Quotes & Sayings


We, and creation itself, actualize the possibilities of the God who sustains the world, towards becoming in the world in a fuller, more deeper way. - R.E. Slater

There is urgency in coming to see the world as a web of interrelated processes of which we are integral parts, so that all of our choices and actions have [consequential effects upon] the world around us. - Process Metaphysician Alfred North Whitehead

Kurt Gödel's Incompleteness Theorem says (i) all closed systems are unprovable within themselves and, that (ii) all open systems are rightly understood as incomplete. - R.E. Slater

The most true thing about you is what God has said to you in Christ, "You are My Beloved." - Tripp Fuller

The God among us is the God who refuses to be God without us, so great is God's Love. - Tripp Fuller

According to some Christian outlooks we were made for another world. Perhaps, rather, we were made for this world to recreate, reclaim, redeem, and renew unto God's future aspiration by the power of His Spirit. - R.E. Slater

Our eschatological ethos is to love. To stand with those who are oppressed. To stand against those who are oppressing. It is that simple. Love is our only calling and Christian Hope. - R.E. Slater

Secularization theory has been massively falsified. We don't live in an age of secularity. We live in an age of explosive, pervasive religiosity... an age of religious pluralism. - Peter L. Berger

Exploring the edge of life and faith in a post-everything world. - Todd Littleton

I don't need another reason to believe, your love is all around for me to see. – Anon

Thou art our need; and in giving us more of thyself thou givest us all. - Khalil Gibran, Prayer XXIII

Be careful what you pretend to be. You become what you pretend to be. - Kurt Vonnegut

Religious beliefs, far from being primary, are often shaped and adjusted by our social goals. - Jim Forest

We become who we are by what we believe and can justify. - R.E. Slater

People, even more than things, need to be restored, renewed, revived, reclaimed, and redeemed; never throw out anyone. – Anon

Certainly, God's love has made fools of us all. - R.E. Slater

An apocalyptic Christian faith doesn't wait for Jesus to come, but for Jesus to become in our midst. - R.E. Slater

Christian belief in God begins with the cross and resurrection of Jesus, not with rational apologetics. - Eberhard Jüngel, Jürgen Moltmann

Our knowledge of God is through the 'I-Thou' encounter, not in finding God at the end of a syllogism or argument. There is a grave danger in any Christian treatment of God as an object. The God of Jesus Christ and Scripture is irreducibly subject and never made as an object, a force, a power, or a principle that can be manipulated. - Emil Brunner

“Ehyeh Asher Ehyeh” means "I will be that who I have yet to become." - God (Ex 3.14) or, conversely, “I AM who I AM Becoming.”

Our job is to love others without stopping to inquire whether or not they are worthy. - Thomas Merton

The church is God's world-changing social experiment of bringing unlikes and differents to the Eucharist/Communion table to share life with one another as a new kind of family. When this happens, we show to the world what love, justice, peace, reconciliation, and life together is designed by God to be. The church is God's show-and-tell for the world to see how God wants us to live as a blended, global, polypluralistic family united with one will, by one Lord, and baptized by one Spirit. – Anon

The cross that is planted at the heart of the history of the world cannot be uprooted. - Jacques Ellul

The Unity in whose loving presence the universe unfolds is inside each person as a call to welcome the stranger, protect animals and the earth, respect the dignity of each person, think new thoughts, and help bring about ecological civilizations. - John Cobb & Farhan A. Shah

If you board the wrong train it is of no use running along the corridors of the train in the other direction. - Dietrich Bonhoeffer

God's justice is restorative rather than punitive; His discipline is merciful rather than punishing; His power is made perfect in weakness; and His grace is sufficient for all. – Anon

Our little [biblical] systems have their day; they have their day and cease to be. They are but broken lights of Thee, and Thou, O God art more than they. - Alfred Lord Tennyson

We can’t control God; God is uncontrollable. God can’t control us; God’s love is uncontrolling! - Thomas Jay Oord

Life in perspective but always in process... as we are relational beings in process to one another, so life events are in process in relation to each event... as God is to Self, is to world, is to us... like Father, like sons and daughters, like events... life in process yet always in perspective. - R.E. Slater

To promote societal transition to sustainable ways of living and a global society founded on a shared ethical framework which includes respect and care for the community of life, ecological integrity, universal human rights, respect for diversity, economic justice, democracy, and a culture of peace. - The Earth Charter Mission Statement

Christian humanism is the belief that human freedom, individual conscience, and unencumbered rational inquiry are compatible with the practice of Christianity or even intrinsic in its doctrine. It represents a philosophical union of Christian faith and classical humanist principles. - Scott Postma

It is never wise to have a self-appointed religious institution determine a nation's moral code. The opportunities for moral compromise and failure are high; the moral codes and creeds assuredly racist, discriminatory, or subjectively and religiously defined; and the pronouncement of inhumanitarian political objectives quite predictable. - R.E. Slater

God's love must both center and define the Christian faith and all religious or human faiths seeking human and ecological balance in worlds of subtraction, harm, tragedy, and evil. - R.E. Slater

In Whitehead’s process ontology, we can think of the experiential ground of reality as an eternal pulse whereby what is objectively public in one moment becomes subjectively prehended in the next, and whereby the subject that emerges from its feelings then perishes into public expression as an object (or “superject”) aiming for novelty. There is a rhythm of Being between object and subject, not an ontological division. This rhythm powers the creative growth of the universe from one occasion of experience to the next. This is the Whiteheadian mantra: “The many become one and are increased by one.” - Matthew Segall

Without Love there is no Truth. And True Truth is always Loving. There is no dichotomy between these terms but only seamless integration. This is the premier centering focus of a Processual Theology of Love. - R.E. Slater

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Note: Generally I do not respond to commentary. I may read the comments but wish to reserve my time to write (or write from the comments I read). Instead, I'd like to see our community help one another and in the helping encourage and exhort each of us towards Christian love in Christ Jesus our Lord and Savior. - re slater

Thursday, June 6, 2024

Emergentism | Chapter 2: From Reduction to Emergence


I wish to present Brendan Graham Dempsey's discourse on designing new civilizations of ecology, religion, science, and cultural behaviours, as aligned with my own these past many years. And though I have been steadily applying AN Whitehead's Process Philosophy to all human disciplines, I sense Brendan's Emergentism group is eclectically picking-and-choosing across a similar space which I have described in the past as the additive parts to the whole of process thought as an integral philosophy to all previous thoughts and constructs. Hence, I deem Process Philosophy as a broadly holistic construct in which all other constructs fit within such as process theology, process religion, process science, process evolution, process ecology, and so... including the area of emergentism. So, let's get to it and see where emergentism goes as an eclectic practice drawing across a variety of thought systems in reviving and resurrecting global, regional and local cultures for the 21st Century.

