The Golden Angle in Trees
Without a doubt, the most popular mystery in art and nature is the golden section. This “divine” proportion seems to pop up in everything from sea shells to roman architecture. Trees are no different, they too show this magical proportion. It lets trees grow branches in just the right angle. The golden angle.
Let’s take a look at a fresh tree sapling. On its single branch, it grows several leaves. Each leaf shoots out in a different direction. Surprisingly, this is no random direction. Moving up from the base, each successive leaf spirals around the branch at an angle of roughly 137.5 degrees.
Biologists call this distribution phyllotaxis. It results in the most optimal placement of branches and leaves, with the least amount of overlap. New branches have the best chance of exploring unoccupied space, almost no branches collide. All because of the golden angle.
This becomes very obvious when a young tree sapling is viewed from above. Quite an amazing sight. Surely this can be no random thing! Do trees know maths? Is it something to do with evolution? Or is there another reason for this?
Although trees can smell, have quite advanced sight and can even feel when they are being touched, they have no brain to process all this information. It’s chemical reactions to outside stimulus. Quite magnificent and complicated reactions, don’t get me wrong. It’s just that trees can’t possibly grasp maths.
So before you think trees are smart, there’s actually a quite simple explanation for this happening. The answer lies in the bud, which grows a complete embryonic version of next year’s twig. The whole structure is packed into that tiny bud. This is where the rotation of branches starts, at a cellular level, it’s basically the most efficient way to pack everything into a small space.
More specifically. When the bud forms, lots of cells are grown. Most of these cells are the ones that grow the twig in length. Some of these cells differentiate into node cells, the ones that grow a leaf and later yet another bud. The ones that become node cells start producing hormones to tell the cells around it to keep low. So cells that are close don’t also produce nodes. This keeps nodes at a distance and provides an even distribution.
Therefore, a tree which has opposite branching with two leaves/buds at each internode, shows a spiralling rotation of 90 degrees instead of the golden angle.
A good comparison is a pine cone, which also strongly manifests the golden angle. Think of the scales as being single cells, compactly packed in the most efficient manner.
The phyllotaxic angle isn’t the perfect golden angle. But the more nodes a tree grows inside a bud, the closer it gets to the golden angle. Willows come very close with their immense number of new nodes per twig.
Phyllotaxis and the Grove
Phyllotaxic angles are automatically calculated by the Grove, in tree growth and twig placement. Selecting alternate or opposite branching also changes the angle to either 137.5 or 90 degrees.
Although trees are all around us, there are quite some misconceptions on how trees grow. Studying the way in which a real tree grows reveals surprising mechanisms that together evolve these complex plants. Learn more about how trees grow.