home | what's new | other sites | contact | about

Word Gems 

exploring self-realization, sacred personhood, and full humanity

Quantum Mechanics

return to "Quantum Mechanics" main-page

from https://blogs.scientificamerican.com/cross-check/david-bohm-quantum-mechanics-and-enlightenment/

David Bohm, Quantum Mechanics and Enlightenment

The visionary physicist, whose ideas remain influential, sought spiritual as well as scientific illumination

By John Horgan on July 23, 2018, Scientific American

David Bohm, 1917-1992, seemed driven by twin, contradictory impulses, to clarify and mystify reality.

Some scientists seek to clarify reality, others to mystify it. David Bohm seemed driven by both impulses. He is renowned for promoting a sensible (according to Einstein and other experts) interpretation of quantum mechanics. But Bohm also asserted that science can never fully explain the world, and his 1980 book Wholeness and the Implicate Order delved into spirituality. Bohm’s interpretation of quantum mechanics has attracted increasing attention lately. He is a hero of Adam Becker’s new book What Is Real? The Unfinished Quest for the Meaning of Quantum Mechanics (reviewed by James Gleick, David Albert and Peter Woit). In The End of Science I tried to make sense of this paradoxical truth-seeker, who died in 1992 at the age of 74. Below is an edited version of that profile. See also my recent post on another quantum visionary, John Wheeler. –John Horgan

In August 1992 I visited David Bohm at his home in a London suburb. His skin was alarmingly pale, especially in contrast to his purplish lips and dark, wiry hair. His frame, sinking into a large armchair, seemed limp, languorous, and at the same time suffused with nervous energy. One hand cupped the top of his head, the other gripped an armrest. His fingers, long and blue-veined, with tapered, yellow nails, were splayed. He was recovering, he said, from a heart attack.

Bohm’s wife brought us tea and biscuits and vanished. Bohm spoke haltingly at first, but gradually the words came faster, in a low, urgent monotone. His mouth was apparently dry, because he kept smacking his lips. Occasionally, after making an observation that amused him, he pulled his lips back from his teeth in a semblance of a smile. He also had the disconcerting habit of pausing every few sentences and saying, “Is that clear?” or simply, “Hmmm?” I was often so hopelessly befuddled that I just smiled and nodded. But Bohm could be bracingly clear, too. Like an exotic subatomic particle, he oscillated in and out of focus.
Advertisement

Born and raised in the U.S., Bohm left in 1951, the height of anti-communist hysteria, after refusing to answer questions from a Congressional committee about whether he or anyone he knew was a communist. After stays in Brazil and Israel, he settled in England. Bohm was a scientific dissident too. He rebelled against the dominant interpretation of quantum mechanics, the so-called Copenhagen interpretation promulgated by Danish physicist Niels Bohr.

Bohm began questioning the Copenhagen interpretation in the late 1940s while writing a book on quantum mechanics. According to the Copenhagen interpretation, a quantum entity such as an electron has no definite existence apart from our observation of it. We cannot say with certainty whether it is either a wave or a particle. The interpretation also rejects the possibility that the seemingly probabilistic behavior of quantum systems stems from underlying, deterministic mechanisms.

Bohm found this view unacceptable. “The whole idea of science so far has been to say that underlying the phenomenon is some reality which explains things,” he explained. “It was not that Bohr denied reality, but he said quantum mechanics implied there was nothing more that could be said about it.” Such a view reduced quantum mechanics to “a system of formulas that we use to make predictions or to control things technologically. I said that's not enough. I don’t think I would be very interested in science if that were all there was.”

In 1952 Bohm proposed that particles are indeed particles--and at all times, not just when they are observed in a certain way. Their behavior is determined by a force that Bohm called the “pilot wave.” Any effort to observe a particle alters its behavior by disturbing the pilot wave. Bohm thus gave the uncertainty principle a purely physical rather than metaphysical meaning. Niels Bohr had interpreted the uncertainty principle as meaning “not that there is uncertainty, but that there is an inherent ambiguity” in a quantum system, Bohm explained.

Bohm’s interpretation gets rid of one quantum paradox, wave/particle duality, but it preserves and even highlights another, nonlocality, the capacity of one particle to influence another instantaneously across vast distances. Einstein had drawn attention to nonlocality in 1935 in an effort to show that quantum mechanics must be flawed. Together with Boris Podolsky and Nathan Rosen, Einstein proposed a thought experiment involving two particles that spring from a common source and fly in opposite directions.
Advertisement

According to the standard model of quantum mechanics, neither particle has fixed properties, such as momentum, before it is measured. But by measuring one particle’s momentum, the physicist instantaneously forces the other particle, no matter how distant, to assume a fixed momentum. Deriding this effect as “spooky action at a distance,” Einstein argued that quantum mechanics must be flawed or incomplete. But in 1980 French physicists demonstrated spooky action in a laboratory. Bohm never had any doubts about the experiment’s outcome. “It would have been a terrific surprise to find out otherwise,” he said.

