Lunar Eclipse set to be 'best in years' - Saturday 3rd March 20.18 - 23.58 GMT

It is like Mars suddenly coming a thousand times closer and just hanging there in the sky above you Robert Massey, Royal Astronomical Society

Skywatchers eagerly awaiting Saturday's total lunar eclipse say that the spectacle could be the "best in years".

The eclipse begins at 2018 GMT, with the Moon totally immersed in the shadow of the Earth between 2244 and 2358 GMT.

During "totality", only light that has been filtered through the Earth's atmosphere reaches the Moon's surface, making it appear a reddish colour.

The eclipse will be visible from the whole of Europe, Africa, South America, and eastern parts of the US and Canada.

"They are beautiful events," said Robert Massey, spokesman for the UK's Royal Astronomical Society.

"They have a really romantic feel to them as you look up because the Moon, which is normally pearly white, takes on this reddish colour."

He added that it was totally safe to observe and no protective filters were needed because the Moon would actually be less bright than during a normal full moon.

See where the eclipse will be visible

Mr Massey encouraged everyone to witness the "spectacular" event.

TOTAL LUNAR ECLIPSE Occurs when Moon passes into Earth's shadow Penumbra: Region where Earth blocks some (but not all) Sun rays Umbra: Zone where Earth blocks all direct sunlight - total eclipse

"It is like Mars suddenly coming a thousand times closer and just hanging there in the sky above you."

Lunar eclipses occur when the Sun, Earth and Moon are in a near-perfect line in space.

The Moon travels through the long cone-shaped shadow that the Earth casts in space. At totality, the only light reaching the Moon's surface at this point has been refracted through the Earth's atmosphere.

The appearance of the lunar surface varies according to how much dust is in the Earth's upper atmosphere. For example, following major volcanic eruptions, the Moon appears to be a deep red and almost invisible.

As there have not been any recent sizeable eruptions, astronomers are predicting that the Moon will be bathed in a bright orange light.

'Best in years'

Professional astronomers will also be enjoying the spectacle rather than worrying about any science, Mr Massey says.

KEY TIMES FOR ECLIPSE Moon enters penumbra: 2018 Moon enters umbra: 2130 Totality begins: 2244 Mid-eclipse: 2321 Totality ends: 2358 Moon leave umbra: 0111 Moon leaves penumbra: 0224 (All times are in GMT)

"It is not like a solar eclipse where you get to see the outer atmosphere of the sun," explained Mr Massey.

"There were some people in the past who measured how different parts of the Moon cooled down as the Earth's shadow passed over it, but I doubt much of that work is going on now."

Robin Scagell, from the Society for Popular Astronomy, was hopeful that the event will be the "best in years".

"If the clouds stay away, it will be fascinating to watch the Moon's graceful movement through the shadow of the Earth," he said.

The last total eclipse visible from the UK was back in May 2004, but it was obscured by cloudy skies.

After Saturday's eclipse, the next to be seen over western Europe will take place on 21 February 2008, but in the middle of the night between 0300 GMT and 0400 GMT.

reposted from: BBC
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Vitamin supplements can increase risk of death

02 Mar 2007

Vitamin pills increase risk of death, reported five newspapers (28 February 2007). The newspapers accurately reported the findings of a generally well-conducted systematic review.

• On the 28 February 2007, five newspapers (1-6) reported that vitamin supplements can increase risk of death. All five newspapers reported that beta carotene, vitamin A, and vitamin E appear to increase the risk of death but reported no effect of vitamin C and selenium. Two newspapers (3, 6) reported that two thirds of the included participants were chronically ill.

• The newspaper reports were based on a well-conducted systematic review (7) of 68 trials, collectively involving 232,606 adults from primary and secondary prevention trials comparing antioxidant supplementation (beta carotene, vitamin A, vitamin C, vitamin E or selenium) with placebo or no intervention. The authors concluded that there is no evidence that antioxidant supplements have beneficial effects on mortality, and state that beta carotene, vitamin A, and vitamin E appear to increase the risk of death. They added that further trials are needed to establish the effects of vitamin C and selenium.

