Natural Patterns
(...Phi and more...)


1. Snails and Stars. Do you like this Snail shell? I photographed it on Yeo Island. It is tiny, about the size of a dime and owes its spiral shape to a simple mathematical ratio known as phi that plays a part in the animal’s development. It is the same ratio that governs the development of galaxies like Whirlpool Galaxy M 51, pictured below.

Phi can be found in the way rose petals grow on a bud, the way sunflower seeds align on the head of a sunflower, and the way that branches space themselves around the trunk of trees. It is one of the most recognizable patterns in the natural world and exists on your own body. Your hand and lower arm are distributed according to phi, as are the size and arrangement of many of your facial features.

Some people go phi-wild spotting the ratio everywhere, but in fact, part of what makes the natural world beguilingly appealing is it refusal to be reduced to simple mathematics. The wonderful patterns in the natural world are produced by many factors.

Chaos theory postulates Lorenz Attractors to describe how patterns emerge that do not fall into exactly defined mathematical equations. Edward Lorenz, who uncovered the now famous Butterfly Effect, noticed that complex dynamic systems like the weather, when described mathematically in the right way, reveal a kind of order which can be graphed. Even chaos can show clear patterns, but never a pattern that exactly repeats.

Phi and Lorenz Attractors are a lattice or reticulated rubric beneath the shapes and patterns that we see around us in nature. But into these clean numeric predictors creep random corrugated noise. In this we have the paradox that nature is largely made up of formula driven patterns, with predictable parameters, muddied by factors too numerous to count. What we see and feel in the end is similarity, never exact replication.

2. It is more than Mathematics. On a very basic level this is obvious. There are many variations in a given species, such as a gold fish, but we usually can distinguish the pattern “gold fish” from the pattern “Guppy.” In fact we lump things together naturally and give them names to help us remember the lumpings.

Nouns make up about 1/4 of the english language. Like all languages english has patterns and there is a language of patterns, called, “pattern language.” Those who study Pattern Language concentrate their efforts on those arrangements of the environment that we as humans prefer to be in. Not surprisingly the patterns we tend to like to live among are curious blends of artificial and natural patterns. We like grids and precise shapes such as circles and squares, but we like to have them softened so that they appear more “natural”. If they are too precise, the environment seems sterile. If they are too random and undefined, the environment seems shabby or overgrown.

The natural world produces patterns over time as things grow or are moved by the action of water and wind, or are worn away by erosion and decay. In this dynamic interaction of factors such as surface tension in liquids, force resistance and conduction, traveling waves, vibrations, activation-inhibition coupled mechanisms, convection and conduction, streaming fluids, and the behaviors of granular media, we get the diversity of patterns we see. Rain washes groves into hillsides, trees grow from genetically predetermined codes, wind rolls sand grains into piles we call dunes, crystals form elemental shapes, fish swim rhythmically against the current in a stream.

Children and scientists enjoy sorting the world by its patterns. This is how we know, by classification, by identifying the animals and plants and stones and forces and laws. These strange squiggles of dark pixels on a background of white ones are patterns which represent verbal patterns, which represent physical objects, or the arrangements of those objects, or the relationships, and so on. Our thoughts themselves are patterns based on the pattern of language and the electrochemical routes through our brains that map meaning and can be mapped.

3. Some interesting things about Natural patterns. Evolution predicts that stresses on a population will result in certain individuals within a species exploiting physiological or behavioral traits that allow them to thrive more than others members of the same species. An example often given is the beak size in finches. The surprise is that from a group of birds with medium sized beaks two distinct groups tend to develop, each exploiting a niche. Few individuals with medium sized beaks turn up in future generations. One group can eat one kind of seed and the other can eat a different kind. Rather than compete for the same food source, finches fall naturally to niche occupancy, rather than niche bridging.

4. Falling into Patterns. Ian Steward, Professor of mathematics at the University of Warwick has modeled speciation mathematically with computers and notes that his models show that after the initial divergent split occurs and “even though the creatures can choose mates from the other group, the clusters tighten up and remain separate from each other. This behavior is not fully understood even mathematically (though curiously it appears to be related to fractal geometry), but it seems very close to what happens in real populations.” This is how we get diversity, lots of creatures falling into one niche or another, exploiting available resources that fit their unique abilities and behaviors. The interesting thing is that this mirrors patterns that result from non-living interactions such as wind, water, and crystallization.
We are intrigued with the smile lines in older faces, warmed by their weathered countenance, drawn to their expressive and knowing eyes.
Take for example the sand dunes I mentioned earlier. If a uniform wind blows across a uniform flat piece of desert sand, the result is parallel ridges of sand, or dunes. What the wind does to the sand is called symmetry-breaking and this principle underlies the formation of these kinds of patterns in sand, water, and other inanimate structures. The symmetry of the flat featureless sand is broken by the wind forming it into dunes.

