Small Matters

CURWOOD: Well, the question of how dogs think and feel isn't the only deep mystery being investigated at Emory University. Ari Daniel reports in this latest installment of our Small Matters series, scientists there are also probing the profound mysteries of how patterns and structures form and evolve. DANIEL: Its a perfect day here. [LEAVES CRUNCHING] Jay Goodwin walks over to a bench to sit down. And he cant help but be reminded about a day just like this one, five years ago, in western Michigan where he used to live. GOODWIN: I was outside I think I was going for a walk, just to kind of clear my head a little bit. I turned a corner, and I saw this flock of birds and they took off into the sky and they started to form a shape sort of an amorphous shape. And it was one that was dynamic, and it was changing but it had a boundary to it, like looking at a blob of oil in water. DANIEL: It stopped Goodwin in his tracks. Several hundred birds pulsing and dipping and soaring to an invisible beat in the sky. GOODWIN: It wasnt clear what they were responding to there werent any predator birds in the sky. And you never got the sense that there was anything that was directing it from within. There was no leader bird that they were all following. But just watching it was, well, it was beautiful. DANIEL: Goodwin realized he had no way of predicting the flocks behavior by simply taking lots of individual birds flapping their wings, and adding them up. Rather, it was something that emerged once all these birds threw themselves together. And its this notion of emergence how really complex patterns and properties can arise from combining somewhat simple units that now defines how Goodwin thinks about his real work. Chemistry. [SOUND OF DOOR UNLOCKING] Goodwin heads into his lab at Emory University. Hes a chemist here. And since seeing that flock, hes come to appreciate how molecules are a lot like birds. That is you get to know how the individuals behave and parade on their own, but then you put them together, and often something new and astonishing emerges. GOODWIN: We always want to allow some room for serendipity and allowing the molecules themselves to show us what theyre capable of doing. DANIEL: Lets take an example; a glass of water. GOODWIN: Water molecules in the liquid form are tumbling past each other, and they see each other very dynamically, very quickly, and they move on. DANIEL: Now cool that water down. The movement of the water molecules begins to slow, and they spend more time kind of looking at each other. GOODWIN: And they begin to align with each other, and become solid. And they grab more water molecules out of solution as they slow down, and that process begins to propagate and to grow until the whole thing is one big lattice of solid ice. DANIEL: And the thing about ice it floats on water. We take that for granted, but most solids sink to the bottom of their liquid form because theyre more dense. Not water, it floats which is crucial for life. GOODWIN: Underneath ice in a lake or an ocean or the Arctic is liquid water. Thats one of the unique features of water. Thats an emergent property. DANIEL: Emergent, because its just what happens when you throw a bunch of water molecules together, and cool them down. Now, Goodwin doesnt study water. Hes curious about other things, like how, in the brains of people with Alzheimers, a single misshapen protein can trigger neighboring proteins to buckle and warp, until a tangled plaque has emerged, like an errant bird reshaping its entire flock. Goodwin also studies what might have happened on the Earth a few billion years ago trying to learn the rules of how simple molecules might have assembled to lead to the emergence of life. Emergence, it turns out, is everywhere. GOLDBART: Theres no particular reason why emergence should be a property that happens at the scale of atoms and molecules, but not at the scale of – lets say viruses, or even galaxies for that matter. DANIEL: Paul Goldbart is a physicist at Georgia Tech who studies how the building blocks of matter interact to form the very small, the very big, and everything in between. He says its like watching a dance knowing that the whole isnt just greater than the sum of the parts its wondrously different. GOLDBART: We marvel at the way matter organizes. Not only do we get to see beauty and organization and patterns, but also theyre useful to better society and provide services and materials that make our lives safer and more vibrant. [SOUND OF GLASS FLASKS BUMPING TOGETHER] DANIEL: Back in the lab, this is exactly what Jay Goodwin is doing. Harnessing the idea of emergence, by putting molecules together and watching what happens, by creating room for his chemistry to surprise him and then, turning those insights to use. GOODWIN: To understanding disease and how to solve disease, and how to develop new therapeutics, how to create new materials that could be intelligent, that could respond to their environments in different ways could be self-healing, could capture solar energy for instance. DANIEL: Goodwins aim has become one of taking advantage of the rules that determine how molecules behave. Rules that are somewhat mysterious, and can emerge when you take the time to appreciate that theyre there. For Living on Earth, I'm Ari Daniel. CURWOOD: Our series, Small Matters, is produced by the Center for Chemical Evolution, with support from the National Science Foundation and NASA.

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