But here is the paradox of Bohm: Although he tried to make the world more sensible with his pilot-wave model, he also argued that complete clarity is impossible. He reached this conclusion after seeing an experiment on television, in which a drop of ink was squeezed onto a cylinder of glycerine. When the cylinder was rotated, the ink diffused through the glycerine in an apparently irreversible fashion. Its order seemed to have disintegrated. But when the direction of rotation was reversed, the ink gathered into a drop again.

The experiment inspired Bohm to write Wholeness and the Implicate Order, published in 1980. He proposed that underlying physical appearances, the “explicate order,” there is a deeper, hidden “implicate order.” Applying this concept to the quantum realm, Bohm proposed that the implicate order is a field consisting of an infinite number of fluctuating pilot waves. The overlapping of these waves generates what appears to us as particles, which constitute the explicate order. Even space and time might be manifestations of a deeper, implicate order, according to Bohm.

To plumb the implicate order, Bohm said, physicists might need to jettison basic assumptions about nature. During the Enlightenment, thinkers such as Newton and Descartes replaced the ancients’ organic concept of order with a mechanistic view. Even after the advent of relativity and quantum mechanics, “the basic idea is still the same,” Bohm told me, "a mechanical order described by coordinates.”

Bohm hoped scientists would eventually move beyond mechanistic and even mathematical paradigms. “We have an assumption now that’s getting stronger and stronger that mathematics is the only way to deal with reality,” Bohm said. “Because it’s worked so well for a while, we’ve assumed that it has to be that way.”

Someday, science and art will merge, Bohm predicted. “This division of art and science is temporary,” he observed. “It didn't exist in the past, and there’s no reason why it should go on in the future.” Just as art consists not simply of works of art but of an “attitude, the artistic spirit,” so does science consist not in the accumulation of knowledge but in the creation of fresh modes of perception. “The ability to perceive or think differently is more important than the knowledge gained,” Bohm explained.

Bohm rejected the claim of physicists such as Hawking and Weinberg that physics can achieve a final “theory of everything” that explains the world. Science is an infinite, “inexhaustible process,” he said. “The form of knowledge is to have at any moment something essential, and the appearance can be explained. But then when we look deeper at these essential things they turn out to have some feature of appearances. We're not ever going to get a final essence which isn't also the appearance of something.”

Bohm feared that belief in a final theory might become self-fulfilling. “If you have fish in a tank and you put a glass barrier in there, the fish keep away from it,” he noted. “And then if you take away the glass barrier they never cross the barrier and they think the whole world is that.” He chuckled drily. “So your thought that this is the end could be the barrier to looking further.” Trying to convince me that final knowledge is unattainable, Bohm offered the following argument:

“Anything known has to be determined by its limits. And that’s not just quantitative but qualitative. The theory is this and not that. Now it’s consistent to propose that there is the unlimited. You have to notice that if you say there is the unlimited, it cannot be different, because then the unlimited will limit the limited, by saying that the limited is not the unlimited, right? The unlimited must include the limited. We have to say, from the unlimited the limited arises, in a creative process. That’s consistent. Therefore we say that no matter how far we go there is the unlimited. It seems that no matter how far you go, somebody will come up with another point you have to answer. And I don’t see how you could ever settle that.”

To my relief, Bohm’s wife entered the room and asked if we wanted more tea. As she refilled my cup, I pointed out a book on Buddhism on a shelf and asked Bohm if he was interested in spirituality. He nodded. He had been a friend of Krishnamurti, one of the first modern Indian sages to try to show Westerners how to achieve the state of spiritual serenity and grace called enlightenment. Was Krishnamurti enlightened? “In some ways, yes,” Bohm replied. “His basic thing was to go into thought, to get to the end of it, completely, and thought would become a different kind of consciousness.”

Of course, one could never truly plumb one’s own mind, Bohm said. Any attempt to examine one’s own thought changes it--just as the measurement of an electron alters its course. We cannot achieve final self-knowledge, Bohm seemed to imply, any more we can achieve a final theory of physics.

Was Krishnamurti a happy person? Bohm seemed puzzled by my question. “That's hard to say,” he replied. “He was unhappy at times, but I think he was pretty happy overall. The thing is not about happiness, really.” Bohm frowned, as if realizing the import of what he had just said.

I said goodbye to Bohm and his wife and departed. Outside, a light rain was falling. I walked up the path to the street and glanced back at Bohm's house, a modest whitewashed cottage on a street of modest whitewashed cottages. He died of a heart attack two months later.

