Vibrations: Difference between revisions

Samual Butler: “All thinking is of disturbance, dynamical, a state of unrest tending towards equilibrium.”^[1]

In Vibrations (1885), Samuel Butler reflects that he had made three contributions to the theory of evolution:

(1.) In Life and Habit (1877) Butler had established the relation between heredity and memory.

(2.) In Evolution Old and New (1879) he had reintroduced teleology into organic life

(3.) In Unconscious Memory (1880) he had suggested an explanation of the physics of memory and made a connection between consciousness and evolution. ^[2]

The theory of vibrations, which is outlined in Butler's Notebooks (1885), represents an extension of Butler’s evolutionary scheme. Charles Darwin had proposed natural selection but was unable to explained how natural selection occurs. How are units of inheretence transmitted? Darwin had put forward the theory of pangenesis, which proposed that genetic characteristics are past on through generations by particles of inheritance called gemmules.^[3] Darwin suggested that an organism’s environment could cause modifications to the gemmules which are passed through the genitals of the parent to the next generation (this was a modification of Lamark's theory and an an adaptation of a similar theory by Herbert Spencer)^[4]. The theory had some credibility in the 19th century but continued to lose ground as the examination of evolutionary evidence became more granular. In 1900 Darwin's theory became obsolete following the rediscovery of Gregor Mendel’s (1822-1884) work. In the middle of the nineteenth century, Mendel had studied the reproductive behaviour of plants over generations and identified units of heredity (which he called “factors”). William Bateson (1822-1884) adopted the term genes for these units of heredity, which led to the eventual discovery of the encoded script within all living organisms, known as chromosomes.

But we are getting a little ahead of ourselves. Back in 1885 Butler is struggling with the problem of how traits of heredity are transferred from one organism to another. He intuits that it has something to do with information, but what could the medium of transmission be?

Butler hypothesises that there is a universal substance which runs through everything and which, vibrating at different frequencies, takes on different forms. In Butler’s words: “[…] the characteristics of the vibrations going on within it at any given time will determine whether it will appear to us as (say) hydrogen, or sodium, or chicken doing this, or chicken doing the other.”^[5] The universal substance has some relation to the notion of Luminiferous aether, the substance that was believed to act as a medium through which light waves passed ^[6] and which will later, in the popular imagination become the medium for any ineffable thing (including radio waves).

Butler then, imagined the universal substance to be in a state of vibration. This vibration constitutes matter itself and the frequencies of the vibrations constitutes particular kinds of matter. The universal substance modulates difference within the material world. Butler notes that the Universal Substance is both “mental and physical’. This is because, after the introduction of the vapour engine, we understand that mind extends beyond discreet entities. Butler also maintains that the universal substance is mediated through action. In Butler the vibrations constitute a network of communication, patterns which establish the conditions for reproduction and adaptation: “May we imagine” writes Butler “that some vibrations vibrate with a rhythm which has a tendency to recur like the figures in a recurring decimal, and that here we have the origin of the reproductive system?”^[7]

Vibrations and the Universal Substance: Butler, William and Gregory Bateson

Frequency variation in zebra stripes

The polymath Gregory Bateson (William Bateson's son) in his collection of textsSteps to an Ecology of Mind, makes a connection between his father and Samuel Butler which identifies modulations of communication both in nature as registers of difference:

“My father was a geneticist, and he used to say, ‘It's all vibrations,’ and to illustrate this he would point out that the striping of the common zebra is an octave higher than that of Grevy's zebra. While it is true that in this particular case the ‘frequency’ is doubled, I don't think that it is entirely a matter of vibrations as he endeavoured to explain it. Rather, he was trying to say that it is all a matter of the sort of modifications which could be expected among systems whose determinants are not a matter of physics in the crude sense, but a matter of messages and modulated systems of messages. It is worth noting, too, that perhaps organic forms are beautiful to us and the systematic biologist can find aesthetic satisfaction in the differences between related organisms simply because the differences are due to modulations of communication, while we ourselves are both organisms who communicate and whose forms are determined by constellations of genetic messages.”^[8]

A decade later, the younger Bateson acknowledges that he and his father had been following the same course in relation to biological and mental variation, which both operate under the order of difference:

“[…] if we separate off, for the sake of enquiry, the world of mental process from the world of cause and matter, what will the world of mental process look like? And [the elder Bateson] would have called it, I think, the laws of biological variation, and I would be willing to accept that title for what I am doing, including, perhaps, both biological and mental variation, lest we ever forget that thinking is mental variation.” 7

Gregory Bateson identified a continuity of enquiry between Butler, his father and himself which circled around the problematic of systemic order, and which is resolved by a cybernetic reading of homeostasis and negative entropy (the communication of variation): “We (a thin line of thinkers from Lamark, to Fechner, to Samual Butler, to William Bateson) knew that mind must in some way enter into the larger scheme of explanation. We knew that ultimately the theory of evolution must become identical with a resolution of the body/mind problem.”^[9]

