19 June 2014
Last updated at 19:25 ET
The BICEP2 Collaboration used a telescope at the South Pole to detect the signal in the oldest light it is possible to observe.
At the time of the group's announcement in March, the discovery was hailed as a near-certain Nobel Prize.
But the criticism since has been sharp.
Rival groups have picked holes in the team's methods and analysis.
On Thursday, the BICEP2 collaboration formally published its research in a peer reviewed journal - Physical Research Letters (PRL).
"Has my confidence gone down? Yes," Prof Clem Pryke, from the University of Minnesota, told his audience.
Light twist
Cosmic inflation: Confidence lowered for Big Bang signal
The measurements were taken using the BICEP2 instrument at the South Pole Telescope facility
Scientists
who claimed to have found a pattern in the sky left by the super-rapid
expansion of space just fractions of a second after the Big Bang say
they are now less confident of their result.
At the time of the group's announcement in March, the discovery was hailed as a near-certain Nobel Prize.
But the criticism since has been sharp.
Rival groups have picked holes in the team's methods and analysis.
On Thursday, the BICEP2 collaboration formally published its research in a peer reviewed journal - Physical Research Letters (PRL).
Continue reading the main story
Prof Clem Pryke BICEP2 Collaboration"I'm feeling like I'm at the eye of the storm”
In the paper, the US-led group stands by its work but accepts some big questions remain outstanding.
And addressing a public lecture in London, one of BICEP2's principal investigators acknowledged that circumstances had changed."Has my confidence gone down? Yes," Prof Clem Pryke, from the University of Minnesota, told his audience.
Light twist
What the team announced at its 17 March press conference was the long sought evidence for "cosmic inflation".
Developed in the 1980s, this is the idea that the Universe experienced an exponential growth spurt in its first trillionth of a trillionth of a trillionth of a second.
It helps explain why deep space looks the same on all sides of the sky - the contention being that a very rapid expansion early on could have smoothed out any unevenness.
Inflation theory makes a very specific prediction - that it would have been accompanied by waves of gravitational energy, and that these ripples in the fabric of space-time would leave an indelible mark on the oldest light in the sky - the famous Cosmic Microwave Background.
The BICEP team claimed to have detected this signal. It is called B-mode polarisation and takes the form of a characteristic swirl in the directional properties of the CMB light.
The critiques that have appeared since March have largely focused on this issue. And they intensified significantly when some new information describing dust polarisation in the Milky Way was released by scientists working on the European Space Agency's orbiting Planck telescope.
Until then, or until new data emerges from other sources, the
BICEP2 collaboration recognises that its inflation detection has
greater uncertainty attached to it.
"[Our] models are not sufficiently constrained by external public data to exclude the possibility of dust emission bright enough to explain the entire excess signal," it writes in the PRL paper.
'Data trumps models'
Developed in the 1980s, this is the idea that the Universe experienced an exponential growth spurt in its first trillionth of a trillionth of a trillionth of a second.
It helps explain why deep space looks the same on all sides of the sky - the contention being that a very rapid expansion early on could have smoothed out any unevenness.
Inflation theory makes a very specific prediction - that it would have been accompanied by waves of gravitational energy, and that these ripples in the fabric of space-time would leave an indelible mark on the oldest light in the sky - the famous Cosmic Microwave Background.
The BICEP team claimed to have detected this signal. It is called B-mode polarisation and takes the form of a characteristic swirl in the directional properties of the CMB light.
Gravitational waves from inflation put a distinctive twist pattern in the polarisation of the CMB
It is, though, an extremely delicate pattern and must not be
confused with the same polarisation effects that can be generated by
nearby dust in our galaxy.The critiques that have appeared since March have largely focused on this issue. And they intensified significantly when some new information describing dust polarisation in the Milky Way was released by scientists working on the European Space Agency's orbiting Planck telescope.
Continue reading the main story
Prof Marc Kamionkowski Johns Hopkins University"If it was not such an exciting result, you would not be hearing so much about it”
Planck, which everyone agrees is
extremely powerful at characterising dust, will release further data
before the end of the year. And, very significantly, this will include
observations made in the same part of the sky as BICEP2's telescope.
"[Our] models are not sufficiently constrained by external public data to exclude the possibility of dust emission bright enough to explain the entire excess signal," it writes in the PRL paper.
'Data trumps models'
At his lecture at University College London, Prof Pryke
explained his team's lowered confidence: "Real data from Planck are
indicating that our dust models are underestimates. So the prior
knowledge on the level of dust at these latitudes, in our field, has
gone up; and so the confidence that there is a gravitational wave
component has gone down. Quantifying that is a very hard thing to do.
But data trumps models."
Prof Pryke spoke of the pressure he and his colleagues had been under since March. He said he never expected there would be such interest in their work, especially from mainstream media.
"I'm feeling like I'm at the eye of the storm," he told me.
"Look, the scientific debate has come down to this - we need more data. With the existing data that's out there, you can generate a lot of farce, a lot of blog posts, a lot of excitement and controversy, but you can't really answer the question scientifically. So, what you need is more data, and that's coming from Planck and it's coming from us."
Prof Marc Kamionkowski, from Johns Hopkins University, commented that what we were witnessing currently was "science in action".
"If it was not such an exciting result, you would not be hearing so much about it," he said in a phone conversation last week.
"We're going to need confirmation by independent groups. That's the way things work in science. We don't believe things because somebody says they're true; we believe them because different people make the measurements independently and find the same results."
The recent Planck dust polarisation data release did not cover the part of the sky observed by BICEP2
Jonathan.Amos-INTERNET@bbc.co.uk and follow me on Twitter: @BBCAmos
Prof Pryke spoke of the pressure he and his colleagues had been under since March. He said he never expected there would be such interest in their work, especially from mainstream media.
"I'm feeling like I'm at the eye of the storm," he told me.
"Look, the scientific debate has come down to this - we need more data. With the existing data that's out there, you can generate a lot of farce, a lot of blog posts, a lot of excitement and controversy, but you can't really answer the question scientifically. So, what you need is more data, and that's coming from Planck and it's coming from us."
Prof Marc Kamionkowski, from Johns Hopkins University, commented that what we were witnessing currently was "science in action".
"If it was not such an exciting result, you would not be hearing so much about it," he said in a phone conversation last week.
"We're going to need confirmation by independent groups. That's the way things work in science. We don't believe things because somebody says they're true; we believe them because different people make the measurements independently and find the same results."
The recent Planck dust polarisation data release did not cover the part of the sky observed by BICEP2
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