R.E. Slater
June 1, 2024
Emergentism | Chapter 2:
From Reduction to Emergence

SEP 20, 2022


New Laws: Thermodynamics and Evolution

By the mid-19th century, with modernity in full swing, two new scientific fields would enter the fray that, at first, seemed only to confirm its increasingly disenchanted worldview: the study of thermodynamics and the theory of evolution.

One seemed to imply that all available energy in the universe was irreversibly running out, leading to the eventual freezing death of the cosmos; the other, that life had developed completely naturally through blind processes of chance mutation and selection.

Such ideas seemed to fit well with the rest of the metaphysics and cosmic story of modernity: namely, a blind, indifferent universe without goal or meaning. Or, perhaps a better way to see it: these paradigms were simply interpreted according to the dominant worldview of the time—one reductionistic, pessimistic, and bleak—and thus only seemed, at first blush, to confirm people’s popular perceptions.

Nevertheless, these new paradigms would eventually become key to a total re-evaluation of reductionism itself—even if, in the late 1800s, no one could yet foresee this.

Let’s start with thermodynamics.

As we’ve seen, classical physics had come to be defined by its assumption that everything can be reduced to particles in motion, which Newton had shown to obey certain mathematical laws that let us predict future states and reconstruct prior ones with just a few measurements—the way you can deduce where a cue ball will end up (as well as where it was coming from) as long as you know its current position and velocity. Reductionistic theory assured that the world was a deterministic machine, and the only thing stopping us from predicting the behavior of everything from clouds to kings with absolute certainty (the way we can predict eclipses or the return of comets, for instance) was simply the practical difficulty of getting all the measurements.

Well, the formulation of the famous laws of thermodynamics would pose a major challenge to that assumption, and begin to problematize the very premises of reductionism.

The laws of thermodynamics came about by studying how energy behaves in closed or “isolated” systems—which is to say, containers cut off from the rest of the environment. Originally, scientists were looking at how heat acted inside engines (steam engines being quite the craze in the early 1800s). Today we might think of a thermos as a good example of an isolated system, since it’s specifically designed to retain the temperature of what’s inside by keeping it as insulated as possible from the surrounding environment. By studying how heat behaved in closed systems like this, scientists sought to formulate universal laws about energy (just as Galileo formulated universal laws of motion by means of isolation and simplification).

As codified in the first law of thermodynamics, then, it was discovered that, in a genuinely closed system, the total amount of energy remains fixed and unchanging. No energy is coming in or going out, nor can energy itself ever be created or destroyed. Its total amount will remain constant—even if it changes form or distribution.

So far, so good. (This idea of “conservation” pairs well with the idea of the conservation of motion in Newtonian physics. Nature always balances her books in the physical accounting of the world.)

But things become more problematic with the second law, likewise deduced from observation, which says that the total energy in the system will gradually and irrevocably dissipate until a homogenous equilibrium state is reached. Differences even out, distinctions blur, and gradients are eradicated over time.

Think what happens when you add hot water to a thermos of cold water. That energetic hot water won’t stay all clumped together in one place; instead, the heat will spread out (or “dissipate”) until all the water in the thermos finally becomes one uniform temperature. This is called “entropy,” and the second law asserts that free energy is always being entropically dissipated over time—degraded, you could say, until eventually it’s totally useless and the system reaches a uniform, featureless balance: equilibrium.


This insight created a big problem for the conception of Newtonian reality as particles in motion whose future and past states could all be predicted with deterministic certitude. Instead of being able to deduce it, once something reaches equilibrium it’s impossible to know its earlier state (AKA its “initial conditions”). You can’t deduce from a warm thermos that there was ever hot water of a certain temperature added to cold water of a certain temperature; all of that information is lost once the temperatures mix due to entropy.

The laws of Newtonian physics were completely reversible. Gravity might bring a rock down, but enough force against gravity could throw a rock right back up again. The laws of thermodynamics, by contrast, had a clear irreversible trajectory. The hot and cold water will mix spontaneously over time, but trying to separate them again requires a lot of energy—free energy that no longer exists in the system, precisely because it’s been dissipated.

In short, according to Newton’s laws, time was negligible; according to the laws of thermodynamics, however, time has a clear direction. It gives us what Arthur Eddington famously called the “arrow of time.” And, according to the laws of thermodynamics, that arrow seemed to move only one way: from a gradient to equilibrium, from difference to sameness, from distinct order to jumbled chaos. According to the second law, entropy in a closed system can only increase, suggesting the universe itself must be like an engine irrevocably running out of fuel, destined for dissolution and death.

At least, that was how its cosmic implications came to be interpreted by an increasingly modernized world. Primed to imagine life as a meaningless accident in an indifferent cosmos, this discovery fell comfortably in line with the grim reductionist worldview—even though it actually flew in the face of the scientific reductionism that had helped found that worldview (and would eventually help overthrow it entirely—something we’ll come back to).

Anyway, the cracks in the reductionistic edifice didn’t end there.

Interestingly, at roughly the same time the laws of thermodynamics were being discovered, the theory of evolution erupted onto the scene and caused its own disruptive stir. According to this new theory, the vastly different kinds of species we see in the world came about not through divine fiat all at once (as the traditional religious story had told it), but through an eons-long unguided process of continual branching and pruning of the tree of life from the shoot of an initial common ancestor.

As Darwin expressed it concisely in The Origin of Species in 1859:


As many more individuals of each species are born than can possibly survive; and as, consequently, there is a frequently recurring struggle for existence, it follows that any being, if it vary however slightly in any manner profitable to itself, under the complex and sometimes varying conditions of life, will have a better chance of surviving, and thus be naturally selected. From the strong principle of inheritance, any selected variety will tend to propagate its new and modified form.

In this way, life was continually diversifying over time, creating more and more novelty, generating more and more difference. “And as natural selection works solely by and for the good of each being,” concluded Darwin, “all corporeal and mental endowments will tend to progress towards perfection.”

This process seemed to follow its own set of universal principles, different from Newtonian law. The “elaborately constructed forms” of the animals, says Darwin, “have all been produced by laws acting around us”—laws new to science, such that “whilst this planet has gone cycling on according to the fixed law of gravity, from so simple a beginning endless forms most beautiful and most wonderful have been, and are being, evolved.” That is, against the static universe of Newtonian physics, a dynamic process of diversification was leading to more and more elaborate forms over time.


Again, despite the challenge this posed to classical reductionism, the immediate interpretation of this theory only fed the growing divide between materialist reductionists and religious traditionalists. Against the protests of the traditionalist holdouts (who fought evolution as a threat to their mythological sense of meaning), those committed to modernism and science felt compelled to embrace the conclusion that Darwin’s insights confirmed the basic hunch of the reductionist worldview. Life was not the product of any Intelligent Designer, but only blind mutation and nature’s savage “culling of the herd.”