WILLIAM BATESON – Evolution, Information and Energy PROBLEMS OF GENETICS

In 1906 Gregory Bateson’s father, William Bateson wrote:

“We commonly think of animals and plants as matter, but they are really systems through which matter is continually passing. The orderly relations of their parts are as much under geometrical control as the concentric waves spreading from a splash in a pool. If we could in any real way identify or analyse the causation of growth, biology would become a branch of physics." 1^[10]

William Bateson, then, established the modern science of genetics by reviving the theories of Gregor Mandel (1822-1884) ^[11] Mandel had identified recessive and dominant traits in successive generations ^[12] Mendel and William Bateson posited specific diversity – whereby mutation within the cell structure of an organism influenced the development of subsequent generations.This granulated approach was closer to Lamark than the orthodox Darwinian approach (which favoured chance as the agent of adaptation, or germ theories proposed by Darwin and Herbert Spencer).^[13] The Bateson-Mandel emphasis allowed for genetic change within a biological system to be transmitted on the level of information, as opposed to the conversion of energy within a closed entropic system. The distinct difference deserves note: dynamic equilibrium requires an exchange of energy whereas homeostasis requires an exchange of information.^[14] From the start of his career Gregory Bateson carried his father’s approach into the heart of his own work, allowing the accommodation of key ideas in relation to pattern and repetition which derived from his father’s work on genetics. ^[15]

In later life Gregory Bateson would make the relation of evolutionary adaptation and information explicit: “My father coined that word [“genetics”] in 1908 – it was still necessary to call the elements of Mendelian heredity ‘factors.’ Nobody could then see or would risk the notion that these must be ideas or chunks of information or command.” ^[16] In Gregory Bateson’s early work as a biologist he had researched the emergent symmetry of pigeons and fish “Even then, I think that the fact of communication and the fact of regularity, symmetry, etc., in anatomy, were going hand in hand.” but it was only twenty years later, when he started his cybernetic research that Bateson was able to recognise the homology between different systems, and that the “regularity in the anatomy of flowering plants was comparable to the regularity which linguists found in language.” Bateson, when referring to his father’s work, often outlines ways in which the elder Bateson anticipated homeostasis and negentropy and intuited evolution and mind as different levels of abstraction within a larger evolutionary system.

William Bateson by Arnold Forster

In Problems of Genetics (1913) William Bateson argues that specific diversity (genetic mutation) allows for variation within a given species. This position is contra to the orthodox reading of Charles Darwin’s doctrine of natural selection. In the opening chapter William Bateson outlines the traditional resistance against the theory of evolution in general and the opposition to specific diversity in particularly. For William Bateson, specific variation is evident in the fossil records of organisms from vertebrates to bacteria: “In all these groups there are many species quite definite and unmistakable, and others practically indefinite.”^[17] It is evident that the evolutionary line is not as simple to read as might be first supposed. As evidence continued to amass after Darwin posited the theory of natural selection, and as this data was analysed and studied, it became increasingly apparent (to William Bateson at least) that variation is neither “evenly distributed” within nature or “arbitrary” and that variation occurs for a number of reasons, which all relate to specific variation.

When this variability is broken down it can be attributed to a number of factors: In part a result of hybridisation; in part a consequence of the persistence of hybrids by parthenogenetic reproduction – in which reproduction occurs without fertilisation (this is common in bees, ants, plants and reptiles); it might be in part due to polymorphism – in which case alternative phenotypes are produced within the same group; or variability may be due to the continued presence of individuals representing various combinations of Mendelian allelomorphs – which indicate alternative forms of the same genes (a gene is understood as a unit of heredity 10^[18]

It is also the case that species “gradually derived from a common progenitor”^[19] continue to thrive in the same environment, they do not render each other extinct, in which case it is a question of difference rather than fitness. Furthermore, a variation is sometimes so common that it loses all definition; take British Noctuid Moths, “Many are so variable that, in the common phrase, ‘scarcely two can be found alike’ ’’.^[20] Variation, therefore, takes place in a multiplicity of local forms for a number of different reasons.

But, having said that, an alligator cannot give birth to a photocopier.

If the differences are multifarious, what keeps differences from being totally arbitrary? What accounts for the fixity within some species and great variety in others? To beg the same question in cybernetic terms, what restraints and thresholds are in place?