In Wholeness and the Implicate Order Bohm insisted on the importance of “playfulness” in science, and in life, but Bohm, in his writings and in person, was anything but playful. For him, truth-seeking was not a game, it was a dreadful, impossible, necessary task. Bohm was desperate to know, to discover the secret of everything, but he knew it wasn’t attainable, not for any mortal being. No one gets out of the fish tank alive.

***********************************

from http://everythingforever.com/Bohm.htm

David Bohm

The Two Kinds of Order

Einstein once spoke of the physicist David Bohm as his successor. Bohm introduced concepts of Implicate Order and Explicate Order. Bohm defined explicate order as the order of the physical world. He defined implicate order as the source of explicate order, and as an underlying whole that physical form constantly unfolds out from and enfolds back into. Others had constructed related models of two orders, including Henri Bergson and William Yeats in the early 1900's. Bohm meant his concepts to replace order and disorder although he was not able to convince other scientists of this necessity, and Bohm struggled with depression at not being able to convince the scientific community of the scientific value of his discoveries. In describing Implicate Order Bohm writes:

This order is not to be understood solely in terms of a regular arrangement of objects (e.g., in rows) or as a regular arrangement of events (e.g. in a series). Rather, a total order is contained in some implicit sense, in each region of space and time. Now the word 'implicit' is based on the verb 'to implicate'. This means 'to fold inward' (as multiplication means 'folding many times'). So we may be led to explore the notion that in some sense each region contains a total structure 'enfolded' within it.

The two directions of order are probably the most important features of nature that we will ever understand. There are endless applications of two orders in every field, in physics, biology, geology, politics, and psychology, just naming the more obvious fields. The theory of two orders generally describes all change, all patterns, all definitive form, so what if anything could be excluded. As we learn to perceive the cosmos as one type of order transforming into another, doors of comprehension will open beyond our wildest dreams.

In order to understand how the whole can exist in every part, Bohm became interested in the mechanics of holographic photography. Using lasers, a holographic image is recorded evenly across the photographic film. Consequently any region of the film contains information about the whole image, so any small region of the film can recreate the image, although in poorer resolution than the entire film produces.

Bohm believed all matter is unfolded out of what he eventually described as a holomovement, which meant that matter could also enfold and so return into the holomovement. Bohm considered quantum mechanics to be a process of unfolding and enfolding. He imagined the universe as an infinite sea of space and energy out of which matter could be unfolded, which he called explicating, and enfolded which he called implicating, which, in Bohm’s words, “together are a flowing, undivided wholeness. Every part of the universe is related to every other part but in different degrees.” In an interview published in Omni magazine conducted by the physicist F. David Peat and John Briggs, Bohm explained his concept of enfoldment:

“Everybody has seen an image of enfoldment: You fold up a sheet of paper, turn it into a small packet, make cuts in it, and then unfold it into a pattern. The parts that were close in the cuts unfold to be far away. This is like what happens in a hologram. Enfoldment is really very common in our experience. All the light in this room comes in so that the entire room is in effect folded into each part. If your eye looks, the light will be then unfolded by your eye and brain. As you look through a telescope or a camera, the whole universe of space and time is enfolded into each part, and that is unfolded to the eye. With an old-fashioned television set that's not adjusted properly, the image enfolds into the screen and then can be unfolded by adjustment.”

The process of unfolding and enfolding suggests a whole exists primarily as a base, and although Bohm described the whole as being dynamic and in constant motion in most of his writings, in his later years he began to describe time as occurring within timelessness. In hindsight it appears that Bohm didn’t focus enough on the timeless nature of patterns. He didn’t recognize consciously enough that ordinary patterns reveal the implicate order, although in Bohm’s analogies you find the same type of examples that I use to explain the transition from grouping to symmetry order. One of Bohm’s favorite analogies spawned from a scientific program he’d seen on a television show. The program featured a small scientific wonder, where an insoluble drop of dark ink in one process disappears uniformly into a glycerin, then in the opposite process the drop reappears.

About the time I was looking into these questions, a BBC science program showed a device that illustrates these things very well. It consists of two concentric glass cylinders. Between them is a viscous fluid, such as glycerin. If a drop of insoluble ink is placed in the glycerin and the outer cylinder is turned slowly, the drop of dye will be drawn out into a thread. Eventually the thread gets so diffused it cannot be seen. At that moment there seems to be no order present at all. Yet if you slowly turn the cylinder backward, the glycerin draws back into its original form, and suddenly the ink drop is visible again. The ink had been enfolded into the glycerin, and it was unfolded again by the reverse turning.

