 7th duc de Broglie (1892–1987) provided another essential concept of quantum mechanics. Just as energy of vibrators and electromagnetic radiation was quantized into discrete packets with particle-like properties, de Broglie proposed that all moving particles had an associated wave-like nature. The wavelength was inversely proportional to momentum, again using Planck’s Constant: λ = h/p, where λ (Greek letter lambda) is wavelength, and p = momentum. This was the subject of his Ph.D. thesis in 1924.20 His own examiners didn’t know what to think, so they asked Einstein. Einstein was most impressed, so de Broglie was awarded his doctorate. Only five years later, he was awarded the Physics Nobel “for his discovery of the wave nature of electrons.”21

It is notable that this prize was awarded before the wave nature of electrons was proven. This happened beyond reasonable doubt when Clinton Joseph Davisson (1881–1958) and George Paget Thomson (1892 –1975) were awarded the 1937 Physics Nobel “for their experimental discovery [made independently of each other] of the diffraction of electrons by crystals.”22 Thomson was the son of J.J. Thomson (1856–1940), who discovered the electron itself. For example, electrons can produce the classic ‘double slit’ interference pattern of alternating ‘light’ and ‘dark’ bands. This pattern is produced even when only one electron goes through a slit at a time.

The discovery of matter waves was instrumental for electron microscopes. These allow smaller objects to be seen than optical microscopes, because the electrons have a smaller wavelength than visible light. The same principle is used for probing atomic arrangements with neutron diffraction—neutrons are almost 2,000 times more massive than electrons, so normally have much more momentum, thus an even smaller wavelength.

Thus de Broglie showed that at a foundational level, both radiation and matter behave as both waves and particles. Writing almost half a century later, he recalled:

When I conceived the first basic ideas of wave mechanics in 1923–24, I was guided by the aim to perform a real physical synthesis, valid for all particles, of the coexistence of the wave and of the corpuscular aspects that Einstein had introduced for photons in his theory of light quanta in 1905.23

But this unified theory did not permit wave and particle qualities to be observed at the same time; it was always one or the other.

Mathematical formulations

In 1925, Werner Heisenberg (1901–1976) formulated a mathematical model to explain the intensity of hydrogen spectral lines. He was then the assistant of Max Born (1882–1970), who recognized that matrix algebra would best explain Heisenberg’s work. Heisenberg was recognized with the 1932 physics Nobel for “for the creation of quantum mechanics, the application of which has, inter alia, led to the discovery of the allotropic forms of hydrogen.”24

The following year, Erwin Schrödinger (1887–1961) developed de Broglie’s ideas of matter waves into the eponymous Schrödinger equation. This describes a physical system in terms of the wavefunction (symbol ψ or Ψ—lower case and capital psi), and how it changes over time. For a system not changing over time, ‘standing wave’ solutions allow the calculation of the possible allowable stationary states and their energies. This brilliantly predicted the energy levels of the hydrogen atom. Later these stationary states were called atomic orbitals. Applied to molecules, they are molecular orbitals, without which much of modern chemistry would be impossible. Other applications of this equation included the calculation of molecular vibrational and rotational states.

Schrödinger’s treatment, as he showed, was equivalent to Heisenberg’s: the stationary states correspond to eigenstates, and the energies to eigenvalues (eigen is the German word for ‘own’ in the sense of ‘peculiar’ or ‘characteristic’). The overall wavefunction could be considered as a superposition of the eigenstates. As Einstein warmly embraced de Broglie’s idea, he did the same to Schrödinger’s, as a more ‘physical’ theory than Heisenberg’s matrices. In 1930, Paul Dirac (1902–1984) combined the two into a single mathematical treatment. Schrödinger and Dirac shared the 1933 Nobel Prize for Physics “for the discovery of new productive forms of atomic theory.”25

Schrödinger was another reluctant convert to QM—he hoped that his wave equation would avoid discontinuous quantum jumps. But he was due to be disappointed: in 1926, Max Born showed that Ψ didn’t have a physical nature; rather, the square of its magnitude |Ψ|2 (or Ψ*Ψ) is proportional to the probability of finding the particle localised in that place. For political reasons, with the developing turmoil of the rise of National Socialism in his country, Germany, Born wasn’t awarded the Nobel Prize for physics until 1954, a half share “for his fundamental research in quantum mechanics, especially for his statistical interpretation of the wavefunction.”26

Weird things

Here is where we find the root of much opposition: the apparently strange things that quantum mechanics predicts.

