Theory Of Universe’s Earliest Moments Developed.


The figure below shows how the image of quantum noise may appear imprinted on the cosmic microwave background. Red and blue denote hot and cold variations of the temperature, measured by the WMAP satellite over seven years. Comparing the statistics of the measured data with our theoretical calculations shows very good agreement.

 The 2013 Gruber Cosmology Prize recognizes Viatcheslav Mukhanov and Alexei Starobinsky for their formative contributions to inflationary theory. This is the new physics!

It is in fact an essential component for understanding the evolution and structure of the universe. According to the Prize citation, their theoretical work “changed our views on the origin of our universe and on the mechanism of its formation of structure.” Thanks to their contributions, scientists have provided a compelling solution to two of the essential questions of cosmology: Why is the structure of the universe so uniform on the largest scales? Where did the departures from uniformity — such as galaxies, planets, and people — come from?

The work for which they are being honored began in the late 1970s and early 1980s, during a period of fertile, even fervid, theoretical investigations into the earliest moments of the universe. In 1965 astronomers had discovered the cosmic microwave background — relic radiation dating to an era 13.8 billion years ago, when the universe was approximately 380,000 years old, during which hydrogen atoms and photons (packets of light) decoupled, causing a kind of “flashbulb” image that pervades the universe to this day. This discovery validated a key prediction of the Big Bang theory and inspired a generation of theorists.

Among them was Starobinsky, then a senior research scientist at the Landau Institute. His approach was to use quantum mechanics and general relativity to try to address how an expanding universe might have originated. While he did not resolve that issue, his calculations made in 1979-1980 did indicate that the universe could have gone through an extraordinarily rapid exponential expansion in the first moments of its existence.


Inflation works as a cosmic microscope to see the quantum fluctuations in the very early Universe

The following year Mukhanov (Moscow Physical-Technical Institute) and G. V. Chibisov (Lebedev Physical Institute, Moscow; he passed away several years ago) began working on the implications of quantum fluctuations within the Starobinsky model. Quantum fluctuations — disturbances in the fabric of space predicted by Heisenberg’s uncertainty principle — are always present in the universe. But in an extremely small, extremely dense, and extremely energetic newborn universe they would have had an outsized presence.

What’s more, the kind of exponential expansion that Starobinsky was proposing would have stretched those fluctuations beyond the quantum scale. In 1981 Mukhanov and Chibisov discovered that these fluctuations could play the role of the seeds that eventually bloomed into the present large-scale web-like structure of the universe: galaxies, clusters of galaxies, and superclusters of galaxies.

When this mechanism was first proposed, it looked like a piece of science fiction. Indeed, usually quantum fluctuations appear only on tiny subatomic scales, so the idea that galaxies have been born from quantum fluctuations seemed totally outlandish. And yet the subsequent developments in theoretical and observational cosmology strongly favored this possibility.

Jim Bardeen, Jim Hartle, Alexei Starobinsky, A...

Jim Bardeen, Jim Hartle, Alexei Starobinsky, Alan Guth (Photo credit: betsythedevine)

Shortly after the Starobinsky work, the American physicist Alan Guth proposed a brilliant idea that an exponential expansion stage of the early universe, which he called “inflation,” could explain the incredible uniformity of our universe and resolve many other outstanding problems of the Big Bang cosmology.

However, Guth immediately recognized that his proposal had a flaw: the world described by his scenario would become either empty or very non-uniform at the end of inflation.

This problem was solved by Andrei Linde, who introduced several major modifications of inflationary theory, such as “new inflation” (later also developed by Albrecht and Steinhardt), “chaotic inflation,” and “eternal chaotic inflation.” A new cosmological paradigm was born.

In 2004, Guth and Linde received the Gruber Prize for the development of inflationary theory.

The original goals of the Starobinsky model were quite different from the goals of inflationary theory. Instead of trying to explain the uniformity of the universe, he assumed that the universe was absolutely homogeneous from the very beginning. However, it was soon realized that the mathematical structure of his model was very similar to that of new inflation, and therefore it naturally merged into the rapidly growing field of inflationary cosmology.

In 1982, several scientists, including Starobinsky, outlined a theory of quantum fluctuations generated in new inflation. This theory was very similar to the theory developed by Mukhanov and Chibisov in the context of the Starobinsky model. Investigation of inflationary fluctuations culminated in 1985in work by Mukhanov, who developed a rigorous theory of these fluctuations applicable to a broad class of inflationary models, including new and chaotic inflation.

This theory predicted that inflationary perturbations have nearly equal amplitude on all length scales. An equally important conclusion was that this scale invariance is close, but not exact: the amplitude of the fluctuations should slightly grow with the distance. These fluctuations would have equal amplitudes for all forms of matter and energy (called adiabatic fluctuations). The theory also predicted a specific statistical form of the fluctuations, known as Gaussian statistics.


Since then, increasingly precise observations of the cosmic microwave background radiation (CMB) have provided decisive matches for theoretical predictions of how those initial quantum fluctuations would look after the universe had been expanding for 380,000 years. Those observations include all-sky maps produced by the Cosmic Microwave Background Explorer (COBE), the Wilkinson Microwave Anisotropy Probe (WMAP), and the Planck satellite. John Mather and the COBE team received the Gruber Cosmology Prize in 2006; Charles Bennett and the WMAP team received theirs in 2012.

Back in 1979, Starobinsky also found that exponential expansion of the universe should produce gravitational waves — a quantum by-product of general relativity, and a target for the new generation of instruments expected over the next decade.

This year’s Gruber Cosmology Prize citation credits Starobinsky and Mukhanov with a profound contribution to inflationary cosmology and the theory of the inflationary perturbations of the metric of space-time. This theory, explaining the quantum origin of the structure of our universe, is one of the most spectacular manifestations of the laws of quantum mechanics on cosmologically large scales. Press release Gruber Foundation

Giant Telescope Gathers First Images


Data already produced from the Murchison Widefield Array project in WA has excited astronomers.

 THE telescope spotted a blue and red blob that looked a little like a fried egg as it began what’s been called one of the great scientific adventures of our time.

The blob was a picture of our sun – seen for the first time through a radio telescope that was switched on in a remote pocket of Western Australia on Tuesday.

The $51 million Murchison Widefield Array (MWA) radio telescope is one of three precursors to a $2 billion “mega-science project”, known as the Square Kilometre Array (SKA) telescope, and is projected to generate tens of thousands of Australian jobs over the next 50 years.

The SKA project aims to develop the world’s largest and most sensitive radio telescope, the low-frequency component of which will begin construction in Australia in 2016.

On Tuesday morning the MWA began collecting data for the first time, as partner agencies celebrated across the country. It will be used to detect and monitor solar storms and investigate using stray FM audio signals to track dangerous space debris.

The MWA will give scientists an unprecedented view into the first billion years of the universe by enabling them to study radio waves more than 13 billion years old.

Prof Steven Tingay said each of the programs has the potential to change humanity’s understanding of the universe. The MWA will be used to gain a better understanding of the connection between our earth and the sun, he said. “This is an exciting prospect for anyone who’s ever looked up at the sky and wondered how the universe came to be,” said Prof Tingay, director of radio astronomy at Curtin University.

He said preliminary results could be seen in as little as three months. The MWA project is the result of a collaboration between 13 institutions in four countries. Science Minister Kim Carr, who launched the project in Melbourne, said the telescope opened up huge opportunities for Australian industry. “There are tens and thousands of jobs to flow from this project,” Senator Carr said. Source: News.Com.AU



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