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CNRS is deeply saddened to learn that Georges Charpak, winner of the 1992 Nobel Prize in physics, has passed away. This exceptional physicist, a pioneer of major advances in his field, began his career at the CNRS in 1948.

"Georges Charpak was an innovative, humanist thinker. He made an immense contribution to research in France and worldwide," comments CNRS president Alain Fuchs. "His work revolutionized subatomic physics and opened the way to the digital age. His invention of multiwire chambers, which earned him the Nobel Prize in 1992, was the precursor of the detectors used today in fundamental physics, without which many discoveries would not have been possible. It also paved the way for the development of a number of major applications and advances, particularly in the field of medical imaging."

For Jacques Martino, director of CNRS's National Institute of Nuclear and Particle Physics (IN2P3), "Georges Charpak led a prodigious life. He became a Resistance fighter and studied with Frédéric Joliot-Curie. His loss means a page of history is turned. On behalf of the IN2P3 and CNRS, I wish to pay my respects to this enlightened, creative mind, who inspired and will continue to inspire many generations of researchers."

Georges Charpak was born in Dabrovika, Poland on March 8, 1924. He arrived in France in 1931 and joined the Resistance in 1942 but he was arrested and deported to Dachau. He returned to France after the war and became a French citizen in 1946. After graduating from the École des Mines engineering school in Paris, he joined CNRS in 1948 to work at the Collège de France nuclear physics laboratory, headed by his former professor Frédéric Joliot-Curie. Charpak earned his Ph.D. in 1954. In 1959, he went to work for CERN in Geneva, where he focused on the development of new techniques for particle physics detectors. This led him to invent, in 1968, the "multiwire proportional chamber", an instrument that would revolutionize particle detection, bringing it into the electronic age. In 1992, he won the Nobel Prize in physics for this invention, which is now widely used as the basis for modern-day particle detectors. His discovery found many important applications, especially in medicine. Charpak's work led to significant improvements in medical radiography, making it possible to reduce patients' exposure to radiation.

Georges Charpak was also a tireless teacher. Co-founder of the "La Main à la Pâte" ("Hands On") movement, an educational program to promote experimental sciences in elementary schools, he was always deeply committed to education, sharing his knowledge and enthusiasm with the younger generations.

Voyager - the space explorers that are still boldly going to the stars

Nasa's two Voyager ships have reached the edge of the solar system – and their incredible 35-year journey is far from over



Voyager 2 passed Jupiter in 1979. Ten years later, after observing Neptune, it began its journey out of the solar system. Composite: BBC2

The year 1977 was an important one for music. Fleetwood Mac's Rumours and the Sex Pistols' Never Mind the Bollocks were released. Elvis left the building for the last time, dying at the age of only 42. But amid all this rock'n'roll history another less celebrated but far more significant album was quietly being made.

Fashioned from copper rather than vinyl, and plated with gold for longevity, The Sounds Of Earth was compiled by the American astronomer Carl Sagan. It was a broader range of music than most of the other albums released that year, aiming to encapsulate 5,000 years of human culture; from an Australian Aborigine song and an Indian raga to Azerbaijani bagpipes, bamboo flutes, Bach, Beethoven and Chuck Berry.

Like any compilation album, each piece was carefully selected and its merit, to make the cut, hotly debated. But unlike most other records, only two copies were made. They were placed inside their aluminium album covers, complete with artwork in the form of a "clear", universally understandable, pictorial depiction of what they were and instructions for how to play them. A stylus was also included, to help any creatures that might chance upon them in the future to hear the music and other recordings. In a scene that would not have been out of place in Ridley Scott's recent Prometheus, they were then carefully bolted to the outside of the two Voyager spacecraft, by the last human beings ever to touch them.