• The newspaper reports accurately described key details of the review. This was a generally well conducted review but some of its conclusions may be overstated.

Evaluation of the evidence base for the effect of antioxidant supplements on mortality in primary and secondary prevention.

Where does the evidence come from?

The evidence comes from research led by Dr Goran Bjelakovic, University of Nis, Department of Internal Medicine, Nis, Serbia. This Cochrane review was supported by The Copenhagen Trial Unit, Center for Clinical Intervention Research, Copenhagen University Hospital, Copenhagen, Denmark. The funding source had no role in the conduct of the study, collection of data, or preparation of the manuscript.

What were the authors' objectives?

The objective was to investigate the effect of antioxidant supplements on mortality in randomised primary and secondary prevention trials.

What was the nature of the evidence?

The study was a systematic review, which included 68 randomised controlled trial (RCTs), involving 232,606 adults from primary and secondary prevention trials. Trials including general or healthy groups of adults were classified as primary prevention, and trials including individuals with a specific disease were classified as secondary prevention. Tertiary prevention trials were excluded from the review. Where reported, the mean age of included participants ranged from 47 to 84 years. The authors searched four electronic databases, and the reference lists of relevant articles for published studies. Each stage of the review, study selection, data extraction and quality assessment, was carried out in duplicate to reduce the risk of errors and bias.

What interventions were examined in the research?

RCTs that compared beta carotene, vitamin A, vitamin C, vitamin E or selenium with placebo or no intervention were included. The primary outcome measure was all-cause mortality at maximum follow-up. Studies were combined using a random effects meta-analysis. Differences between studies that could have influenced the findings were investigated. Results were presented as relative risks for all mortality. Analyses to determine how sensitive results are to changes in how the study was conducted were carried out, looking at trial quality (low or high risk of bias) and method of administration (singly or in combination).

What were the findings?

The authors classify 47 of the 68 included studies as having high methodological quality; for example, allocating participants randomly to the different treatment groups, using an approach that does not allow one to predict to which treatment group a participant will be allocated.

No statistically significant difference was found in risk of mortality between all supplements versus placebo or no intervention. When only trials with a low risk of bias were considered, a statistically significant increased risk of mortality (5%) was found for antioxidant supplements compared to placebo or no intervention.

A statistically significant increase in risk of mortality was found in those taking beta carotone (7%), vitamin A (16%), and vitamin E (4%) supplements (either singly or in combination) compared to placebo or no intervention after exclusion of high bias trials and selenium trials. Selenium supplementation was found to reduce the risk of mortality by 10% although this was not statistically significant after excluding trials with a high risk of bias. No statistically significant difference in the risk of mortality was shown between those taking vitamin C supplements and placebo or no intervention.

What were the authors' conclusions?

The authors concluded that there is no evidence that antioxidant supplements have beneficial effects on mortality. They also state that beta carotene, vitamin A, and vitamin E appear to increase the risk of death, but that further RCTs are needed to establish the effects of vitamin C and selenium.

How reliable are the conclusions?

The authors searched several relevant sources without language restrictions, so they are likely to have found most or all of the relevant research studies. Study selection, quality assessment and data extraction were carried out in duplicate, reducing the risk of error and bias. Trials included varied populations (general population, patients with gastrointestinal, cardiovascular, neurological, skin, ocular, renal and rheumatoid diseases), and compared antioxidants with different properties, at different doses and duration, singly or in combination with different additional supplements, and the results should be interpreted in light of these variations. Differences between the studies, particularly in terms of trial quality, were assessed. It might have been useful to separate healthy populations from disease specific populations. In addition, all cause mortality was not a primary outcome for a number of the included trials. The authors also state that many of the included trials investigated the effects of supplements administered at higher doses than those found in a balanced diet and some trials used doses well above recommended daily allowances, as such generalisability to recommended levels might be difficult.