Uncertainty principle

Heisenberg recognized a fundamental limit to what could be measured. E.g. try to measure the position and momentum of an electron as finely as possible by shining a light photon on it. To finetune the position better, we need a small wavelength. But as de Broglie showed, the shorter the wavelength, the larger the momentum, thus the more that can be transferred to the electron. Thus the electron’s momentum cannot be known precisely. And if we reduce the momentum of the photon to avoid disturbing the electron too much, the wavelength increases, so its position becomes less certain—it is smeared out in space. Thus as Heisenberg said: “It is impossible to determine accurately both the position and the direction and speed of a particle at the same instant.”27 To be precise, the uncertainty in position and momentum is related to Planck’s Constant ΔxΔp ≥ h/4π. The same applies to energy and time: ΔEΔt ≥ h/4π.

Actually, there was a precedent for this in the remarkably productive mind of Einstein: he had recognized that there would be a residual energy even at absolute zero, which he called Nullpunktsenergie,28 or in English zero-point energy. It is easily explained in terms of the uncertainty principle: if there were a zero-energy state in some crystal lattice with fixed atomic positions, it would entail that the atoms’ positions and momenta could be known with total precision. To avoid this, there must be some residual energy.

This is actually proved by the inability to solidify helium no matter how cold, except under very high pressures (25 atmospheres): the zero-point energy would shake any solid lattice apart.

But despite Einstein’s contribution, he detested the uncertainty principle. In the years around 1930, he debated Bohr on various ways around it. These two admired each other greatly, but most physicists thought that Bohr had the better of the arguments—in one famous riposte, he used Einstein’s own theory of general relativity to defeat an ingenious thought experiment.

Interpretations of QM

This is where many of the problems lie. Probably the most common view is called the Copenhagen Interpretation, after Bohr’s place of research. It holds that the wavefunction exists as a superposition of all possible probabilistic states. But after a measurement or observation, we now know where something is with 100% probability, so the wavefunction is “collapsed” to just one of those states.

Some New Agers have imposed a mushy, mystical, and moral-relativistic view of QM, asserting that reality is not objective but depends on conscious observers. Both Einstein and Schrödinger didn’t like the mysticism of a supposed “observer collapses the wavefunction”. Einstein argued that a barrel of unstable explosive would contain a superposition of exploded and unexploded states. Schrödinger applied this idea to one of the most famous illustrations of QM, now called the Schrödinger’s Cat Paradox. But this was a thought experiment intended as a reductio ad absurdum of what he thought was a ridiculous type of interpretation of QM, since he rightly thought that the law of non-contradiction trumped the interpretation:29

One can even set up quite ridiculous cases. A cat is penned up in a steel chamber, along with the following device (which must be secured against direct interference by the cat): in a Geiger counter, there is a tiny bit of radioactive substance, so small that perhaps in the course of the hour, one of the atoms decays, but also, with equal probability, perhaps none; if it happens, the counter tube discharges, and through a relay releases a hammer that shatters a small flask of hydrocyanic acid. If one has left this entire system to itself for an hour, one would say that the cat still lives if meanwhile no atom has decayed. The psi-function of the entire system would express this by having in it the living and dead cat (pardon the expression) mixed or smeared out in equal parts.

The nuclear fusion reactions in the sun’s core work by QM but there is no conscious mind watching, unless you count spiritual beings which Copenhagen generally does not. From a biblical standpoint, there were plenty of things happening uniformly before God created man on Day 6 to observe any of them.

It is typical of these cases that an indeterminacy originally restricted to the atomic domain becomes transformed into macroscopic indeterminacy, which can then be resolved by direct observation. That prevents us from so naively accepting as valid a “blurred model” for representing reality. In itself, it would not embody anything unclear or contradictory. There is a difference between a shaky or out-of-focus photograph and a snapshot of clouds and fog banks.