Such a sense of nature—“red in tooth and claw,” as the poet Tennyson assessed it for his religiously shaken fellow Victorians—was the last straw for any religiously inclined rational mind, now helplessly buffeted from an ancient traditional holism of cosmic meaning and benevolent care:
Are God and Nature then at strife, That Nature lends such evil dreams? So careful of the type she seems, So careless of the single life; That I, considering everywhere Her secret meaning in her deeds, And finding that of fifty seeds She often brings but one to bear, I falter where I firmly trod, And falling with my weight of cares Upon the great world's altar-stairs That slope thro' darkness up to God, I stretch lame hands of faith, and grope, And gather dust and chaff, and call To what I feel is Lord of all, And faintly trust the larger hope.


But, like entropic energy itself, that larger hope would only grow fainter and fainter with time, until, by the 20th century, it seemed to dissipate altogether. The reductionistic worldview ushered in by modernity had become the new cultural default. The old naïve holism of religion was lost, along with all its assumed sense of value and meaning. Reductionist science—along with nihilistic interpretations of thermodynamics and evolution—had fundamentally changed people’s perspective regarding the part that humans played in the cosmic whole, leading them to no longer see themselves as agential wholes but only deterministic meat-suits moving through space.

As a consequence, people today who feel they know a thing or two (and likely find themselves in positions of power) can, as we said, confidently assert: Life’s just a cosmic accident; the fit survive by preying on the weak and stupid; morality’s a fairy tale invented to keep people in line; and, sooner or later, the sun will explode, the universe will end in heat death, and none of this dazzling sound and fury will have meant a goddamn thing—so why not live it up while we can? By the early 20th century, all of the ingredients for the meaning crisis were firmly in place.

As it turns out, however, this nihilistic worldview is actually… well… just simply wrong. It is based on contradictions, incomplete science, and unjustified extrapolations—failures that the new science has since begun to correct, but which nevertheless still hold sway in the public imagination. Let’s unpack this and, in the process, introduce the new science of complexity.

First of all, the classical reductionism of Newtonian physics was reversible; it didn’t matter in which direction you “ran the tape”—backwards or forwards—everything was just a matter of deterministic particles in motion.


However, both thermodynamics and evolution were different. They presented a model of reality quite contrary to this idea, with laws that had a direction. Entropy demanded a distinct “arrow of time,” and descent with modification meant that life was growing more and more varied with time.


Thus, despite being subsumed into the bleak modern worldview, these paradigms seemed to contradict some of its founding assumptions.

But if this were true, and the universe was irreversibly unfolding in some particular direction, which direction was it? Thermodynamics and evolution glaringly contradicted one another on this crucial point. One suggested the world was losing its usable energy and winding down towards the simple uniformity and homogeneity of equilibrium; the other, that the world was becoming ever more differentiated and elaborately structured—even in a “progress towards perfection.”

Well, which was it? Chaos or order? Inert sameness or dynamic novelty? What was the true ending to the cosmic story science was telling?

The resolution of this conundrum would only come with the transcendence of the reductionist paradigm altogether—a process set in motion towards the end of the 19th century, and only fully realized quite recently.
The Birth of Emergence


Reductionism, and the worldview it gave rise to, are predicated on the idea that we can understand reality best by isolating parts from the whole. By first analyzing the components, thought the pioneers of modern science, we can then work our way up to an understanding of the totality—because, after all, isn’t the whole just a sum of its parts?

Well, it just so happens: Nope, it’s not. It’s really, really not.

We know now something that the early scientists didn’t (and couldn’t): that when it comes to the more complex realities of nature, it’s not just about the parts and how they work by themselves. It’s just as much—if not more—about how the parts relate to one another.

Wholes are made not only of parts, but of the relations of those parts. How one part works in concert with another part, and that one with another, and all of them together—those are dynamics that matter as much as the stuff of the parts themselves.

Wholes aren’t just things—they’re also processes.

Unfortunately, these inter-related dynamics are precisely what get lost when you break apart a whole and just consider its parts in isolation. Just as you’d destroy the life of an organism if you dissect it, so do you destroy some of the most vital aspects of genuinely novel wholes when you cut them up. Separation into parts destroys the connections, and the connections are what make it what it is.

In this way, the full truth of things lies, it turns out, in precisely what the early scientists did their best to systematically remove: relationality, interconnectivity—that is, complexity.

This is why it would take a science of complexity to fill in the gaps left by the reductionistic paradigm and fix the errors it introduced, even as that paradigm was itself an advance over the confused holism of traditional religion. But this would take some time to… well, emerge.

Eventually, though, as modern science progressed, and certain phenomena remained doggedly immune to reductionistic analysis (particularly life and mind), some influential thinkers began to take notice and theorize along the relational lines expressed above. They recognized that there was something that a consideration of parts alone failed to provide, and that reductionism had been missing a bigger picture.

The philosopher John Stuart Mill was one of the earliest such thinkers in this vein. Already in 1843, he presciently wrote in his book A System of Logic:


All organised bodies are composed of parts, similar to those composing inorganic nature, and which have even themselves existed in an inorganic state; but the phenomena of life, which result from the juxtaposition of those parts in a certain manner, bear no analogy to any of the effects which would be produced by the action of the component substances considered as mere physical agents. To whatever degree we might imagine our knowledge of the properties of the several ingredients of a living body to be extended and perfected, it is certain that no mere summing up of the separate actions of those elements will ever amount to the action of the living body itself.

Contrary to the assumption of the reductionists, Mill said, the whole is not just a sum of its parts. The behavior of life seemed to conform to principles that depended on the parts working holistically in concert, and thereby creating something truly novel.

Life and mind clearly presented problems for the reductionist view of science—problems future thinkers would attempt to resolve in this vein. In his 1874 book Problems of Life and Mind, the philosopher George Henry Lewes picked up Mill’s line of thought and extended it, coining a new term for the sort of phenomena Mill had put his finger on. He called them “emergents.” “Every resultant,” Lewes said,


is either a sum or a difference of the co-operant forces; their sum, when their directions are the same—their difference, when their directions are contrary. Further, every resultant is clearly traceable in its components, because these are homogenous and commensurable. It is otherwise with emergents, when, instead of adding measurable motion to measurable motion, or things of one kind to other individuals of their kind, there is a co-operation of things of unlike kinds. The emergent is unlike its components insofar as these are incommensurable, and it cannot be reduced to their sum or their difference.

So began the “British Emergentist” movement of the late 19th and early 20th centuries, which included Lewes, as well as figures like Samuel Alexander, C. D. Broad, and Conway Lloyd Morgan. Their radical idea: emergent wholes are more than the sum of their parts. With this crucial insight, the British Emergentists would lay the groundwork for future theories of emergence, such as are today a mainstay of complexity science.

Recognizing that, in the case of emergents, wholes are more than the sum of their parts, it was clear that certain properties only pertain at certain levels of existence.

To use a common contemporary example, water is wet, but a single H2O molecule is not. Even though water is just a large collection of these molecules, the quality of wetness doesn’t arise until you reach the macro-scale. Zoom in and wetness disappears; zoom out and it emerges. “More is different,” a common refrain in emergence theory, means that more complexity in a system causes the qualities of its higher-level wholes to differ markedly (and often unpredictably) from those of its lower-level parts. The universe, it turns out, has different levels, and these different levels have their own laws.