The authors also add that the trials assessed the influence of synthetic antioxidants and that findings should not be translated to potential effects of fruits or vegetables.

Systematic reviews

Information staff at CRD searched for systematic reviews relevant to this topic. Systematic reviews are valuable sources of evidence as they locate, appraise and synthesize all available evidence on a particular topic.

There was one related systematic review identified on the Cochrane Database of Systematic Reviews (CDSR) (8) and five on the Database of Abstracts of Reviews of Effects (DARE) (9-13).

References and resources

1. Medical backlash over health foods. The Times, 28 February 2007, p1.

2. Food and vitamin pills are 'bad for you'. The Times, 28 February 2007, p7.

3. Taking vitamin supplements may increase risk of death, says study. The Guardian, 28 February 2007, p10.

Taking vitamin supplements may increase risk of death, says study

Sarah Boseley
Wednesday February 28, 2007
The Guardian

People who regularly take vitamins A and E and beta-carotene in the hope of living a fitter and longer life may run a risk of earlier death, according to research in an influential medical journal.

The three supplements are marketed on the premise they deliver antioxidants to the body to mop up free radicals, thought to be responsible for some of the effects of ageing. But none was found to lengthen the lives of those who took them, according to an analysis in the Journal of the American Medical Association of all the substantial trials done to date.

Scientists of the respected Cochrane collaboration, which regularly pools data from trials to evaluate drugs and medical treatments, discovered the three supplements had the opposite effect. Those who took them, in 47 trials with 180,938 people, had a 5% greater risk of dying than those who did not.

Other common supplements with similar claims made for them, vitamin C and selenium, did not increase risk of death, the researchers from Copenhagen University hospital in Denmark found, but only selenium may have some benefit. "Our systematic review contains a number of findings. Beta carotene, vitamin A, and vitamin E given singly or combined with other antioxidant supplements significantly increase mortality," wrote Goran Bjelakovic and colleagues.

"There is no evidence that vitamin C may increase longevity. We lack evidence to refute a potential negative effect of vitamin C on survival. Selenium tended to reduce mortality, but we need more research on this question." Around 10% to 20% of people in Europe and North America take these supplements regularly, so "the public health consequences may be substantial", they say. People are exposed to "intense marketing" they add, but consumers would be better obtaining antioxidants from fruit and vegetables.

But Balz Frei, director of the Linus Pauling Institute at Oregon State University, said the study and the data were flawed, because more than two-thirds of research examined used people with heart disease, cancer, or other risks, treated to see if the supplements worked: "Over the years it has become clear ... antioxidants don't work in disease treatment."

4. What's up doc? Experts claim 'carrot' vitamin pill can kill you. The Sun, 28 February 2007, p25.

5. Vitamin pills can help send you to an early grave, say scientists. Daily Mail, 28 February 2007, p4.

6. Anti-ageing vitamins increase death risk, finds study. Daily Telegraph, 28 February 2007, p6.

7. Bjelakovic G, Nikolova D,Gluud LL, Simonetti RG, Gluud C. Mortality in randomized trials of antioxidant supplements for primary and secondary prevention: systematic review and meta-analysis. JAMA 2007;297:842-57.

8. Bjelakovic G, Nikolova D, Simonetti RG, Gluud C. Antioxidant supplements for preventing gastrointestinal cancers. Cochrane Database of Systematic Reviews 2004, Issue 4. Art. No.: CD004183. DOI: 10.1002/14651858.CD004183.pub2.