However, Bohr never claimed any ‘collapse requires consciousness’ view; all that was required for an “observation” was a thermodynamically irreversible change. While a watched pot proverbially never boils, I found no difference in spectra whether I watched them or just set up the experiment to run. Also, the nuclear fusion reactions in the sun’s core work by QM but there is no conscious mind watching, unless you count spiritual beings which Copenhagen generally does not. From a biblical standpoint, there were plenty of things happening uniformly before God created man on Day 6 to observe any of them.

Thus some creationist (and non-creationist) physicists accept QM but propose a more realist interpretation just as Einstein and Schrödinger advocated. E.g. physicist Dr Russell Humphreys explains (personal communication):

In contrast with the Copenhagen interpretation, the Causal interpretation says that all particles have a definite location and speed at all times, even if we cannot measure both those numbers precisely at the same time. It further says that quantum-mechanical waves are real, and that they can influence the motion of the particles. Like a motorboat moving on a lake, the motion of a particle generates waves in the space nearby it, and those waves influence the path of the particle through space.

For example, in the famous two-slit experiments (described in most quantum mechanics textbooks), the Causal interpretation says that a particle approaching the slits only goes through one of them, but that the waves moving with the particle go through both slits. On the far side of the slits, the waves interfere with each other, setting up a pattern of peaks and troughs that guide the particle as it travels. The precise path it travels depends on precisely where it passed through the slit. This view of what is observed in experiments is far more straightforward than what the Copenhagen interpretation claims.

The Causal interpretation, held by a minority of well-known physicists since the 1920s, has become fairly well-developed in recent years. One of the best presentations of it for physicists is The Quantum Theory of Motion: An Account of the de Broglie–Bohm Causal Interpretion of Quantum Mechanics, by Peter R. Holland.30 Unfortunately, I know of no exposition of the Causal interpretation for laymen.

But many of the creationist critics of QM confuse QM with interpretations of QM.

Entanglement

Another strange effect is “entanglement”: two particles interact and thus share the same quantum state until a measurement is made. But we do know something about them, say that their ‘spins’ must be opposite, just that we don’t know which one has which spin. Then the particles go their separate ways. Then we measure one of them, and find that it has, say, anticlockwise spin. This means that the other one must instantly adopt clockwise spin—and so it will prove when it’s measured at any later time, as long as the entanglement is not otherwise disrupted. Both Einstein and Schrödinger disliked the apparent implication that this correlation would travel much faster than light. But many experiments are consistent with this implication, for example one with entangled photons:

The results also set a lower bound on the ‘speed of quantum information’ to 2/3 ×107 and 3/2 ×104 times the speed of light in the Geneva and the background radiation reference frames, respectively.31

To put this into perspective, Newton’s conception of gravitation was criticized at the time for postulating an ‘occult’ action-at-a-distance force which he thought acted instantly (under General Relativity, the force of gravity moves at the speed of light). There is no reason why God’s upholding of His creation (cf. Colossians 1:15) should be limited by the speed of light, especially as God is the creator of time itself.

Quantum entanglement could well revolutionize holographic imaging. The project leader, Dr. Hugo Defienne, of the University of Glasgow’s School of Physics and Astronomy, says:

Classical holography does very clever things with the direction, colour and polarisation of light, but it has limitations, such as interference from unwanted light sources and strong sensitivity to mechanical instabilities.
The process we've developed frees us from those limitations of classical coherence and ushers holography into the quantum realm. Using entangled photons offers new ways to create sharper, more richly detailed holograms, which open up new possibilities for practical applications of the technique.
One of those applications could be in medical imaging, where holography is already used in microscopy to scrutinise details of delicate samples which are often near-transparent. Our process allows the creation of higher-resolution, lower-noise images, which could help reveal finer details of cells and help us learn more about how biology functions at the cellular level.32

More evidence

I could not have worked in my own specialist area of spectroscopy unless molecules had quantized energy states, especially in vibrational energy in my case, but electronic states and rotational states as well.

I could not have worked in my own specialist area of spectroscopy unless molecules had quantized energy states, especially in vibrational energy in my case, but electronic states and rotational states as well.

