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How to think about… Entropy

Ashes to ashes, dust to dust, the inescapable rise of entropy links our fates and that of the universe. Or perhaps the universe just wants us to think that

entropy

PLACE 20 coins, heads up, on a tray and film it as you give it a shake. Then play the film backwards. From a jumbled mess, the coins all jump and come to rest with the same side up 鈥 an unreal, slightly creepy sequence. 鈥淚t seems like a mundane observation, but actually this is very profound,鈥 says physicist at the University of Bristol, UK.

This little experiment illustrates the power of perhaps the most essential, implacable field within physics: thermodynamics, the science of heat, energy and, most crucially, entropy.

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The roots of thermodynamics lie in efforts to understand the steam engines that powered the industrial revolution of 18th and 19th-century Europe. The French engineer Sadi Carnot realised that their heat always tends to dissipate, moving to cooler regions. Anything that goes against this grain requires additional energy to power it.

This movement from hotter to cooler is an expression of a more fundamental drive in the universe: disorder, as measured by entropy, always increases. The specifics don鈥檛 matter 鈥 heat always flows, flipped coins always jumble, burning logs always turn to ash. 鈥淚f we discover a new force tomorrow, thermodynamics will be fine,鈥 says at University College London.

Entropy increase is so universal that many physicists propose it is why we see time flowing (see 鈥How to think about鈥 Time鈥). It is certainly why our hearts must constantly pump blood, supplying our cells with energy as a temporary stay against the inevitable onset of decay and disorder.

Is there any way out? Perhaps. The laws of thermodynamics only hold true as statistical averages. As a result, some see an escape route from entropy鈥檚 inevitable rise in the small-scale workings of the quantum world: rules based on statistics don鈥檛 mean much when you鈥檙e dealing聽with just a few particles.

There are concepts akin to entropy that tend to increase in the quantum world, says Oppenheim 鈥 uncertainty over a particle鈥檚 position, for one. The science of quantum thermodynamics is in its infancy, and any hopes of using its fuzzy rules to make batteries more efficient than conventionally possible will not be realised any time soon. Oppenheim is sceptical that we will ever override traditional thermodynamic restrictions. But one instance where quantum thermodynamics comes into play is at the event horizon of a black hole (see 鈥How to think abouth鈥 Black holes鈥) 鈥 so it could help solve the enduring riddle of how to unite general relativity with quantum theory.

鈥淥ur hearts pump blood to stay the rise of decay and disorder鈥

That鈥檚 unlikely to help out much with the bleak future predicted for the universe, in which it slides into a long, slow 鈥渉eat death鈥, eventually turning all order to disorder. 鈥淥ur present understanding is that things will become more and more disordered until life becomes very, very boring,鈥 says Oppenheim.

Or will it? Even within that disordered soup at the end of the universe, in theory 鈥渁ll kinds of interesting things can still occur鈥, says Oppenheim. Perhaps the most bizarre of these was first expounded by Ludwig Boltzmann in 1896. Boltzmann argued that, given enough time in a large enough universe, fluctuations might randomly create a sub-universe that looks like ours. More plausibly, it might create a brain that thinks it exists in just such a universe 鈥 and that thinks entropy is always on the up.

This article appeared in print under the headline 鈥淗ow to think about鈥 Entropy鈥

Topics: Physics / Quantum science