... All the empty space in the universe, which we naturally assume to be less than the physical matter we are able to interact with, is actually more full of content than the surface of form we see due to light waves. What we imagine to be empty space contains the whole of everything. It is a considerably different way of looking at the world, but the message is that matter is constantly unfolding out of and refolding into a larger balanced whole. Bohm writes:

Classical physics says that reality is actually little particles that separate the world into its independent elements. Now I'm proposing the reverse, that the fundamental reality is the enfoldment and unfoldment, and these particles are abstractions from that. We could picture the electron not as a particle that exists continuously but as something coming in and going out and then coming in again. If these various condensations are close together, they approximate a track. The electron itself can never be separated from the whole of space, which is its ground.

**********************************************

f rom https://davidcenter.com/wp/2020/08/12/bohm-pribram-and-the-holographic-model/

Bohm says that everything has order but some states of order can only be seen from a higher perspective (implicate order). This is known as hidden order because it is not manifested but enfolded in the implicate order. By way of analogy, Bohm describes a vessel containing glycerine and a small glob of ink. The glycerine in the vessel can be rotated with a crank. When the glycerine is spun the glob of ink spreads out until it is no longer visible (enfolded). When the spin is reversed the glob of ink will reconstitute itself into a visible glob (unfolded).

**********************************************

from https://www.theosociety.org/pasadena/sunrise/46-96-7/sc-pruyn.htm

David Bohm experienced a difficult childhood. Born in a Jewish family in Wilkes-Barre, Pennsylvania, he was raised mainly by his father, a furniture store owner and assistant of the local rabbi. Bohm held a negative opinion of his father and received little encouragement from his mother, who often suffered from mental illness. As a result, he sought inspiration in his own world and, at an early age, showed the character of a genuine truth-seeker.

From the beginning of his scientific career, Bohm placed more faith in intuition as a way of arriving at solutions than in the more common way of mathematics. When he arrived at Caltech in 1939, he found the campus disturbingly different from what he had expected. He encountered a world of competition that left little room for creative thinking and real physics. Peat writes that Bohm's roommate "believed that Caltech students learned physics through the act of problem-solving itself. But for Bohm, understanding always involved probing deeper and deeper into underlying assumptions" (p. 34). By this time, Bohm was accustomed to regarding all phenomena as flowing from a deeper level of existence and periodically withdrawing into that same unknown world. He showed familiarity with the Hermetic axiom: as above, so below.

He also believed that by paying attention to his own feelings and intuitions, he should be able to arrive at a deeper understanding of the nature of the universe of which he was part. He saw the universe as infinite and ineffable; he developed a vision of an infinite number of hierarchies within hierarchies, which made up what he called the implicate order. He found confirmation of his mystic vision on television in the 1960s, when he saw a device made of two concentric glass cylinders, the space between them filled with colorless glycerin. The experimenter put a drop of ink in the glycerin, and then turned the outer cylinder. As a result, the droplet was drawn out into a thread, which gradually became thinner and thinner until it vanished completely; the ink had disappeared but still existed in the glycerin. When the cylinder was turned in the opposite direction, the ink reappeared from its enfolded, hidden existence. Bohm realized that there was no disorder or chaos, but, rather, a hidden order.

Bohm's profound concern was the foundations of physics and quantum theory; he did not shy away from taboos and stick to the safety of accepted science, as so many scientists did and still do. As a result, he did not have an easy career. On many occasions he found himself neglected; he published several books that to his disappointment were often ignored by colleagues. Nor did he become a Nobel laureate, though he was a worthy candidate. Bohm also suffered great distress when forced by McCarthyism to leave his home country in the early '50s on account of the Marxist views he held at that time. He found refuge in Brazil, but had a hard time far away from home without friends and colleagues, and was subject to bouts of depression. He again found himself threatened, this time by a group of Nazi sympathizers who tried to scare him off the campus. The situation became so serious that the head of the faculty called for the assistance of a good friend of Bohm's: Albert Einstein. Einstein wrote a letter intended for publication to the Governor of the State of Sao Paulo:

[Bohm] has become deeply interested in the following questions. Is it really necessary to assume that the processes in the molecular domain are governed by chance? Is it not possible to explain the present theory in such a way as to indicate that everything should proceed by necessity, so that chance is, in principle, eliminated. . . . I have had in the past the greatest confidence in Dr. Bohm as a scientist and as a man, and I continue to do so. — p. 148 ...

David Bohm died in a taxi as he was being driven home from work. He had just been putting the finishing touches to a book on quantum physics, co-authored with his collaborator Basil Hiley. This book --The Undivided Universe (1993) — marks the culmination of Bohm's life-long effort to develop an alternative interpretation of quantum physics, one which rejects the role of chance, and instead posits the existence of subtler forces acting from hidden, implicate levels of reality, in order to explain the sometimes puzzling behavior of the subatomic world.

Infinite Potential: The Life and Times of David Bohm is an inspiring book, well documented and illustrated. It presents a compelling picture of a great scientist, a man who dared to question orthodoxy and to introduce new and radical ideas into science, but who suffered neglect and misunderstanding, as so many truly great men have.