9. Miller ER, Pastor-Barriuso R, Dalal D, Riemersma RA, Appel LJ, Guallar E. Meta-analysis: high-dosage vitamin E supplementation may increase all-cause mortality. Annals of Internal Medicine 2005;142(1):37-46. [DARE Abstract]

10. Shekelle PG, Morton SC, Jungvig LK, Udani J, Spar M, Tu W, Suttorp MJ, Coulter I, Newberry SJ, Hardy M. Effect of supplemental vitamin E for the prevention and treatment of cardiovascular disease. Journal of General Internal Medicine 2004;19(4):380-9. [DARE Abstract]

11. Ritenbaugh C, Streit K, Helfand M. Routine vitamin supplementation to prevent cancer: a summary of the evidence from randomized controlled trials for the U.S. Preventive Services Task Force. Rockville, MD, USA: Agency for Healthcare Research and Quality; 2004. [DARE Abstract]

12. Alkhenizan AH, Al-Omran MA. The role of vitamin E in the prevention of coronary events and stroke: meta-analysis of randomized controlled trials. Saudi Medical Journal 2004;25(12):1808-14. [DARE Abstract]

13. Lonn EM, Yusuf S. Is there a role for antioxidant vitamins in the prevention of cardiovascular diseases: an update on epidemiological and clinical trials data. Canadian Journal of Cardiology 1997;13(10):957-65. [DARE Abstract]

Consumer information

British Heart Foundation

British Nutrition Foundation

Food Standards Agency - Vitamins and minerals

NHS Direct - Do I need vitamin supplements?

Previous Hitting the Headlines summaries on this topic

'Vitamins health fear'. Hitting the Headlines archive, 4 April 2005.

Vitamin E 'could raise risk of heart failure'. Hitting the Headlines archive, 17 March 2005.

Vitamins and their effects on gastrointestinal cancer and death. Hitting the Headlines archive, 4 October 2004.

Too many vitamins may be bad for you. Hitting the Headlines archive, 9 May 2003.

Vitamin pills 'are useless'. Hitting the Headlines archive, 8 July 2002.

reposted from: NHS
my: highlights / emphasis / key points / comments

What put the BANG in the BIG BANG?

Inside inflation: after the big bang

• 03 March 2007
• From New Scientist Print Edition. Subscribe and get 4 free issues.
• Peter Coles

MASSACHUSETTS, 1981. A young physicist comes up with what seems to be an absurd idea: the universe went through a period of ultra-fast expansion just after the big bang. Alan Guth cannot prove that this "inflation" actually happened nor can he suggest a compelling physical reason why it should have, but the idea seems nevertheless to solve several major problems in cosmology.

Fast forward to today. Guth is a professor at the Massachusetts Institute of Technology and inflation is now well established as an essential component of cosmology. But should it be?

There is little direct evidence that inflation actually took place. Observations of the cosmic microwave background - "fossil" radiation from the big bang - are consistent with the idea that inflation took place, but that doesn't mean it actually happened. What's more, we still don't know what would have caused it if it did. So how confident can we be that inflation is really a part of the universe's history?

A quarter of a century ago, our understanding of the universe was much less precise than it is today. In those days it was a domain in which theoretical speculation ruled over measurement and observation. Technology simply wasn't up to the task of performing large-scale galaxy surveys or detecting the all-important details in the cosmic microwave background (see "Shadow of the big bang").

“14 billion light years = size of the observable universe today”

The lack of stringent experimental constraints made cosmology a theorists' paradise in which many imaginative and esoteric ideas blossomed. Not all survived to be included in the standard model of cosmology, but inflation has proved to be one of the hardiest, and indeed most beautiful, flowers in the cosmological garden.

Although some of the concepts involved had been formulated in the 1970s by Russian physicist Alexei Starobinsky, it was Guth's 1981 paper that first crystallised the picture of the inflationary universe. At this time cosmologists didn't know that the universe was as flat as we now believe it is, but it was still a puzzle why it was even anywhere near flat. After all, the great breakthrough of Einstein's general theory of relativity was the realisation that space could be curved. Of all the possible initial conditions, isn't it very improbable that our universe should be flat?

What's more, the distribution of stuff in our universe is also astonishingly smooth. Although it contains galaxies that cluster into immense chains more than a 100 million light years long, on scales of billions of light years it is almost uniform. This also seems surprising. Why is the celestial tablecloth so immaculately ironed?