The tiered, hierarchical nature of reality thus becomes an important aspect of emergence theory. Alexander, writing in his 1920 book Space, Time, and Deity, writes:


The emergence of a new quality from any level of existence means that at that level there comes into being a certain constellation or collocation of the motions belonging to that level, and this collocation possesses a new quality distinctive of the higher-complex. …The higher-quality emerges from the lower level of existence and has its roots therein, but it emerges therefrom, and it does not belong to that lower level, but constitutes its possessor a new order of existent with its special laws of behavior.

These “levels” emerge when more and more of reality is taken up and included together in deepening webs of relationship. That is how the universe complexifies through cosmic evolution. So Morgan stated in 1922, later published in his work Emergent Evolution, that just what emerges is precisely “some new kind of relation…at each ascending step.” Such a theory of new orders of reality implies, says Morgan:


(1) that there is increasing complexity in integral systems as new kinds of relatedness are successively super-venient; (2) that reality is, in this sense, in process of development; (3) that there is an ascending scale of what we may speak of as richness in reality; and (4) that the richest reality we know lies at the apex of the pyramid of emergent evolution up to date.

Perhaps this cosmic “pyramid” of “levels” and “ascending scales” is starting to sound a bit familiar? Despite taking a mortal blow from modern reductionism, was something like the “Great Chain of Being” (the metaphysical framework for holistic traditional religion) coming into focus in the Emergentist view of the world?

Despite similarities, there are also certainly crucial differences between these visions of a tiered cosmos. For one, the hierarchy of the early Emergentists was not value-based (evil to good), but complexity-based (simple to complex [“richness in reality”]). More importantly, there was no dualism here; the Emergentist hierarchy, though parting with reductionism, still allowed one to “keep the view that there is only one fundamental kind of stuff” as C. D. Broad put it in his 1925 book, The Mind and Its Place in Nature. This means that all scales remained natural, not supernatural—which leads to a fascinating implication: the “apex of the pyramid” here is not a supernatural Deity, but a natural (if emergent) “God.” So Alexander remarks in Space, Time, and Deity:


As actual, God does not possess the quality of deity but is the universe as tending to that quality… Thus there is no actual infinite being with the quality of deity; but there is an actual infinite, the whole universe, with a nisus [i.e., goal] toward deity… Deity is nisus and not an accomplishment.

We shall return to such fascinating implications for theology in the next chapter.

The British Emergentists had hit on a powerful idea, emergence, opening an entirely new metaphysical map of reality that could lead beyond reductionism. Unfortunately, timing is everything, as they say. And, as it happened, an explosion of discoveries in general relativity and quantum mechanics beginning in the early 20th century would effectively steal the show for the next generation of scientists, putting emergence on ice—at least until its big return in the 1980s, when complexity science would come fully into its own.
The Rise of Complexity Science


In the interim, from the 40s to the 60s, the effort to find a more scientifically rigorous holistic framework for life and mind continued with the development of new disciplines like cybernetics and general systems theory—key paradigms within the neo-holistic science of complexity.

As its founder, Ludwig von Bertalanffy, put it: “General system theory is a general science of ‘wholeness’ which up till now was considered a vague, hazy, and semi-metaphysical concept.” Cybernetics and general systems theory succeeded in breaking out of the limitations of the reductionist paradigm by considering the relational dynamics of complex systems, and pioneered important theoretical concepts like non-linearity, self-organization, and autopoiesis (or “self-construction”).


Key to von Bertalanffy’s systems-view of living organisms was the insight that they are decidedly not “closed systems,” such as the ones reductionistic scientists liked to study, but were in fact “open systems,” allowing free exchange of matter and energy with their environment. As he put it:


[T]he conventional formulation of physics are, in principle, inapplicable to the living organism being open system having steady state. We may well suspect that many characteristics of living systems which are paradoxical in view of the laws of physics are a consequence of this fact.

That is, life had escaped understanding in terms of classical physics precisely because it was, contrary to the “isolated systems” studied in fields like thermodynamics, connected to and in direct relationship with its environment by flows of matter and energy.

All of this would eventually lead to a truly revolutionary discovery—beginning a whole new field called non-equilibrium thermodynamics—which would contribute immensely to a radical re-conception of how energy behaves, and thus how life itself emerges and operates.

These paradigm-shifting breakthroughs were pioneered by a Belgian chemist named Ilya Prigogine. By Prigogine’s time, science had established clearly how energy behaves in closed systems: The fixed amount of energy dissipates, order and organization dissolve, and everything reaches a featureless, disordered balance called equilibrium. Such was entropy, whose increase was demanded according to the second law.

But, Prigogine wondered, what if the system isn’t closed, but opened up to a flow of energy? That is, let’s say we’re not looking at water in a closed thermos anymore, but a pan of water over a lit stove. How does the system behave now?

Simple as the idea was, the results were truly extraordinary. For, rather than spontaneously dissolving towards the disorder of equilibrium, the water in this scenario does the opposite: it spontaneously self-organizes, and structure emerges!


Structures like this (called Bénard cells, after their original discoverer Henri Bénard) arise naturally, fueled by the energy flowing into the system. In fact—and here’s the amazing part—they arise precisely in order to dissipate that energy and generate the entropy demanded by the second law of thermodynamics! They emerge naturally because such configurations are simply more efficient at producing that entropy than more chaotic, disordered ones.

A much more familiar example of such a dissipative structure (as Prigogine called them) is the whirlpool that appears in your bathtub when you pull the stopper. This highly ordered spiral gyre emerges naturally and spontaneously as the result of countless water molecules self-organizing. Why? Because such a configuration actually allows the water to drain faster.

The natural tendency of the universe to seek balance and equilibrium can actually propel systems to become temporarily more ordered to achieve this end. That is, the same law that drives closed systems towards disorder and equilibrium actually drives open systems to generate order and complexity—and to remain “far from equilibrium,” in fact, as long as that flow of energy into the system persists.

If this dynamic sounds familiar, it should. This is precisely the way that all living organisms operate, too! For life to accomplish all of the complex processes it must perform to resist entropy and stay highly ordered, it must be continually taking in new energy sources to metabolize.

Or, in terms more familiar to us: If you don’t eat, you die. Life is always in relational exchange with its environment—a complex, open system, in which the second law operates to facilitate self-organization, keeping it far from equilibrium (i.e., death).


This revolution in our conceptualization of thermodynamics has fueled a spate of discoveries related to the question of how life emerged in the first place. In 2013, for instance, Japanese researchers showed that shining a light on silver nanoparticles caused them to spontaneously self-organize into more orderly configurations that could capture and dissipate the light’s energy more efficiently.