Another example is when a flat dish of water is heated uniformly from below. At a certain temperature the uniformity of the surface of the water is broken into a pattern of convection cells. These cells are usually hexagonal with some pentagons as well and they are roughly the same size. The flat symmetry of the surface of the water is broken into a symmetrical lattice of hexagonal cells. Speciation follows this same pattern. A relatively uniform group, when stressed, falls into two or more groups of relatively uniform individuals. Those groups continue in a certain symmetry until a stress further divides them.

5. Spice of Life. Within any group of more or less similar individuals there will be variation. Such variation is tolerated to a degree, but when stressed, the group finds new patterns of symmetry based on these variations. The new groups tend not to interact, even though they were formerly united. Isn’t it interesting that symmetry-breaking produces new symmetry? Like the finches, we humans generally pick for mates those most similar to ourselves. But unlike finches, this tendency is not as strong.

One thing that is consistent is our choice for members of the opposite sex who have very symmetrical bodies. When it comes to voting on what we consider to be the most beautiful faces, for example, symmetry is a large factor in our decision. There is a lot of speculation about why this is. Symmetrical faces in people might predict health. Disease, parasites, and malnutrition all break symmetry signaling a compromised individual. Young faces are more symmetrical than older ones and young people are less tolerant of people who vary from the mean.

Some young people are able to get past their built-in wiring and see beyond physical abnormalities. Perhaps they have a grandparent they love who has failing health, perhaps they notice the bravery of a challenged child, or the steadfast love of an friend with a chronic illness. The truth is that beyond the level of biological attraction there is a different attraction to faces that have character. We are intrigued with the smile lines in older faces, warmed by their weathered countenance, drawn to their expressive and knowing eyes.

Those of us who have experienced this shift in values, this appreciation of symmetry breaking and the formation of new symmetries, or richer patterns, or more subtle beauties, start to wonder what it is that we are drawn to. As our palette matures we can tolerate the bitter olives, the pungent fungi, the aged cheese, we never could have stomached before. With time the neat rows of vegetables and carefully aligned flower beds are allowed to ramble a bit. We notice the beauty in falling down barns, fallow fields, and crooked fences. Walking in the woods we become aware of the lovely soldier trees wounded in the battle for survival. The Arbutus with one living strip of bark winding up the otherwise dead tree to support a branch of shinny leaves. Even the ones that have lost the fight impress us with their character. It doesn’t matter to us that the dead tree weathered by the storm is no longer of any use, we love its bleached grain and twisted skeleton. still, in the stream.

6. Finding the Balance. This attraction to things with no obvious practical value is mysterious. One time while walking home late at night across a university campus I was struck by the beauty of wet Ivy leaves growing on the side of a tree. Ivy is not a food source, neither is it useful in any way known to me, but it was very beautiful on that cool evening. The same is true of the flaky shelves of shale I observed one time from the window of my car. Yet I pulled over and got out just to look at them. The apprehension of beauty in the patterns we observe is a further puzzlement.

Take a hand full of stones or chestnuts or other natural objects and set them down on a piece of wood. Move them around and observe that some arrangements are more pleasing than others. Why should this be? They are just stones on a piece of wood.

Another interesting question has to do with what is really at the heart of these patterns. Authors such as Philip Ball who wrote “The Self-Made Tapestry: Pattern Formation in Nature,” suggest that the formation of patterns reveals a tendency for the natural world to produce organization, and even order. Self-ordering systems and self-made patterns might explain the factors that produced life itself, the most complex and varied set of natural patterns we know of. Is it possible that patterns attract us because we know, at some level, that self-ordering is occurring, that life is emerging, that against the leveling action of the elements, order is happening?

I have noticed that what I like most is when there is a balance between order and disorder. The dead snag standing in the wind, the deserted temple with only one wall still standing, the concrete wall stained with lichen and moss, all exist between the two extremes. Is this an example of the middle path? Perhaps. We must not deny that a rain forest, steamy with life is beautiful, or a prairie, flat and expansive, has appeal. How much more so though when we find a ruin amidst the vines, or a stone monolith on the plain?

One thing is clear. Once you start to notice wabi sabi beauty in the interaction of patterns around you, you will experience a wealth of emotions ephemeral and difficult to name. Some people describe the sight of leaves strewn under an autumn tree as depressing and messy. But if we look past the loss of green, the fading glory of summer, and accept the value of humus and the beauty of those branches and bows so well hidden during the growing season, then the feeling that emerges is a sort of pleasurable acceptance, a somber longing for more patterns, for more awareness and clarity. This is the greatest pattern of all, the spiral progression up the ladder of maturity like a spark of recognition riding the DNA chain to its full expression.

© Richard R. Powell - November 2004


Notes:
Ian Steward’s discussion of speciation is published in New Scientist Vol. 11 October 2003 pg 35.

For a more in-depth discussion of Phi and Natural Beauty, see chapter ten of Wabi Sabi Simple.

© All Photo's by the author, except Whirlpool Galaxy M 51 which is available from The Hubble Heritage Project: http://heritage.stsci.edu/gallery/gallery.html