Guth grappled with these questions and realised that they could be resolved rather elegantly if only the force of gravity could be persuaded to change from pull to push for a very short time just after the big bang. The expansion of the universe would then speed up rather than slow down. The universe could then inflate by an enormous factor (10³⁰ or more) in a fraction of a millisecond. Even if it were initially curved and wrinkled, all memory of this messy starting configuration would be wiped out. The present-day universe would be very flat and very smooth no matter how it had started out.

“>10³⁰ = factor by which the universe expanded”

So how could this bizarre period of anti-gravity be possible? Guth hit upon a simple physical mechanism by which inflation might just work in practice. It relied on the fact that in the extreme conditions just after the big bang, matter would not adhere to the classical laws describing gases and liquids but must instead be described by quantum field theory. The simplest type of quantum field is called a scalar field; such objects are associated with particles that have no spin, the quantum parallel of angular momentum. Modern particle theory involves many scalar fields that are not observed in low-energy interactions, but which may well dominate affairs at the extreme energies of the primordial fireball.

Just as classical fluids can undergo a "phase transition" if they are heated or cooled, such as the transition from steam to liquid water, a similar thing happens with scalar fields: their configuration is expected to change as the universe expands and cools. Phase transitions do not happen instantaneously, however, and sometimes a bubble of the substance involved can get trapped in an uncomfortable state in between where it was and where it wants to be, like a bubble of gas trapped in a liquid.

Guth realised that if a scalar field got stuck in such a false state, it could free up energy - in a form known as vacuum energy - to drive a small piece of the universe into accelerated expansion. In the process, the tiny bubble can inflate to the size of the entire universe. We don't know which scalar field of the many that may theoretically exist is responsible for generating inflation, but whatever it is, it is now dubbed the inflaton.

“10^-35 seconds = age of the universe when inflation kicked in”

This mechanism is an echo of a much earlier idea introduced to the world of cosmology by Einstein in 1916, although he didn't use the term vacuum energy. He called it a cosmological constant, and also considered it to be a modification of the law of gravity rather than something arising from quantum fields. Nevertheless, Einstein's idea was incorporated by Dutch mathematician Willem de Sitter into a theoretical model of an accelerating universe. This is essentially the same mathematics that is used in modern inflationary cosmology.

The connection between scalar fields and the cosmological constant may also eventually explain why our universe's expansion seems to be accelerating now - something that has been attributed to a mysterious force called dark energy. However, that would require a scalar field with a much lower energy than that required to drive inflation. Perhaps dark energy is some kind of shadow of the inflaton.

Guth wasn't the sole creator of inflation. About the same time, many others including Andy Albrecht, Paul Steinhardt, Andrei Linde and Starobinsky, produced different and in some cases more compelling variations on the basic theme. It was almost as if it was an idea whose time had come. Within just a few years inflation had become an indispensable part of cosmological theory.

“10^-27 metres = size of the observable universe before inflation”

Literally hundreds of versions appeared in the leading scientific journals: old inflation, new inflation, chaotic inflation, extended inflation, and so on. Out of this activity came the realisation that a phase transition wasn't really necessary, all that mattered was that the scalar field should find itself in a state where the vacuum energy dominated.

It also became clear that even theories that didn't involve scalar fields could behave as if they did. Modified gravity or theories with extra space-time dimensions provided ways of mimicking scalar fields with rather different physics. And if inflation could work with one scalar field, why not have inflation with two or more? The only problem was that there wasn't a shred of evidence that inflation had actually happened.

This episode provides a fascinating glimpse into the historical and sociological development of cosmology in the 1980s and 1990s. Inflation is undoubtedly a beautiful idea, but the problems it solves are theoretical, not observational. For example, the flatness of the universe only appears to require this explanation because we don't have a theory of initial conditions for the universe that might provide a better reason. Inflation turns an initially curved universe into a flat one, but the fact that the universe appears to be flat doesn't prove that inflation happened.

