The Quantum Universe: Something Strange Is Afoot

Enlarge Image Image Gallery In “The Quantum Universe,” Brian Cox and Jeff Forshaw not only demystify quantum physics but also make it accessible to the average person without dumbing it down. Cover Courtesy Da Cappo Press

Quantum physics prompted even Nobel Prize-winning physicist Richard Feynman to admit, “I think I can safely say that nobody understands quantum mechanics.” Although it encompasses everything from how a ball moves through the air to how trees create oxygen, from how a computer’s circuit board functions to the life cycle of a star, understanding quantum physics means disregarding everyday perceptions of how the world works. Brian Cox and Jeff Forshaw shed a little light on how the universe as we know it behaves in The Quantum Universe (And Why Anything That Can Happen, Does) (Da Cappo Press, 2011). The following excerpt is from the book’s first chapter, “Something Strange Is Afoot.” 

Quantum. The word is at once evocative, bewildering and fascinating. Depending on your point of view, it is either a testament to the profound success of science or a symbol of the limited scope of human intuition as we struggle with the inescapable strangeness of the subatomic domain. To a physicist, quantum mechanics is one of the three great pillars supporting our understanding of the natural world, the others being Einstein’s theories of Special and General Relativity. Einstein’s theories deal with the nature of space and time and the force of gravity. Quantum mechanics deals with everything else, and one can argue that it doesn’t matter a jot whether it is evocative, bewildering or fascinating; it’s simply a physical theory that describes the way things behave. Measured by this pragmatic yardstick, it is quite dazzling in its precision and explanatory power. There is a test of quantum electrodynamics, the oldest and most well understood of the modern quantum theories, which involves measuring the way an electron behaves in the vicinity of a magnet. Theoretical physicists worked hard for years using pens, paper and computers to predict what the experiments should find. Experimenters built and operated delicate experiments to tease out the finer details of Nature. Both camps independently returned precision results, comparable in their accuracy to measuring the distance between Manchester and New York to within a few centimetres. Remarkably, the number returned by the experimenters agreed exquisitely with that computed by the theorists; measurement and calculation were in perfect agreement.

This is impressive, but it is also esoteric, and if mapping the miniature were the only concern of quantum theory, you might be forgiven for wondering what all the fuss is about. Science, of course, has no brief to be useful, but many of the technological and social changes that have revolutionized our lives have arisen out of fundamental research carried out by modern-day explorers whose only motivation is to better understand the world around them. These curiosity-led voyages of discovery across all scientific disciplines have delivered increased life expectancy, intercontinental air travel, modern telecommunications, freedom from the drudgery of subsistence farming and a sweeping, inspiring and humbling vision of our place within an infinite sea of stars. But these are all in a sense spin-offs. We explore because we are curious, not because we wish to develop grand views of reality or better widgets.