In 2015, it was shown that introducing an electric charge to conduction beads in oil caused them to self-organize into a dissipative structure with “wormlike motion,” which continued as long as the flow of energy persisted.

In 2017, Jeremy England of MIT published findings from computer simulations showing “dissipative adaptation,” in which molecules spontaneously self-organized into improbable configurations specifically adapted to the frequency of the energy source they were dissipating. The configurations that were maintained did so by outcompeting other possible configurations by more effectively producing entropy, suggesting a proto-Darwinian process of variation and retention in the struggle for energy consumption.

Evolution itself, then, can be understood in thermodynamic terms: specifically, as the goal of organisms to remain far from equilibrium. To do so requires them to effectively extract and dissipate free energy from the environment. Because energy resources (i.e., food) is limited, this competitive process fuels the Darwinian “struggle for existence,” in which successful organisms breed and unsuccessful ones are weeded, leading to further organization and the complexification of species.

Based on such discoveries, an additional law of thermodynamics has been proposed (first by Alfred Lotka and later by H. T. Odum) that includes the evolutionary implications of energy: “During self-organization, system designs develop and prevail that maximize power intake, energy transformation, and those uses that reinforce production and efficiency.”

Energy self-organizes matter into life, and life self-organizes by maximizing energy. Or, as complexity scientist Harold Morowitz put it, “The energy that flows through a system acts to organize that system.”

In this way, the dynamics of life became considerably clearer—not by looking at smaller and smaller parts (the way reductionism sought—and failed—to make sense of things), but by considering precisely the opposite: the relationship with the broader whole in which parts are embedded.

More than that, a consideration of how the whole is changing can inform our understanding of the parts. In this case, the whole is the universe itself and the parts are everything in it. The fact that the universe as a whole is expanding means that the second law does not require that everything one day end in heat death. This assumption was likely far too hasty. The great complexity scientist Stuart Kauffman summarizes this point in reassuring terms in his 2016 book Humanity in a Creative Universe:


The second law says free energy is running down. But we know now that the expansion of the universe is accelerating due to the mysterious dark energy that comprises about 70 percent of the energy of the entire universe. The implications of this accelerating expansion is that we do not have to worry about enough free energy. As the universe becomes larger, its maximum entropy increases faster than the loss of free energy by the second law, so there is always more than enough free energy to do work.

The takeaway? The initial conclusions scientists had drawn from the laws of thermodynamics were wrong: the universe was not destined only to grow more and more disordered with time. That idea arose on the false assumption that isolated systems could tell us everything we needed to know about energy.

But opening the system changes the whole story: energy also spontaneously organizes things—a revolutionary insight, considering that there are no truly isolated systems in nature! In the real world, everything is connected, everything is permeable, everything flows. Even that insulated thermos will dissipate its energy eventually. The universe is not a laboratory of isolated variables, but a tapestry of endlessly interweaving relations.

That is, after all, precisely what the early scientists were contending with, and did their best to systematically remove from the equation (literally). Today, bringing complexity back in is what is allowing us to understand reality better, and fix our sense of how the parts and the whole relate.

As Prigogine, who won the 1977 Nobel Prize in chemistry for his discoveries, put it:


[T]he importance we now give to the various phenomena we observe and describe is quite different from, even opposite to, what was suggested by classical physics. …The models considered by classical physics seem to us to occur only in limiting situations such as we can create artificially by putting matter into a box and then waiting till it reaches equilibrium.

But take nature out of the box, and entirely new laws come into play! The second law leads to order, not disorder, and the interconnected universe is seen for the continually self-organizing process it is.

This self-organizing dynamic is a naturally cumulative, snowballing process that keeps building on itself—a process Prigogine called “order through fluctuation.” As energy pushes open systems farther from equilibrium, fluctuations in the energized system lead to threshold “bifurcation points,” at which the system is presented with novel, higher-order configurations as potential next stages of its evolution.

As systems scientist Erich Jantsch explains in his book The Self-Organizing Universe:


At each transition, two new structures become spontaneously available from which the system selects one. Each transition is marked by a new break of spatial symmetry. The path which the evolution of the system will take with increasing distance from thermodynamic equilibrium and which choices will be made in the branchings cannot be predicted. The further the system moves away from its thermodynamic equilibrium, the more numerous become the possible structures.

In this way, more and more complex structures evolve as energy flowing through the system naturally and spontaneously pushes it ever onwards, toward increasingly novel forms. The universe organizes itself.


With these insights (still unknown to many in the general public even today), the apparent conflict between thermodynamics and evolution was resolved. There was indeed an arrow of time, and the question of which direction it was heading in was clear.

Evolution had suggested an increase in novelty, diversity, and complexity; now, thermodynamics agreed. More than that, it actually helped explain why and how complexification occurs, by linking the evolutionary process to free energy and emergent self-organization.

In this way, evolutionary development was no longer something unique to life, but a process that could be expanded to include less complex matter, too. In his book Cosmic Evolution: The Rise of Complexity in Nature, Eric Chaisson writes:


Life is an open, coherent, spacetime structure maintained far from thermodynamic equilibrium by a flow of energy through it—a carbon-based system operating in a water-based medium, with higher forms metabolizing oxygen. Although the second part of this definition pertains to the living state as we know it, the first part could well apply to a galaxy, star, or planet… And that is the crux of our argument: Life likely differs from the rest of clumped matter only in degree, not in kind.

The degree to which it differs is one of complexity—for which Chaisson employs a specific metric, one that can be used to measure the complexity of anything from stars to living organisms: free energy rate density.

As systems theorist Ervin László summarizes it in his pioneering book Evolution: The Grand Synthesis:


Free-energy flux density is a measure of the free energy per unit of time per unit of mass: for example, erg/second/gram. A complex chemical system retains more of this factor than a monatomic gas; a living system retains more than a complex chemical system. This indicates a basic direction of evolution, an overarching sweep that, together with the decrease of entropy and of equilibrium, defines the arrow of time in the physical as well as in the biological and the social world.

Free energy flows through systems, organizing them into more orderly configurations. Order builds upon order, and complexity mounts—until whole new emergent levels appear, like life from matter. In this way, complexity is really just a measure of how energy organizes matter—something it has been doing to exponentially greater degrees as time passes.

In Cosmic Evolution, Chaisson charts this evolutionary increase in free energy rate density, offering a compelling visualization of the complexification of the universe to date:


In this way, the entire cosmos has been evolving—matter naturally self-organizing into stable forms through the flow of energy, leading to life, and life evolving through natural selection, leading to still more complex species.

As it does, something else emerges: agency. Work by complexity researchers like Sara Walker, George Ellis, Giulio Tononi, Erik Hoel, and others has shed considerable light on the way more complex organisms come to exhibit causal power on their lower-level constituent parts. Such causal emergence repudiates the old deterministic account of organisms as being nothing but particles in motion. Rather, it shows that information generated at higher levels can have a causal effect on its material substrate. In this way, there is not only “bottom-up” causation from particles, but also “top-down” causation, as information encoded in patterns of organization at the macro-level works to direct material particles at the micro-level towards specific states and goals.