Certain initial conditions could lead to present-day flatness without the intervention of an inflationary epoch. One might argue that these are special cases and therefore "improbable", making it more probable that inflation happened than that it didn't. On the other hand, without a theory of the initial conditions how can we say which are more probable? Based on this kind of argument alone, we could probably never work out whether we live in an inflationary universe or not.

But there is another thread in the story that makes it a much more compelling scientific theory, because it makes direct contact with observations. Although it was not the original motivation for the idea, Guth and others realised very early on that if a scalar field were responsible for inflation then it should be governed by the usual rules of quantum fields.

One of the things that quantum physics tells us is that no quantum process evolves entirely smoothly. The famous Heisenberg uncertainty principle imposes a degree of unpredictability on the behaviour of the inflaton. The upshot of this is that although inflation smoothes away any primordial wrinkles in the fabric of space-time, in the process it lays down others of its own.

“100 micrometres = size of the universe if inflation hadn't happened”

The inflationary wrinkles are really ripples, wave-like density fluctuations vibrating through the matter of the early universe like sound waves travelling through air. Without these fluctuations the cosmos would be smooth and featureless, containing no variations in density or pressure, and therefore no sound waves. Even if it began in a fireball, such a universe would be silent. Inflation puts the "bang" in big bang.

The acoustic oscillations generated by inflation comprise a wide range of wavelengths. Most importantly of all, they are formed "coherently". That is, because inflation happens so rapidly, all of the acoustic wavelengths are excited at the same time, just as hitting a metal pipe with a hammer generates a wide range of frequencies, all starting at the same time. The result is not just random noise but something more tuneful. The big bang wasn't exactly melodic, but there is a discernible relic of the coherent nature of the sound waves in the pattern of temperature fluctuations in the cosmic microwave background as seen by NASA's Wilkinson Microwave Anisotropy Probe (WMAP). The hot and cold spots of the microwave background reflect denser or rarefied regions, and the acoustic peaks seen by WMAP offer compelling proof that whatever generated the pattern did so coherently.

There are very few alternative theories capable of reproducing the WMAP results. Some interesting ideas have emerged recently from string theory. Since this theory requires more space-time dimensions than the four we are used to, something has to be done with the extra ones we don't observe. For example, in so-called braneworld cosmologies our four-dimensional universe exists as a subset (called a brane) of a more multi-dimensional space.

This idea may one day lead to a viable alternative to inflation. But it is early days and not all the calculations needed to establish this theory have yet been done. In any case, not every cosmologist feels the urge to make cosmology consistent with string theory, which has even less evidence in favour of it than inflation. So does WMAP prove inflation happened? If not, will we ever know?

It is difficult to talk sensibly about scientific proof of phenomena that are so far removed from everyday experience. At what level can we prove anything in astronomy? We all accept that the Earth goes around the sun, but do we really know for sure that the universe is expanding? I would say that the latter hypothesis has survived so many tests and is consistent with so many other aspects of cosmology that it has become, for pragmatic reasons, an indispensable part of our world view. But I would hesitate to say that it was proven beyond all reasonable doubt.

The same goes for inflation. It is a beautiful idea that fits snugly with standard cosmology and binds many parts of it together but that doesn't necessarily make it true. Many theories are beautiful, but that is not sufficient to prove them right. When generating theoretical ideas scientists should be fearlessly radical, but when it comes to interpreting evidence we should all be deeply conservative.

As for the future of cosmology, WMAP has provided a tantalising glimpse of further evidence and paved the way for even more stringent tests of the standard framework. Primordial density fluctuations produce not only a pattern of temperature variations over the sky, but also a corresponding pattern of polarisation. This is fiendishly difficult to measure, partly because it is such a weak signal (only a few per cent of the temperature signal) and partly because the microwaves are heavily polluted by polarised radiation from our own galaxy. Although WMAP did indeed detect polarisation, the published map is heavily corrupted by foreground noise.