Superconductors and superfluids

Other interesting evidences include superconductors, which I have also researched,33 and superfluids. These are substances with exactly zero resistivity and zero viscosity, respectively.

These are rare examples of quantum behaviour on the macro level. They are related to yet another prediction by Einstein, this time with Satyendra Nath Bose (1894–1974): they realized that at very low temperatures, the wavefunctions of identical particles could overlap to form a single quantum state, now called a Bose–Einstein Condensate.

This easily explains why it’s possible to have zero resistance and viscosity. A current of electrons or fluid usually loses energy to the surrounding materials, but if they are in one quantum state, any possible energy loss would be quantized, thus could not occur below this threshold. Superfluids also exhibit quantized vortices.

Woodward–Hoffmann rules for electrocyclic reactions

One class of organic reactions is electrocyclic, where a conjugated unsaturated “straight” chain hydrocarbon closes into a ring, or the reverse. To do this, there must be some rotation—either the two ends must rotate both clockwise/both anticlockwise, or conrotatory; or one clockwise and the other anticlockwise, or disrotatory. Whether it’s conrotatory or disrotatory turns out to be completely determined. Robert Burns Woodward (1917–1979) and Roald Hoffmann (1937– ) worked out the eponymous rules, based on the conservation of symmetry of the molecular orbitals, which no known classical model could predict.

In particular, the lobes of the molecular orbital can form a bond only if the wavefunction has the same sign (positive or negative), and this can be achieved only by rotation in one of the two possible types (conrotatory or disrotatory). Furthermore, a photochemical reaction turns out to have the opposite symmetry, also explained because the photon excites an electron into another orbital with a different symmetry.

Hoffmann shared the 1981 Nobel with Kenichi Fukui (1918–1998) “for their theories, developed independently, concerning the course of chemical reactions.” Woodward had died before he could be awarded his second Nobel Chemistry Prize.

Designs in nature using QM

Another good reason to support QM is that it is proving to be an ally of the creation model. There are many design features that require quantum mechanics to work.

The sense of smell: the design of olfaction

Some time ago I wrote on how our sense of smell works in accordance with vibrational spectroscopy and quantum mechanical tunneling:

Luca Turin, a biophysicist at University College, London, proposed a mechanism [34,35] where an electron tunnels from a donor site to an acceptor site on the receptor molecule, causing it to release the g-protein. Tunnelling requires both the starting and finishing points to have the same energy, but Turin believes that the donor site has a higher energy than the receptor. The energy difference is precisely that needed to excite the odour molecule into a higher vibrational quantum state. Therefore when the odour molecule lands, it can absorb the right amount of the electron’s energy, enabling tunnelling through its orbitals. This means the smell receptors actually detect the energy of vibrational quantum transitions in the odour molecules, as first proposed by G.M. Dyson in 1937.36

Bird electromagnetic navigation and quantum entanglement

More recent support comes from studies in bird navigation. For some time now, it has been known that birds and many other creatures use the earth’s magnetic field.37 But in European robins, red and yellow light somehow disorients their magnetic sense. So some researchers proposed that light causes one of the eye proteins to emit a pair of ‘entangled’ electrons with opposite spins. Again, we don’t know which is which until a measurement occurs, and here this ‘measurement’ is caused by some difference in the earth’s magnetic field. Thus the other electron must instantly adopt the opposite spin, which the bird detects and somehow computes the information about the magnetism. The birds are disoriented by weak oscillating magnetic field, which could not affect a macro-magnet like a magnetite crystal, but would disrupt an entangled pair.38

The history and practice of QM shows no hidden motivation to attack a biblical world view, in contrast to uniformitarian geology and evolutionary biology. Any proposed replacement theory needs to explain at least all the observations that QM does. This is not a specifically creationist project.