Such causal emergence appears for the first time in earnest with the origin of life, as information in the genome is able to supervene over the molecular and atomic level, leveraging the parts towards the aims of the biological whole. This sort of agency gains entirely new levels of causal freedom and power, however, with the rise of more complex minded animals. In this way, the self-consciousness such as human beings exhibit can be understood as a uniquely complex form of causal emergence, whereby activity at the mental level exerts itself over and above the activity of the body. In this way, the will itself emerges. We are, then, not just determined automatons the way reductionists like Laplace envisioned, but genuinely free agents with self-determination, whose choices matter.


In sum, with the implications becoming clear from this profound paradigm shift in the sciences, we now find ourselves facing an entirely new cosmic story, a mind-bending vision in which the universe has been, of its own accord, bringing all things together in more novel and intricate forms, producing order spontaneously from its originally featureless chaos in an uninterrupted evolutionary process that has led from unconscious, deterministic material at the lowest level to self-conscious agents with free will at higher levels.

Far from being a depressing dissolution or undirected slog of “frisky dirt” evolving nowhere, there is, we now see, a great epic of complexification underway, the “epic of evolution” as Chaisson calls it, as new wholes emerge, interact in new webs of relation, and then form parts in even higher-level wholes, such as lead to subjectivity, self-awareness, and free will.

Okay, but what is the real significance of all this? What is this grand story of complexification really telling us? What does it reveal about the nature of reality and our place in it? Now that we have traced some of the historical context, showing how knowledge advanced from a pre-scientific religious holism, to the primitive science of reductionism, and onwards still to a neo-holistic science of complexity, we can finally consider what all of this really means in the broadest terms. For that, we must turn to some unifying theories that bring it all together.



Emergentism: there is no chapter 7





Emergentism | Chapter 1: From Religion to Reduction


I wish to present Brendan Graham Dempsey's discourse on designing new civilizations of ecology, religion, science, and cultural behaviours, as aligned with my own these past many years. And though I have been steadily applying AN Whitehead's Process Philosophy to all human disciplines, I sense Brendan's Emergentism group is eclectically picking-and-choosing across a similar space which I have described in the past as the additive parts to the whole of process thought as an integral philosophy to all previous thoughts and constructs. Hence, I deem Process Philosophy as a broadly holistic construct in which all other constructs fit within such as process theology, process religion, process science, process evolution, process ecology, and so... including the area of emergentism. So, let's get to it and see where emergentism goes as an eclectic practice drawing across a variety of thought systems in reviving and resurrecting global, regional and local cultures for the 21st Century.

R.E. Slater
June 1, 2024


Emergentism | Chapter 1:
From Religion to Reduction

SEP 13, 2022


Parts and Wholes

Emergentism, as its name suggests, is about emergence. But what is emerging, and out of what does it emerge? Well, broadly speaking, we can say that new wholes emerge out of lower-level parts.

All wholes are made up of parts, which have their own particular qualities. However, when parts come together to create a distinct new entity with its own unique and irreducible qualities, then you get a whole. It’s pretty much that simple.

Think of an orchestra as an analogy. It has a string section and a brass section, the woodwinds and the percussion. Each section has its own unique characteristics, its own timbre, range, and tone. But when you bring them all together, something special happens. They create something unique. When combined, all work as one—literally, “in concert”—all parts harmonizing together into a new distinctive whole that none could accomplish on its own: AKA, the symphony. Sounds pretty, doesn’t it?

Of course, once you start thinking in these terms, you recognize that this part-whole pattern goes even deeper. For instance, the string section of an orchestra is, in turn, made up of its own parts: violins and violas, cellos and basses. Each of these instruments likewise has its own unique characteristics at an even smaller scale. When brought together, they form a second-order whole: the string section.

So a whole orchestra is made up of whole sections, which are in turn made up of whole instrument groups, which are of course made up of whole instrumentalists—and so on.

Parts, then, are just lower-level wholes themselves. Parts form wholes, and those wholes serve as parts in even greater wholes. Theoretically, the process is unlimited.




Once you have this basic idea in your head, you can start to look at everything in the world this way. Anything you consider will be a whole made up of smaller parts, which in turn may be considered in terms of its parts, and so on.

Okay, you say; that’s all well and good—but so what? Why does this matter?

Surprisingly, it actually matters quite a lot. For one thing, it matters for what matters. Bold as the claim may be, I think we can actually trace the origins of the meaning crisis to the way we think about parts and wholes.

The assumptions we make about these truly fundamental concepts can have profound implications for our worldview. And a worldview with a broken sense of how parts relate to wholes can break our relationship to the whole world. And isn’t that precisely what has happened?

Consider, for instance, that meaning itself is a whole-part relationship. For something to have meaning, it must be a means—that is, it must exist for something else, as a means to something else. It must have a causal significance, we would say, in something “bigger” than itself.

In the context of the orchestra, each musical part has a meaning that’s intelligible only at the level of the whole. Any violist will know (especially since they tend to get the harmonies and not the melodies) how meaningful their contribution is, not at the level of their part alone (which is fundamentally relative and incomplete), but in concert with the rest of the orchestra.

Indeed, you could say, the violist’s part in a Beethoven symphony, for example, is virtually meaningless outside the context of the rest of the orchestral score. Simply put, to have meaning is to be an important part in a larger whole.

If, then, our sense of the relationship between parts and wholes becomes corrupted, we are at risk of losing our very sense of meaning itself—just as, in fact, we have done. We have become parts without a whole, at the same time that we cannot even claim to be whole ourselves.

But how did that happen? And is there anything that suggests we might be able to find our way out of this fractured way of thinking?

As it turns out, the answer to both of these questions is the same: the development of science…

Holistic Religious Traditionalism

All light casts a shadow, it is said. Progress creates its own problems. This, of course, doesn’t mean we should shun the light and resist any kind of advancement—only that we should always be seeking to cast new light on the shadow and keep progressing beyond today’s new problems.

We need to remain vigilant to correct for the new errors that our very attempts at error-correction may introduce along the way. In fact, that itself is science, and the continual refinement of knowledge that keeps refining our worldview.

When the scientific method was first developed in earnest in the 1600s, and geniuses like Galileo and Newton began to reveal the hidden patterns of reality with astonishing precision and predictive power, the world entered a new phase. Modernity as we know it had begun.

The break from the pre-modern world was profound and irrevocable. The conclusions that scientists were drawing from their data were of a radically different sort than those espoused by the prevailing dogmas of the day—mythic and religious conceptions of the world rooted in centuries of tradition.

The traditional religious worldview had, by this time, its own highly developed ideas, complete with its own metaphysics (fundamental philosophical presumptions about how reality works) and cosmic story.

According to the metaphysical framework of the traditional worldview, everything was significant, everything hung together, everything was connected. The universe was one great whole made up of different levels or grades of being.