Future generations of experiments, such as the European Space Agency's Planck Surveyor, due for launch in 2008, will have to grapple with the thorny issue of foreground subtraction if it is to make progress. But there is a crucial means of cross-checking the results that would justify these endeavours. The key is that inflation does not just produce acoustic waves, it also generates twisting deformations of space-time called gravitational waves.

Gravitational waves produce a very particular form of polarisation pattern that cannot be generated by acoustic oscillations, so hunting for this signal seems a promising way to test inflation. Even though it is a very weak signal, and the experience of WMAP suggests it might be swamped by foreground noise, it is definitely worth a go. Finding it would add considerably to the evidence in favour of inflation as an element of physical reality.

“>1 kilometre = approximate size of the universe after inflation”

Besides providing strong evidence for the standard model of cosmology, WMAP has also provided tantalising evidence that we may be missing something. Not all the properties of the microwave sky seem consistent with the model. For example, the pattern of hot and cold spots should be structureless, mirroring the random fluctuations of the primordial density perturbations. In reality, certain components of the pattern are inexplicably aligned, as in the so-called "axis of evil" discovered in 2005 by Kate Land and João Magueijo of Imperial College London (New Scientist, 22 October 2005, p 19). These anomalies could be systematic errors in the data, or perhaps residual foreground effects that need to be subtracted, but they could equally indicate the presence of things that can't be described within the standard model.

Cosmology is now a mature and respectable science. Yet there are still many gaps in our knowledge. We don't know the form of the "dark matter" responsible for unexplained extra gravity. Nor do we have any real understanding of dark energy. We don't know for sure if inflation happened, and we are certainly a long way from being able to identify the inflaton. In a way we are still as confused as ever about how the universe began. But perhaps now we are confused on a higher level and for better reasons.

Peter Coles is professor of astrophysics at the University of Nottingham, UK. His latest book is From Cosmos to Chaos: The science of unpredictability (Oxford University Press)

From issue 2593 of New Scientist magazine, 03 March 2007, page 33-37

Shadow of the big bang

Our ability to reconstruct the history of the universe, or at least to attempt this feat, depends on the fact that light travels with a finite speed. The further away we see a light source, the further back in time its light was emitted. We can now observe light emitted from stars in distant galaxies when the universe was less than a sixth of its current size. In fact we can see even further back than this using microwave radiation rather than optical light.

Our universe is bathed in a faint glow of microwaves produced when it was about one-thousandth of its current size and had a temperature of thousands of kelvin, rather than the chilly 3 K that prevails today. The existence of this cosmic background radiation is one of the key pieces of evidence in favour of the big bang model. It was discovered in 1965 by Arno Penzias and Robert Wilson, for which they subsequently won the Nobel prize.

It is not just the cosmic microwave background that has helped us construct the standard model of cosmology. Observations of distant supernovae and the pattern seen in the large-scale distribution of galaxies have also offered hints. The picture that has emerged from these disparate clues is of a universe dominated by dark energy and dark matter, in which the early stages of cosmic evolution involved an episode of accelerated expansion called inflation.

Assembling the standard model of cosmology has been a gradual process, reaching its latest form with recent results from NASA's Wilkinson Microwave Anisotropy Probe (WMAP). For several years this satellite has been mapping the properties of the cosmic microwave background and how it varies across the sky. Small variations in the temperature of the background reflect sound waves excited in the hot plasma of the primordial fireball (see Diagram). Various telltale properties of these waves allow us to probe the early universe in much the same way that solar astronomers use observations of the surface of the sun to understand its inner structure.

The detection of the primeval sound waves is one of the triumphs of modern cosmology, not least because the amplitude of the waves tells us precisely how loud the big bang really was. The fundamental tone tells us that the universe is very nearly flat, while the overtones pin down a dozen or so important cosmological parameters to unprecedented accuracy - a truly remarkable achievement.

reposted from: New Scientist
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