CAMBRIDGE, Mass. — One night late in 1979, an itinerant young physicist named Alan Guth, with a new son and a year’s appointment at Stanford, stayed up late with his notebook and equations, venturing far beyond the world of known physics.
He was trying to understand why there was no trace of some exotic particles that should have been created in the Big Bang. Instead he discovered what might have made the universe bang to begin with. A potential hitch in the presumed course of cosmic evolution could have infused space itself with a special energy that exerted a repulsive force, causing the universe to swell faster than the speed of light for a prodigiously violent instant.
If true, the rapid engorgement would solve paradoxes like why the heavens look uniform from pole to pole and not like a jagged, warped mess. The enormous ballooning would iron out all the wrinkles and irregularities.
Those particles were not missing, but would be diluted beyond detection, like spit in the ocean.
“SPECTACULAR REALIZATION,” Guth wrote across the top of the page and drew a double box around it.
On Monday, Guth’s starship came in. Radio astronomers reported that they had seen the beginning of the Big Bang, and that his hypothesis, known undramatically as inflation, looked right.
Reaching back across 13.8 billion years to the first sliver of cosmic time with telescopes at the South Pole, a team of astronomers led by John Kovac of the Harvard-Smithsonian Center for Astrophysics detected ripples in the fabric of space-time — so-called gravitational waves — the signature of a universe being wrenched violently apart when it was roughly a trillionth of a trillionth of a trillionth of a second old. They are the long-sought smoking-gun evidence of inflation, proof, Kovac and his colleagues say, that Guth was correct.
Inflation has been the workhorse of cosmology for 35 years, though many, including Guth, wondered whether it could ever be proved.
What it means
If corroborated, Kovac’s work will stand as a landmark in science comparable to the recent discovery of dark energy pushing the universe apart, or of the Big Bang itself. It would open vast realms of time and space and energy to science and speculation.
Confirming inflation would mean that the universe we see, extending 14 billion light-years in space with its hundreds of billions of galaxies, is only an infinitesimal patch in a larger cosmos whose extent, architecture and fate are unknowable. Moreover, beyond our own universe there might be an endless number of other universes bubbling into frothy eternity, like a pot of pasta water boiling over.
In our own universe, it would serve as a window into the forces operating at energies forever beyond the reach of particle accelerators on Earth and yield new insights into gravity itself. Kovac’s ripples would be the first direct observation of gravitational waves, which, according to Albert Einstein’s theory of general relativity, should ruffle space-time.
According to inflation theory, the waves are the hypothetical quantum particles, known as gravitons, that carry gravity, magnified by the expansion of the universe to extragalactic size.
“You can see how the sky is being distorted by gravitational waves,” said Andrei Linde, a prominent inflation theorist at Stanford. “We are using our universe as a big microscope. The sky is a photographic plate.”
Marc Kamionkowski of Johns Hopkins University, an early-universe expert who was not part of the team, said, “This is huge, as big as it gets.”
“Although I might not fully understand it,” Kamionkowski said, “this is a signal from the very earliest universe, sending a telegram encoded in gravitational waves.”
Kovac and his collaborators, working in an experiment known as BICEP, for Background Imaging of Cosmic Extragalactic Polarization, reported their results in a scientific briefing at the Center for Astrophysics here on Monday and in a set of papers submitted to The Astrophysical Journal.
Kovac said the chance that the results were a fluke was only one in 3.5 million — a gold standard of discovery called five-sigma.
Secret, lengthy research
The results are the closely guarded distillation of three years’ worth of observations and analysis. Eschewing email for fear of a leak, Kovac personally delivered drafts of his work to a select few, meeting with Guth, who is now a professor at MIT (as is his son, Larry, who was sleeping that night in 1979), in his office last week.
“It was a very special moment, and one we took very seriously as scientists,” said Kovac, who chooses his words as carefully as he tends his radio telescopes.
By last weekend, as social media was buzzing with rumors that inflation had been seen and news spread, astrophysicists responded with a mixture of jubilation and caution.
Abraham Loeb, a Harvard-Smithsonian astronomer who was not part of the team, said: “It looks like inflation really took place. Since 1980, this was really speculative physics.”
Lawrence Krauss of Arizona State and others also emphasized the need for confirmation, noting that the new results exceeded earlier estimates based on temperature maps of the cosmic background by the European Space Agency’s Planck satellite and other assumptions about the universe.
“So we will need to wait and see before we jump up and down,” Krauss said.
Corroboration might not be long in coming. The Planck spacecraft, which has been making exquisite measurements of the Big Bang microwaves, will be reporting its own findings this year.
Gravity waves are the latest and deepest secret yet pried out of the cosmic microwaves, which were discovered accidentally by Arno Penzias and Robert Wilson, both then at Bell Labs, 50 years ago. They got the Nobel Prize.
Kovac has spent his whole career trying to read the secrets of these waves. He is one of four leaders of BICEP, which has operated a series of increasingly sensitive radio telescopes at the South Pole, where the air — thin, cold and dry — creates ideal observing conditions. The others are Clement Pryke of the University of Minnesota, Jamie Bock of the California Institute of Technology and Kuo of Stanford.
In 2002, Kovac was part of a team that discovered that the microwave radiation was polarized, meaning the light waves had a slight preference to vibrate in one direction rather than another.
This was a step toward the ultimate goal of detecting the gravitational waves from inflation. Such waves, squeezing space in one direction and stretching it in another as they go by, would twist the direction of polarization of the microwaves, theorists said. As a result, maps of the polarization in the sky should have little arrows going in spirals.
Detecting those spirals required measuring infinitesimally small differences in the temperature of the microwaves. The group’s telescope, BICEP2, is basically a giant superconducting thermometer.
“We had no expectations what we would see,” Kovac said.
A special time
The data traced the onset of inflation to a time in cosmic history that physicists like Guth, staying up late in his Palo Alto house 35 years ago, suspected was a special break point in the evolution of the universe.
Physicists recognize four forces at work in the world today: gravity, electromagnetism, and the strong and weak nuclear forces. But they have long suspected that those are simply different manifestations of a single unified force that ruled the universe in its earliest, hottest moments.
As the universe cooled, according to this theory, there was a fall from grace, not unlike some old folk mythology of gods or brothers falling out with each other. The laws of physics evolved, with one force after another “freezing out,” or splitting away.
That was where Guth came in.
Under some circumstances, a glass of water can stay liquid as the temperature falls below 32 degrees, until it is disturbed, at which point it will rapidly freeze, releasing latent heat in the process.
Similarly, the universe could “supercool” and stay in a unified state too long. In that case, space itself would become temporarily imbued with a mysterious kind of latent heat, or energy.
Inserted into Einstein’s equations, the latent energy would act as a kind of antigravity, and the universe would blow itself up. Since it was space itself supplying the repulsive force, the more space was created, the harder it pushed apart. In a runaway explosion, what would become our observable universe mushroomed in size at least a trillion trillionfold — from a submicroscopic speck of primordial energy to the size of a grapefruit — in less than a cosmic eye-blink.