The records sit on one face of each craft's 10-sided "chassis" or bus, above which sits the large, white 3.7-metre wide communications dish, which dominates the structure. Protruding, insect-like, from the craft are "limbs" and antennae. The radioisotope thermoelectric generators, which power the Voyagers in the darkest reaches of the outer solar system, stretch out to on one side, just below a proboscis-like, 13m-long magnetometer boom. Across the other side of the craft, another broad arm juts out. It carries Voyager's "eyes" – an array of cameras, spectrometers, particle detectors and other equipment.

The challenge for Nasa's Jet Propulsion Lab, which designed and constructed the Voyagers, was to build a craft that could survive in space for years. In the early 1970s, when the JPL team began the project, they'd never built a craft rated for longer than a few months of interplanetary travel. It was a big jump to create something that would reach the outer planets, and perhaps even farther.

"At that point in time, that was a mind-blowing thought," says Voyager systems engineer John Casani. "How you build a spacecraft that can survive failures and still keep on chugging. We thought we could do it. Nobody else did!"

Half a decade of back-breaking building and testing followed, to create a craft which was up to the job. As the build was nearing completion Casani decided to do something unique, to celebrate the sacrifices of his 2,000-strong engineering team and their families had made. During an open house party held to mark the end of Voyager's design phase, he invited everyone there to sign their names on large sheets of paper. He then had these papers reduced and reproduced onto six small metal plaques, still large enough to read the individual names. These were then stitched into the thermal blankets inside the main spacecraft bus, as a memorial to those whose ingenuity, skill and support had made these unique machines possible.

With these signatures and their golden records on board, the twin spacecraft were launched in late summer of 1977 from Cape Canaveral and placed on a "grand tour" trajectory that would carry them on fleeting, but historic fly-bys of Jupiter and its moons, and then on to Saturn and its rings. Deflected towards Saturn's moon Titan, Voyager 1 would head out of the plane of the solar system and off in the direction of the northern constellation of Camelopardalis.

Voyager 2 would carry on towards an encounter with Uranus in 1986 and Neptune in 1989, which would accelerate it to more than 50,000mph and hurl it in the direction of the brightest star in our sky – Sirius.

On the course of this journey past the giant planets, the craft returned more than 67,000 photographs – among them stunning images of worlds we hadn't even dreamt of. As Voyager's chief scientist Ed Stone put it as they flew past Saturn: "Our imaginations were not nearly up to what nature provided." The pictures have challenged our understanding of meteorology and geology – redefining our understanding of the solar system and of planetary science as a discipline.

These were places that we had only known as fuzzy pinpricks of light seen through telescopes from Earth before Voyager. These two spacecraft on the grandest of grand tours have taught us more about the outer solar system in the last 35 years than in all of human history. It was, and still is mankind's greatest voyage of discovery. But it is perhaps appropriate that the final image captured by Voyager, the image for which the mission is best remembered, was of ourselves.

On Valentine's Day 1990 Voyager 1 was instructed to turn its cameras around to snap a final family portrait of as many of the planets as possible, seen uniquely from 6bn km above the solar system. The imaging team knew that, from this distance, each planet would occupy less than a pixel.

It would be the farthest picture ever taken of home, capturing us as a single speck – an almost invisible point in the black ocean of space. At first when the photograph was printed, Earth was mistaken as a speck of dust which Voyager scientists initially tried to brush off the glossy print! But this visually underwhelming image of Earth – a "pale blue dot" as Sagan described it – was as profound as the spectacular whole Earth images captured by the Apollo astronauts some 20 years before.

Not long after taking this final picture, Voyager 1 passed the orbit of Pluto, and by the end of 2004 had entered the realm of the Kuiper belt – a band of dark, Pluto-like worlds of rock and ice orbiting the Sun, almost imperceptibly far away. Voyager 2 reached this domain shortly afterwards. Today the two spacecraft still continue to hurtle away from us at 16km per second.

Thirty five years after leaving Earth, and now 18bn km from home, Voyager 1 is entering the "bow shock" - a region of space marking the boundary between the solar and the galactic winds – the edge of the Sun's influence. Voyager 2 has also encountered this frontier, as each craft prepares to enter the region astronomers call "interstellar space".