This “Ladder of Nature” or “Great Chain of Being” (as it came to be formulated) connected everything in Creation, from God at the top, to angels in heaven; humans, animals, plants, and minerals on Earth; all the way down to demons and the Devil in hell.

Nor was this idea unique to the West. The East had its own version of the Great Chain, stretching from Ultimate Reality (Brahman, Nirvana) down through the heavenly devas in their divine abodes, to the earthly realm, and finally to the hell realms.

In fact, this conception was so cross-culturally universal, it has been called the basis of the “perennial philosophy” of the traditional worldview.




Set within this metaphysical framework, like the performance of play upon a stage, was a traditional cosmic story. In Christian Europe just before the scientific revolution began, this story was one of a divine creation, a sinful fall from grace, a divine redemption, and a coming judgment.

In the beginning, God created the world, including humans and all the animals, to exist in an originally perfect state. But humans were quickly tempted by the Devil to transgress against God’s will—the punishment for which was a mortal life of suffering, ending in eternity in hell. God, however, sent down his Son from heaven to redeem the fallen world and thereby allow humanity entrance into heaven. His return is imminent, whereat all of the world will face judgment, and either be thrown into hellish torment or risen up into heavenly bliss. In the interim, believers have the responsibility to save as much of the world as possible by spreading the good news of salvation to unbelievers, and so ready the Earth for the coming judgment.

In this way, humanity was believed to play a part in the whole cosmic narrative. All were actors—and important ones—in the divine drama. An individual life by itself might seem full of confusion and suffering; but in the wider context of the whole divine plan, it had meaning. Humanity was part of something bigger, a higher purpose under a higher power.

As those who attended regular church services (which is to say, pretty much everybody) would have heard read from the Bible at the pulpit then:

Just as a body, though one, has many parts, but all its many parts form one body, so it is with Christ. For we were all baptized by one Spirit so as to form one body… Now you are the body of Christ, and each one of you is a part of it. …If one part suffers, every part suffers with it; if one part is honored, every part rejoices with it.(1 Corinthians 12:12, 27, 26)

Under God, the inherent connectedness of everything rendered everything potentially significant and full of meaning. The stars above could be read for what events they foretold, and what impact they had on one’s life. The ancient dictum “as above, so below” demanded that the earthly and heavenly, the whole and the individual, were intimately related—even models or types of the other. And similarities of any kind between two things—shape or color, for instance—could be interpreted as meaningful ties with real causal significance.

Actually, to say that the pre-modern, traditional worldview allowed people to feel like meaningful parts of the whole might be putting the cart before the horse. To even recognize a part-whole relationship first requires a differentiation process, whereby the whole can be differentiated into its distinct parts. If this isn’t done, or done only minimally, then part and whole remain (con)fused, undifferentiated, indistinct.

Surprising as it may sound, the categories of “subjective” and “objective” only come to full prominence with modernity, meaning that people tended to blur these categories much more in the past than we do today. In the modern world, people separate their experience of reality from reality itself. In the pre-modern world, this was not done in the same way or to the same degree.

With considerably less distinction made, people’s experience felt more whole. They experienced reality as more holistically intuitive, since there was no profound divide between inner and outer worlds. The world was one. As within, so without.

Appreciating this allows us to understand the Great Chain itself much better, since it presents a cosmic whole arranged by levels of value.

God, the best thing imaginable, is on the top; the Devil, the worst thing, on the bottom. Value was inherent to the world, an aspect of things themselves, as they really are—and not just something we subjectively overlay on top of a value-neutral objective world. Meaning, then, was something real—as real as rocks and trees and tables. And the cosmos itself was ranked by an “ontological normativity”—a metaphysical hierarchy where value and being were fused.

The upshot of all this was that, whatever else plagued it, and whatever other pathologies it may have been prone to, the traditional religious worldview was certainly not threatened by any meaning crisis. Meaning was everywhere, all around. Everything was meaningful, charged with significance, part of an intrinsically value-laden cosmos and a divine narrative that had a role for every soul to play.

But all of that would change. For, with the advent of early modern science, an entirely new conception of the part and the whole comes to the fore—and, with it, an entirely new worldview.

The Rise of Modern Science

The world, we all know, is immensely complex. The word “complex” comes from Latin and means “woven together.” And that is indeed an apt metaphor, since all you have to do is look around you to see the countless varied phenomena endlessly interacting, intermingling, and interrelating in infinite combinations.

A worm eats the decaying leaf of a tree, helping both fertilize and aerate the soil the tree itself grows in, allowing more water to be soaked up from the ground, which a storm, whose lightning put nitrogen in the soil for the tree, dropped after being pushed along by weather currents influenced by the forest (including the tree) on which it fell

The world is an infinitely rich tapestry of different threads all interweaving in a dizzying array of combinatorically explosive ways!

Beautiful as this tapestry is, though, its endlessly interrelated lines make the whole impossible to understand with any clarity or certainty. To the inquiring mind eager for greater knowledge of reality, the intricate braid starts to feel like a twisted knot. Follow one thread, and immediately you become lost in a tangle of confusion and uncertainty. Where one line of causation ends and another begins is impossible to tell in the interlaced lattice of life’s complexity.

What can we ever know about anything, when everything is bound up with everything else?

The genius of the early modern scientists was to slowly, patiently, methodically, unravel from the snarled mess one single strand for study. Then, and only then, could they measure, assess, and know, with certainty, the properties of something, where before there was only ignorance. With this, they could then begin to see how each strand relates to the others and piece together how reality behaves as a whole—since what is a whole but the sum of its parts?




Think of it this way: If you’re making a loaf of bread from scratch, but keep getting vastly different results, what do you do? Well, you could change a few different things each new loaf you make—but if one comes out perfect, how will you know just what you did right in order to repeat it? Was it the longer rise time, the higher temperature, or the extra yeast that did the trick? You’ll never know, unless you try adjusting each one individually. Only once you’ve isolated each variable will you be able to write the official recipe—and get perfect loaves every time.

This is how we’ve come to use rationality to analyze the world. The word “analyze” means, literally, “to break apart.” By breaking the world into its parts and assessing each one in isolation, the early modern scientists hoped to gain an understanding of how the whole loaf of reality works.

And, in countless crucial ways, they did! The astonishing triumph of modern science (as well as its limiting weakness, as we’ll see) lay in this: its isolation of the part from the whole.

When Galileo set out to understand the fundamental principles of motion, he didn’t go outside and look at the trees swaying in the wind or the water rushing down a river. (There are, we would now say, far too many variables to account for in such a context.) Instead, he went inside, shut out the noisiness of nature, and devised a controlled experiment—one that intentionally weeded out any possible interference with the one variable he wished to isolate and study. He reduced the vast number of potential interacting phenomena to a single, isolated instance more amenable to scrutiny—rendering the complex simple. Removing the part from the relentless interference of its contextual whole, he was able to discover a definite and repeatable pattern of behavior, and thereby establish universal principles. The simpler part could then be used to explain the much more complicated whole. In this way, complex phenomena could be seen as ultimately reducible to their simpler parts.




