The Physics of Wall Street: a brief History of Predicting the Unpredictable
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Tyranny of the Dragon King
• 163 expertise in a new area is difficult, and for most people, once or twice is often enough for a lifetime. But Sornette has made contributions to more than a dozen fields, ranging from material science to geophysics, to decision theory (a branch of economics and psychology), to financial markets, even to neuroscience (he has done considerable work on the origin and pre- diction of epileptic seizures). He thinks of himself as a scientist in the broadest sense, as someone conversant in the sciences at large. He studied physics as a young man, not because he believed he wanted to devote his life to the field, but because he thought of physics as a kind of mother science. He likes to quote the philosopher descartes, who in his magnum opus Discourse on Method wrote that the sciences are like a tree: metaphysics is the roots, physics is the trunk, and everything else is the branches. (nowadays, Sornette is more modest about his training. He thinks of his background in physics as an excellent prepa- ration for approaching many problems but says that the intellectual challenges of fields like economics and biology are at least an order of magnitude more difficult than those posed by physics.) despite the va- riety of topics, however, much of Sornette’s work involves identifying patterns endemic to the structures of complex systems and using these patterns to predict critical phenomena: ruptures, quakes, crashes. one of Sornette’s earliest scientific projects involved ruptures in Kevlar, a synthetic fiber developed in 1965 by du Pont (and heir to the nylon tradition described earlier). It is a famously strong substance, used in the bulletproof vests worn by police and soldiers, and even as a replacement for steel in suspension bridge cables. It is stronger at very cold temperatures than at room temperature, and it is largely stable at extremely high heat, at least for short periods. It’s a marvel of modern chemistry. these properties have made Kevlar a very attractive material for all sorts of high-tech applications. It was one of these — space flight — that led Sornette to become involved in Kevlar research. Initially, the space race was a two-sided affair, between the United States and the Soviet Union. But by the mid-1960s, the leaders of several Western european nations began to realize that europe couldn’t rely on the lar- gesse of the superpowers to further european economic, military, and scientific interests in space. At first, europe’s entry into the space race was slow and scattered, but then in 1975, the various nascent organiza- tions that had been formed over the previous decade combined into what is now the european Space Agency. By this time, the space race had begun to slow, with further escalation proving too costly for both superpowers. this left an opportunity for the new european agency to rapidly catch up and assert itself as a dominant force in the space industry. A principal part of the new european initiative was a series of cutting-edge rockets called Ariane, designed as satellite delivery mechanisms. In 1983, the still-young european Space Agency began developing a new variety of Ariane rocket, the Ariane 4, to launch commercial sat- ellites, particularly communication satellites. (It was enormously suc- cessful — at one stage, it was used for roughly half of all commercial satellites launched worldwide.) the new rocket was designed by the french space agency, cneS, but manufactured by private contractors. It was one of these private contractors, a firm called Aérospatiale, that contacted Sornette. rockets, including the Ariane, often require several substances that need to be kept under very high pressure in order for combustion to occur. the chemicals are stored in vessels called pressure tanks — es- sentially, high-tech water balloons intended to maintain the necessary high pressures without bursting under the strain. the researchers at Aérospatiale who contacted Sornette were studying the behavior of pressure tanks that would be used in the Ariane 4. these tanks were made out of Kevlar. Usually, the tanks were strong, even at very high pressures. except when they suddenly exploded. the group at Aéro- spatiale was trying to determine the conditions under which this would happen. We know that if a balloon is inflated sufficiently, it will nearly always pop when pricked with a sharp pin. other substances, though, can be trickier to figure out. Materials like Kevlar will eventually rupture from the strain of high-pressure contents, but determining precisely when, or why, is a surprisingly difficult problem. When substances like Kevlar are put under significant stress, tiny fractures begin to appear. 164 • t h e p h y s i c s o f wa l l s t r e e t |