Five instruments on each craft are still functioning, reporting back the nature of this new environment into which we have extended our senses; characterising the new magnetic fields and galactic particles they are now in contact with.

Their public voice also continues to reach us from this distance. Despite being technologically frozen in the 1970s, the Voyagers have managed to embrace the digital age – now harnessing Twitter to communicate their story. When a Twitter follower asked 'what could Voyager 2 see?' it replied in fitting Sagan-esque prose: "I can sense stars and their whispers amid the roaring of our own sun".

Although they don't tweet every day, both craft still maintain daily contact with the Earth. Even travelling at the speed of light their messages take quite a long time to reach home. "The journey time is now about 15 hours each way," says Voyager's current manager Suzanne Dodd. "We sent a command Saturday morning and it came back Sunday afternoon." Dodd has been with Voyager since the mid-1980s, and likens keeping in touch with the spacecraft to the nurturing of an elderly senior citizen. "Sometimes they need a bit of tuning on their hearing!"

It's not just the Voyagers that are ageing. Everyone on the team has lived out their lives against the backdrop of their mission. "When I started on Voyager my two daughters were young," says Ed Stone, who has been on board since day one. "By the time they were in college we had passed Saturn and were on our way to Uranus. They got married and the Voyagers just kept going, and we had grandchildren and Voyager just kept going and our grandchildren are now aware of what's happening to the Voyagers just like our children were."

Barring any serious engineering failures, the Voyagers will both continue to report from interstellar space until around 2025, when declining power and propellant required to point their communication dishes towards Earth will gradually prevent them from calling home.

Were it not for these diminishing consumables, and the risk of losing their lock on the increasingly dim and distant Sun, Nasa could track them for another century or two.

But even without power the two Voyagers will continue to serve us. In the largely empty, benign environment of interstellar space, these craft are likely to last for millions of years. They will outlive the pyramids, they're likely to outlive us, and perhaps even the Earth itself; the only record of our existence, circling the galaxy for ever. If other intelligent, technological creatures ever find them, as they drift for eons in deep space, the craft will reveal something about the beings that built them. Our size and dexterity can be inferred from their scale. Their engineering sophistication will tell these creatures something about our technological and mathematical abilities, at least as they were in the 1970s. But the Voyagers' design alone will tell them nothing about what kind of creatures we really were.

So while the team at the Jet Propulsion Lab put the finishing touches to the Voyagers in early 1977, spacecraft engineer John Casani suggested to Carl Sagan that they include something on board each craft that would address this. Sagan reasoned that music might be the best way of communicating to other creatures something more about us. "Could the meaning of music be understood by something else," Sagan wondered. "The soaring emotions from music might be a mystery to them, but if we were to convey something of what humans were about then music has to be a part of it," he later recalled in an interview with BBC Radio 4.

Sagan quickly pitched the idea for the golden records, estimating it would cost $25,000 to make them. Casani agreed and Sagan and team member Ann Druyan set about choosing the music. They had just six weeks to assemble the album, the most symbolic music compilation project in history. It was an almost impossible task, by Sagan's own admission.

A frantic consultation with musicologists around the world ensued, as Druyan, who later became Sagan's wife, battled to track down 26 specific recordings, which reflected something of the emergence and evolution of music on Earth.

When the physician and biology writer Lewis Thomas was asked which tracks he would send he quickly replied 'the complete works of JS Bach …" before adding, after a pause " … But that would be boasting!" But The Sounds of Earth does carry more from Bach than any other single composer, with three pieces chosen to reflect the evolution of his style.

As with any mixtape project, particularly one intended to represent something of our diversity as a species and what it means to be a human, there are going to be some obvious omissions; not least the Beatles. Druyan was hoping for Here Comes the Sun but the request was turned down by the band's record company, as they presumably couldn't agree to clearance for the rights "in perpetuity, across the known Universe".