A recent paper paid its usual vacuous homage to evolution:

In artificial systems, quantum superposition and entanglement typically decay rapidly unless cryogenic temperatures are used. Could life have evolved to exploit such delicate phenomena? Certain migratory birds have the ability to sense very subtle variations in Earth’s magnetic field. Here we apply quantum information theory and the widely accepted “radical pair” model to analyze recent experimental observations of the avian compass. We find that superposition and entanglement are sustained in this living system for at least tens of microseconds, exceeding the durations achieved in the best comparable man-made molecular systems. This conclusion is starkly at variance with the view that life is too “warm and wet” for such quantum phenomena to endure.39

Of course, this is more evidence of a Designer whose techniques far exceed the best that man can do—in this case, maintaining quantum entanglement far longer than we can!40

Photosynthesis

Photosynthesis use light energy to split the water molecule, and make carbohydrates from its energized components. But the energy required is so great that a single photon with enough energy would blast most organic molecules apart. So photosynthetic organisms use a system that combined four lower-energy photons, and uses the combined energy to split the water molecule, held in place by special enzymes.41

Bacterial photosynthetic efficiency

Also, supposedly primitive purple bacteria exploit quantum mechanics to make their photosynthesis 95% efficient. They use a complex of tiny antennae to harvest light, but this complex can be distorted which could harm efficiency. However, because of the wave and particle nature of light and matter, although it absorbs a single photon at a time, the wave nature means that the photon is briefly everywhere in the antenna complex at once. Then of all possible pathways, it is absorbed in the most efficient manner, regardless of any shape changes in the complex. As with the previous example, quantum coherence is normally observable at extremely low temperatures, but these bacteria manage at ordinary temperatures.41

Photosynthetic dimmer switch

As above, photosynthesis by its nature needs a lot of energy for its purpose. The oxygen molecule it produces is chemically reactive on top. This could damage the complex molecules involved. But studies of green sulfur bacteria show there is a dimmer switch of a sort, which can divert excess energy. It works because the vibrational and electronic wave functions are precisely tuned so that they mix and become indistinguishable, called vibronic coupling. This occurs if the vibrational energy quantum of a bacteriochlorophyll molecule precisely matches the energy difference between two electronic states of the Fenna–Matthews–Olson (FMO) pigment–protein complex. Then energy can flow to the reaction centre with chlorophyll molecules, and generate plant food.

But if there is oxygen around, there could be energy overload. That is, were it not for a pair of cysteine residues in the photosynthetic complex. They are readily oxidized, i.e. a proton is removed. But this changes the energy states so that the electronic and vibrational matching is disrupted. so the normal pathway is blocked, and the system is protected. Instead, the energy flows through a less direct path and is ‘quenched’.42

The original research papers again make a vacuous homage to evolution.43 However, how would the organisms have produced food photosynthetically while evolving this finely tuned system? This looks more like the work of an Engineer who designed the whole.44

Chiral-induced spin selectivity (CISS)

Still another quantum mechanical application used by all life is Chiral-induced spin selectivity. This helps to explain why homochirality is so important for life. Electrons have quantum mechanical “spin” that provides a magnetic moment. The spin can be either “up” or “down”. It turns out that chiral molecules exert a strong preference on the spin of electrons transmitting through them. A spin-up electron prefers travelling in one direction, and a spin-down electron prefers the opposite direction. The electron spin can determine which of two possible chemical reactions is preferred. This could further explain the almost perfect efficiency (99.99%) of biological reactions, compared to chemical synthesis labs where 80% is considered very good. Another effect is that electrons in the ‘right’ spin traverse the molecule with little heat loss. That's because the electron can’t transfer energy to most quantum vibrational modes because that would need a change of spin and linear momentum. This prevents leaves from overheating during electron transfers resulting from photosynthesis, and allows our brains to work with enormously less power than an equivalent microprocessor would need.45,46

Conclusion

Quantum mechanics really works, and has been strongly supported by experiment. The history and practice of QM shows no hidden motivation to attack a biblical world view, in contrast to uniformitarian geology and evolutionary biology. Any proposed replacement theory needs to explain at least all the observations that QM does. This is not a specifically creationist project.

It seems wise for creationists to adopt the prevailing theories of operational science unless there are good observational reasons not to. Otherwise it could give the impression that we are anti-establishment for its own sake, rather than pro-Bible and opposing the establishment only when it contradicts biblical history. Fighting on two fronts has usually been a losing battle strategy. Rather, as previously with relativity, it makes more sense to co-opt it as an ally of creation, as with some of the design features in nature.

Published: 25 November 2011

References

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