This was the methodological insight that broke the world wide open for infinitely greater understanding and technological progress, yielding a torrent of entire fields of knowledge and the practical industries based on them.

It was also, in its way, what broke the world.

This methodical approach—which has come to be called reductionism—became the essence of the early scientific enterprise. Once the first scientists began their analytical studies, breaking the world into its parts to explain how things work, they set off a domino cascade of dissection: the isolation of smaller parts led to the realization that those parts were themselves actually wholes made of still smaller parts—and so on and so forth.

A few decades after Galileo, Robert Hooke peered through his microscope and discovered that a plant organism was made of smaller parts, which he called “cells.” In 1811, Amedeo Avogadro wrote of even smaller parts, which he called “molecules,” following only shortly after John Dalton’s articulation of the modern theory of atoms in 1803. In 1897, with the discovery of the electron, J. J. Thomson declared that even the “uncuttable” atom had parts—a realization that ushered in a rash of subatomic particle discoveries in the early and mid- 20th century, crowned as recently as 2020 with the discovery of the famed Higgs boson.

With each lower level of discovery, the explanation for how the world works was reduced a step further. Each deeper part was considered more fundamental than the last, as the behavior of life might be explained by cells, cells by molecules, molecules by atoms, and atoms by subatomic particles.

As this reductionist approach took hold, it was increasingly believed that everything could be explained in this way. Even the most seemingly complex phenomena could be understood, in the last analysis, as the composite machines that they actually are—including living organisms and, yes, human beings, too.

So, as early as 1651, the philosopher Thomas Hobbes could confidently proclaim:

For seeing life is but a motion of limbs, the beginning whereof is in some principal part within; why may we not say, that all ‘automata’ (engines that move themselves by springs and wheels as doth a watch) have an artificial life? For what is the ‘heart’ but a ‘spring’; and the ‘nerves’ but so many ‘strings’; and the ‘joints’ but so many ‘wheels,’ giving motion to the whole body, such as was intended by the artificer?

If the world is ultimately explicable in terms of its components—that is, if the whole is ultimately no more than the sum of its parts—then life itself, like everything else, is ultimately no more than mechanical particles in motion.

In fact, many recognized, if this is so, and if the complete course of bodies in space can be determined by of laws of motion devised by Galileo and Newton, then everything is already pre-determined! Theoretically, knowing the position and velocity of all the particles in the universe would allow you to deduce its entire history and future, since the universe is governed by the same physical principles as billiard balls colliding on a pool table.




The famous scientist Pierre Simon Laplace declared as much in 1795, writing:

We may regard the present state of the universe as the effect of its past and the cause of its future. An intellect which at a certain moment would know all forces that set nature in motion, and all positions of all items of which nature is composed, if this intellect were also vast enough to submit these data to analysis, it would embrace in a single formula the movements of the greatest bodies of the universe and those of the tiniest atom; for such an intellect nothing would be uncertain and the future just like the past would be present before its eyes. (“A Philosophical Essay on Probabilities”)

Determinism, which followed ineluctably from the logic of reductionism, meant that human beings, despite our experience, actually had no free will at all, and that our sense of being autonomous agents was actually, at base, just an illusion.

True causal power only existed at the level of the smallest part, which science revealed to be mechanical and deterministic. Everything higher up, any higher whole, was ultimately driven by that deeper logic—because surely wholes are no more than the sum of their parts.

Reductionism and the Meaning Crisis

As reductionism became more and more engrained in the scientific enterprise, and the mechanized world it produced became everywhere more impressive and ubiquitous, the pre-modern world and its religious worldview faded increasingly from sight.

The meaning-rich world of inherent value was replaced by a mechanistic, value-neutral objectivity (described by forces, not feelings). Value could not be shown to be something subject to force and motion, and so must not be fundamentally real. Values exist only in our minds, then—such that there must exist a sharp divide between the subjective and the objective. Mixing them together is the source of endless confusion, since, ultimately, only the objective world is real.

Likewise, with the explanatory power that particles and forces provided, there was no longer any need for supernatural explanations of phenomena. (As Laplace answered Napoleon when asked about the absence of God from his work: “Sire, I had no need of that hypothesis.”) Nor did mere associations or “correspondences” serve a use any longer, nor the supposed influence of the stars—which Newton had shown to be governed by the same laws as prevail on Earth. Everything could—or would—be explained by simple material part-icles in motion: a metaphysical framework known as materialism.

Thus, with the triumph of reductionism, the entire religious edifice of tradition cracked, its metaphysical Great Chain and cosmic story rapidly eroding. In its place was modernity’s new worldview—with its own metaphysics and unnerving new narrative.

This metaphysical framework was valueless. The hierarchy of reality was not organized by good and evil, only size—and the smallest parts were the most important. There was no personal God, only deterministic laws that govern the universe—and these were as indifferent to humans’ existential lot as any machine. Whatever could not be described in terms of fundamental particles in motion was either a fiction or an illusion.

The cosmic story of this worldview was, as a consequence, radically different from that of traditional religion. Having stripped a benevolent God of any causal power, there was no providential “creation” per se; the universe just was (and presumably always was; or, if it did have a beginning, arose from chance).

There was no divine drama or omniscient Plan. Human beings, and all life, were essentially just complicated machines, governed not by their agency but by their constituent parts following deterministic paths through space. And just as there is no meaning to turning gears or pumps, neither is there any meaning, ultimately, to human life.




In this way, it should be clear that reductionism was what first sowed the seeds of our contemporary meaning crisis. With the rise of modern reductionistic science, humanity’s role in a divine saga was lost, and the perceived whole of conscious human life itself was reduced to its smallest parts—where one no longer finds any meaning, only law.

This idea continues to reverberate and resonate today. Millions of despairing souls still believe it—and it is driving them to the nihilistic conclusions nascent in it. Until, at last, here we are: We have become parts without a whole, at the same time that we cannot even claim to be whole ourselves.

Our lives lack the larger context of a cosmic story in which we play an important causal role. Nor can we even claim to be genuine agents with volitional integrity, since our wills and even our conscious awareness itself are merely “epi-phenomenal” illusions: vestigial byproducts of particles acting in deterministic fashion deeper down.




By the dawn of the 19th century, through relentless differentiation of parts from the whole, modernity had revealed reality in all its countless sundered pieces. The subject had been cleaved from the objective world, value had been parsed from existence, and causation was sundered from conscious will to obtain only at the lowest material level of the universe.

If there were any “grand design,” it was no more than the indifferent mechanical workings of a clock—the sort which the modernist Robert Frost would evoke in a poem of modern alienation and nihilistic despair:

And further still at an unearthly height,
One luminary clock against the sky
Proclaimed the time was neither wrong nor right.