But the most striking story from this effort to compile the golden record concerns the closing piece for the album; Beethoven's Cavatina from the String Quartet No. 13 in B flat, Op 130. Whilst researching an article about the project for the New York Times, Druyan had looked at Beethoven's diaries, and: "in his own hand he'd written: 'will they like my music on Venus? What will they think of it on Uranus…" At last, a way to respond to that impulse, that question that Beethoven asked so long ago, she felt.

Despite its ambition, and the epic time scales over which the Voyagers are likely to survive, given the vastness of space, these two tiny craft and their golden records are unlikely ever to be found. But Sagan was clever enough to realise this. For him it wasn't so much what the records said to other civilisations that mattered, but more significant was what they said about our own. Like the pale blue dot photograph captured by Voyager 1, the compilation record was a mirror to hold up to ourselves.

"Here is a moment when we have to suddenly think what is it about our culture we'd want others to know about, that we'd be proud of," Sagan reflected in a 1982 interview. "The record should represent the human species as an entirety. We are a single species on the planet Earth. The unity of the species seen down here is a fact that is essential for the human future."

As our first interstellar ambassadors set sail on this new sea, it's worth reflecting once more on this unique vantage point which such exploration, far beyond our "pale blue dot" offers us. From such a perspective national boundaries melt away and ethnic, religious or ideological differences seem an irrelevant way to define our identity.

In the summer of 1977 the launching of our collective message in a bottle into the cosmic ocean was a highly optimistic gesture, which briefly put all our tribal differences aside. This optimism is perhaps best summed up by one of the voice recordings it carries. "This is a present from a small, distant world, a token of our sounds, our science, our images, our music, our thoughts and our feelings. We are attempting to survive our time so we may live into yours."



Campbell and Riley's documentary, Voyager – to the Final Frontier, is on BBC4 at 9pm on 24 October. Hear the Voyager golden discs' playlist at goldenrecord.org.




The future and futurology

The way we are going

Oct 9th 2003


From The Economist print edition


Tomorrow's People: How 21st-Century Technology is Changing the Way We Think and Feel
By Susan Greenfield



Penguin/Allen Lane; 288 pages; £20




IN HER preface, Susan Greenfield, a distinguished neuroscientist, admits that she had really wanted to write a novel, a story, seen “through the eyes of a brilliant and beautiful heroine, a female neuroscientist”, about the kind of lives we will be living towards the end of this century. Although she dropped the idea in favour of a work of non-fiction, “Tomorrow's People” is set firmly in the dystopian tradition of Huxley and Orwell. Baroness Greenfield's purpose is to issue a warning: that the coming integration of IT and biotechnology will have such a profound effect on the way we think and live that “we are standing on the brink of a mind makeover more cataclysmic that anything in our history.”

Baroness Greenfield is acutely aware of the perils of futurology. Visions from the 1950s of a world in which robots performed the domestic chores, meals were taken as pills and we zoomed around in personal helicopters were touchingly wide of the mark. Critically, nobody from that era foresaw the rise and ubiquity of the computer. Thomas Watson, the legendary boss of IBM, once famously predicted that there might turn out to be a world market for just five computers.

In Baroness Greenfield's vision of the future there is no dividing line between the real and the virtual, and most of our experiences are shaped either by a souped-up version of the internet or by smart drugs. We will rarely have to leave our homes, which will become an extension of our minds and bodies. Entertainment will be on tap to match our moods, while our physical environment, from the view through our windows to the shape of our rooms and the furniture inside them, will have the protean ability to adapt itself to our desires and needs. There will be no cancer or baldness or obesity. Nano-machines inside our bodies will change our appearance at will. Our bodily functions will be monitored and any incipient malfunctions dealt with by clothes that both dispense drugs and have the happy knack of cleaning themselves.

Relationships with other human beings will increasingly become too troublesome and unrewarding compared with the more immediate satisfactions to be had from the ever-present networked screens. We will be able to have sex virtually with anyone, while reproduction will be possible at any stage of our lives and regardless of our sexuality.


