Quantum

microtubules to crystallize in one part of the cell rather than another.

Morphogenetic fi elds are not fi xed forever, but evolve. The fi elds of Afghan hounds and poodles have become very different from those of their common ancestors, wolves. How are these fi elds inherited? I suggest they are transmitted from past members of the species by morphic resonance, the infl uence of previous self- organising patterns of activity on subsequent similar patterns of activity. Morphic resonance also underlies the formation of crystals. Each kind of crystal embodies a crystal habit.

The fi elds organizing the activity of the nervous system are also inherited through morphic resonance. Through morphic resonance, animals take up the habits of their species; these are their instincts. Each individual both draws upon and contributes to the collective memory. This means that new patterns of behaviour can spread more rapidly than would otherwise be possible. For example, if rats of a particular breed learn a new trick in Harvard, then rats of that breed should be able to learn the same trick faster all over the world, say in Edinburgh and Melbourne. There is already evidence from laboratory experiments

(discussed in A New Science of Life) that this

actually happens.

The resonance of a brain with its own past states also helps to explain the memories of individual animals and humans. There is no need for memories to be stored inside the brain.

Social groups are likewise organized by fi elds, as in schools of fi sh and fl ocks of birds. Human societies have cultural memories that are reinforced by morphic resonance. Language learning is facilitated by morphic resonance with previous speakers of the language.

The memory of nature

From the point of view of morphic resonance, there is no need to suppose that all the laws of nature sprang into being fully formed at the moment of the Big Bang, like a kind of cosmic Napoleonic code, or that they exist in a

metaphysical realm beyond time and space.

If we want to stick to the idea of natural laws, we could say that as nature itself evolves, the laws of nature also evolve, just as human laws evolve over time. But then how would natural laws be remembered or enforced? The law metaphor is embarrassingly anthropomorphic. Many kinds of organisms have habits, but only humans have laws.

Evolutionary creativity

But evolution depends on more than habits; otherwise nature would be entirely repetitive. New things happen. Long ago, the fi rst stars and galaxies appeared. On this planet the fi rst living cells arose, then plants and animals appeared, eyes arose independently in several different kinds of animals, including vertebrates like us, and cephalopods, like the octopus. Some plants started fl owering, and all kinds of fl owers evolved from them. Animals invented many new ways of behaving, like spiders spinning webs, or bats fl ying by echolocation. Among humans, creativity has been expressed in every area, including music, agriculture, gastronomy, language, architecture, physics, computing, games, engineering and religion.

We are now at a new stage of human and Gaian evolution. We too are creatures of habit, and some of our habits must change if we are to survive. We need to do things in new ways. Our creativity, like all other creativity in nature, is subject to natural selection.

Mechanistic, reductionist science is a major cause of the ecological crisis. More of the same cannot possibly make things better. Only by recognising our connections with the rest of nature can we fi nd a vision that can inspire us. We are part of a process of creative evolution in which old habits die hard, but in which new patterns of behaviour can spread much faster than ever before.

Rupert Sheldrake, Ph.D. is a biologist and author of more than 80 scientifi c papers and ten books, including A New Science of Life (Icon Books, 2009). He was a Fellow of Clare College, Cambridge and a Research Fellow of the Royal Society. His web site is www.sheldrake.org

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