In order to address that question William Bateson, like Butler had done a generation before him, must come up against the problematic of a concept which did not yet exist: negative entropy. The very fecundity of the natural world and the very complexity of variation within it argued against the entropic model of heat death, whereby heterogeneity within a system decreases, and also argued against the entropic logic of “the survival of the fittest”14.^[21] William Bateson, in Problems of Genetics, allows that natural selection and specific diversity both play their part, but the challenge to the orthodoxy of natural selection, which in the time of William Bateson was meeting increasing number of anomalies, was genetic code’s flexibility, which allowed for both fixity and variation. The elder Bateson held that “the phenomena of variation and stability must be an index of the internal constitution of organisms, and not mere consequences of their relations to the outer world.” The notion of an index which informs structure is a good deal more precise than Samual Butler, who searched similar territory by supposing that every organism contains: “a little unwritten history of the universe from its own point of view” but William Bateson, to use stochastic in its etymological sense, was still unable to hit his target in the centre.^[22]

[William Bateson] “As soon as it is realised how largely the phenomena of variation and stability must be an index of the internal constitution of organisms, and not mere consequences of their relations to the outer world, such phenomena acquire a new and more profound significance.” ^[23]

The notion that the transforms which occur in evolution are executed through the transmission of code gained support over time.

By 1943 Edwin Schrödinger‘s What is life lectures suggested that chromosomes contain the coded script of living organisms, a decade before being given empirical credence by Watson and Crick. Bertalanffy’s general systems theory, McCulluch-Pitts Neural net theory, Shannon’s information theory and Wiener’s theory of negentropy would be amongst the many elements that supported the notion that informational-biological systems described by William Bateson had a structural relation to other systems.

ENTROPY, CREATIVE EVOLUTION AND HENRI BERGSON

This brief overview of William Bateson’s understanding of specific diversity makes it clear that, like Butler before him, William Bateson is unable to make a specific relation between negative entropy, information and evolution. This triad can be later explained by cybernetics, but a full theorisation of the role of negative entropy is still some distance away. This is why, at this stage in the Fabulous Loop de Loop, we encounter a number of thinkers who repeatedly stumble over the issue of entropy. Which is why it is worth comparing William Bateson’s approach to the entropic conundrum to the approach of another influential voice in the evolutionary discourse at the beginning of the 20th centaury, Henri Bergson.

William Bateson had held that animals and plants are "systems through which matter is continually passing". This notion of the continuity of existence is close to Bergson's Creative Evolution ^[24] but there are significant differences of emphasis and substance. These differences centre on how energy and information is distributed within a system. Bergson faces the same dilemma as his contemporaries, how does one account for adaptation and the growth in complexity of organisms without violating the second law of thermodynamics? For Bergson entropy is at the very centre of adaptation, it is that force which exercises upon matter an increased degradation and disorder. Entropic forces make matter feed upon itself.In order to square this circle Bergson makes a distinction between entropic matter and a vitalistic consciousness. But this is not a hard and fast dualism, Bergson understands mind and matter to be two divergent entities which are preserved within the continuity of duration (Bergson describes a co-dependent duality, a productive equilibrium). Bergson made a thumbnail sketch of his theory in a 1911 lecture thus:

“If, as I have tried to show in a previous work (Creative Evolution), matter is the inverse of consciousness, if consciousness is action unceasingly creating and enriching itself, whilst matter is action continually unmaking itself or using itself up, then neither matter nor consciousness can be explained apart from one another. […] I see in the whole evolution of life on our planet a crossing of matter by a creative consciousness, and effort to set free, by force of ingenuity and invention, something which in the animal still remains imprisoned and is only finally released when we reach man.”^[25]

We can see that, in relation to the issue of entropy, Bergson is moving in a different direction to Butler and William Bateson, who's concepts had a closer relation to what would come to be known as cybernetics. In cybernetics, consciousness comes into being through negative entropy (as negative feedback loops and positive feedback loops afford homeostasis within an adaptive system). In cybernetics, order is consolidated within the organism in stages so that non-conscious actions can evolve into reflexive action (steps in an ecology of mind). The cybernetic world view does not need to presuppose a consciousness that acts on entropic matter in order to give it vitality. Bergson’s vitalism reintroduces the very dualism it is trying to eliminate by creating a consciousness which is separate from matter (even if it is “indivisible” ) Order and disorder within a homeostatic system are intrinsic to that system, it is an unnecessary complication to add consciousness as a corrective to entropy. It is clear that Bergson’s Creative Evolution opposes the development of a cybernetic evolutionism which Samuel Butler and William Bateson were working towards. Butler and William Bateson both opposed a distinction between mind and matter by recognising that the line between matter and consciousness, are arbitrary and that matter, mind and consciousness are “co-evolutionary” ^[26]

We will return to Bergson’s Creative Evolution in the final chapter of The Fabulous Loop de Loop, because even in the ecological landscape of 1960s counterculture, Bergson’s entropic-vitalistic model of mind and ecology were prevalent (as were other transformative ecological theories such as the theory or the Noosphere). For now, it is sufficient to say that the understanding of negative entropy as the unifying principle was far from universally recognised. The problem of entropy would continue to be a stone in the shoe as we hobble into the 20th century. We will see in the next chapter that Kenneth Craik comes closer to resolving the problem of energetics at the heart of adaptation. Craik engages with the thematic which is by now familiar: the relation of the machine to the organism; the relation of design to purpose, all of which are tied in a knot which the new conception of negative entropy will attempt to untie.