Read more: "2013 Smart Guide: 10 ideas that will shape the year"
We're about to get a better grasp of one of the biggest ideas in the universe: inflation. The first maps of the cosmos from the European Space Agency's Planck satellite are due out in early 2013. They should help us to hone descriptions of how, after the big bang, the universe grew from smaller than a proton into a vast expanse in less than a trillionth of a trillionth of a second.
The early universe was a featureless soup of hot plasma that somehow grew into the dense galaxy clusters and cosmic voids we know today. On a large scale, regions far apart from each other should look very different, according to the laws of thermodynamics. But studies of the cosmic microwave background (CMB) - the first light to be released, some 300,000 years after the big bang - show that the universe still looks virtually the same in all directions.
To explain this unlikely sameness, physicists invoked inflation: since all points in the universe were once next-door neighbours, the idea is that they blew apart so quickly that they couldn't forget about each other. Data from NASA's Wilkinson Microwave Anisotropy Probe (WMAP), launched in 2001, bolstered a key prediction of inflation, that the universe's structure was seeded by quantum fluctuations in space-time.
Stephen Hawking recently told New Scientist that WMAP's evidence for inflation was the most exciting development in physics during his career. But a best-fit model for what drove the exponential expansion, when it began and how long it lasted, hasn't been agreed. The WMAP data also revealed some surprises, such as inexplicable patterns in the CMB. So cosmologists have been anxiously awaiting Planck's higher-resolution maps to set the record straight. The Planck team will release its first cosmological results from 15 months' worth of data in March.
In addition, the Planck results will help refine figures for how much dark energy, dark matter and normal matter make up the universe. Planck might also record the first direct signs of ripples in space-time called gravitational waves. Not bad for a probe that's already half dead - one of Planck's two detectors stopped working in January. The entire craft will be shuttered in August.
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