Live your best possible life. How good can it get?

2021-10-04 CSL

One of the common assumptions about some of the ‘weirdest’ aspects of quantum phenomena, is that we don’t need to be concerned with it, since it happens in the realm of the very, very, astonishingly small.

Our everyday life experience tells us that macroscopic systems obey classical physics, and we’ve even received reassurances from brilliant physicists that we need not concern ourselves with the possibility of quantum effects in daily life.  It’s understandable that we then naturally expect that quantum mechanics must reproduce classical mechanics results in the macroscopic range–which is known as “the correspondence principle,” that physicist Niels Bohr established in 1920.   Proponents of this premise have presumed for the past century that any transition from to classical mechanics operates according to a kind of coarse-graining mechanism, whereby measurements performed on macroscopic systems that have limited resolution, and are unable to resolve individual microscopic particles will behave classically. 

As discussed in my book, Quantum Jumps: scientists now confirm we can see quantum phenomena at macroscopic scale! “It is amazing to have quantum rules at the macroscopic scale. We just have to measure fluctuations, deviations from expected values, and we will see quantum phenomena in macroscopic systems”

Can we see quantum correlations at the macroscopic scale?

How Quantum Correlations Can Survive

Researchers Miguel Gallego (University of Vienna) and Borivoje Dakić (University of Vienna and IQOQI) were surprised to discover that quantum correlations survive in the macroscopic limit when correlations are not independent and identically distributed (IID) at the level of microscopic constituents.

This idea of independent and identically distributed (IID) is the key here, since it is often presumed to be generally true in experimental laboratory settings.  When quantum measurements are taken and calculated for the corresponding correlations, experimental designs typically involve a large number of repetitions, since the key assumption is that each run of the experiment must be repeated under exactly the same conditions, yet independently from other experimental runs.  Experiments are designed with the idea in mind that they ensure that each quantum random “coin toss” is fair and unbiased, so the ratio of “heads” to “tails” comes out evenly, with either “heads” or “tails” expected 50% of the time.

As it turns out, this assumption, that plays such a pivotal role in the expectation that there exist only classical physics happening past some macroscopic limit.  What these recent research results show is that what is really going on is that macroscopic groupings of clusters of quantum particles that are “coarse-grained” together interact with each other, with Borivoje Dakić stating:

“The IID assumption is not natural when dealing with a large number of microscopic systems. Small quantum particles interact strongly and quantum correlations and entanglement are distributed everywhere. Given such a scenario, we revised existing calculations and were able to find complete quantum behavior at the macroscopic scale. This is completely against the correspondence principle, and the transition to classicality does not take place”

What Are the Implications?

classic physics subsetWhile we have long presumed the wide, wonderful, weird world of quantum physics to operate either alongside or within the classical realm, the real truth of the matter is that we’re seeing ever-increasing evidence to suggest that classical theory and physics might best be viewed as a special case within the bigger quantum reality.

By appreciating the possibility that quantum logic is primary in the natural world, we see how humanity stands to benefit from embracing the innate quantum logic implicit in everything. We can thus envision how the addition of quantum theory ushers in a new view of all areas of study, including:  biology, psychology, sociology, cosmology, statistics, and history. The idea that quantum phenomena occur at all levels—not merely at microscopic quantum levels—indicates we are able to develop a more functionally predictive and naturally based quantum perspective that promises to completely revise our worldview.

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Dakic, Borivoje Dakic & Gallego Miguel.  “Can We See Quantum Correlations at the Macroscopic Scale?”  PhysOrg.  23 Sep 2021.

Larson, Cynthia Sue. “Primacy of quantum logic in the natural world.” Cosmos and History: The Journal of Natural and Social Philosophy 11, no. 2 (2015): 326-340.

Larson, Cynthia.  Quantum Jumps:  An Extraordinary Science of Happiness and Prosperity.  2013.

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You can watch the companion video to this blog here:


QuantumJumps300x150adCynthia Sue Larson is the best-selling author of six books, including Quantum Jumps.  Cynthia has a degree in physics from UC Berkeley, an MBA degree, a Doctor of Divinity, and a second degree black belt in Kuk Sool Won. Cynthia is the founder of RealityShifters, and is president of the International Mandela Effect Conference. Cynthia hosts “Living the Quantum Dream” on the DreamVisions7 radio network, and has been featured in numerous shows including Gaia, the History Channel, Coast to Coast AM, One World with Deepak Chopra, and BBC. Cynthia reminds us to ask in every situation, “How good can it get?” Subscribe to her free monthly ezine at:

Comments on: "Can We See Quantum Phenomena?" (2)

  1. We see the effects of quantum behavior every time the Sun rises — without quantum tunneling and the Heisenberg Uncertainty Principle (necessary to the weak force), fusion in the Sun wouldn’t work.

    There is also a simple home experiment that demonstrates quantum effects: Two polarizing filters set at 90° relative to each other block all photons (assuming ideal filters) but insert a third filter set to 45° between them, and now 12.5% of the photons pass through. As far as I know, this cannot be explained with the classical wave description of light.

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