Knowledge of any skills other than those of the technological elite will become a redundant concept because all the information we will ever need will be instantly available to us all, and because intelligent machines will be able to undertake almost any task better and more quickly that we can ourselves. Reading and writing will be redundant. As for privacy—what was that?
What makes this at least semi-believable is that the technology probably will soon be available to render much of this possible. Moore's Law alone, which decrees that computer-processing power will double every 18 months and has at least another ten years to run, will soon allow computers to do things that are almost unimaginable. After that should come quantum computing—an advance comparable to the replacement of the vacuum tube by the transistor. As professor of pharmacology at Oxford University, Baroness Greenfield is well-placed to understand the impact of the next generation of mind-altering drugs, while the applications for nanotechnologies seem almost limitless.
The author is, thank goodness, horrified by the vision of the future she depicts: “The private ego is the most precious thing we have and it is far more vulnerable than ever before.” That ego, our individualism, is not, she argues, the automatic corollary of having been born human, but instead depends on the availability of an appropriate environment—an environment which, for the first time, we can no longer take for granted. What frightens her is the possibility that we will become so immobilised by dreams and shadows, so free of pain, mentally standardised by the cyber-world that is our principal habitat and rendered oblivious by chemicals, that we will have lost the ability to choose. Scary stuff indeed. That said, she surely makes insufficient allowance for the “yuck” factor. Human beings are a stubborn lot. If we don't like something, we're quite good at avoiding doing it.
Tomorrow's People: How 21st-Century Technology is Changing the Way We Think and Feel.

By Susan Greenfield.


Penguin/Allen Lane; 288 pages; £20

March 21, 2010 Women in science: Pioneers blaze path for others By Rachel Shields The Royal Society has named its top 10 female scientists, yet many still feel marginalised

They have mapped the infinity of space, developed spray-on skin for burns victims, pioneered cancer-beating therapies, created cutting-edge computer chips, discovered the first radio pulsars, and won Nobel prizes. But female science professors are still being asked to make the tea and take notes at meetings by their - often junior - male colleagues. Sexism remains all too prevalent in Britain's scientific community, according to some of its leading figures, even as The Royal Society unveils a list of the 10 greatest women scientists in British history. Women scientists this weekend called for government funding to be ring-fenced for projects headed by women, and men who are principal child carers, to help them get ahead in what remains a male-dominated profession. "If you are on high-level committees, you'll be asked to make the tea," said Professor Athene Donald, the deputy head of physics at Cambridge University. "Recently, on a committee, the chairman thought I was the secretary. And I've been in committees where we've been addressed as "gentlemen", despite the fact that there are women there. It is very off-putting."

Baroness Greenfield, who is suing the Royal Institution after it ousted her as its director in January, has criticised the Government for failing to provide enough financial support for women trying to make a career in the sector. "However much people support and encourage women, it has got to be backed by resources. The Government has never really delivered that," said Lady Greenfield. "I hope that the election campaign addresses this. What is needed is about £50,000 a year per woman, and then add the cost of equipment, and you are looking at £200,000 for one person. Science research is expensive." Lady Greenfield also argues that the insecure nature of science research puts women at a disadvantage: most scientists have to make do with temporary research contracts until they secure a fixed position in their thirties and forties; maternity leave provision is limited; and, for those in cutting-edge research, a career break at that stage can leave them way behind their male peers. "Many people won't have security of tenure until they are in their thirties. It is one of the few employment cultures with no security," she said.

It is thought that the subject's "nerdy" image puts girls off studying science beyond GCSE, and the sector also struggles to retain female graduates, with more than 70 per cent of women science graduates deciding on non-science related careers. One of the aims of the Government's 10-year strategy on science and technology, launched in 2004, was to encourage more women into the sectors. "The science and technology professions have been built by men, for men," said Annette Williams, the director of the UK Resource Centre for Women in Science, Engineering and Technology. The centre was established in 2004 to address the gender imbalance by using mentoring, training and networking. "Often, women can find the climate quite hostile. And science and technology are so male-dominated that they are behind other sectors in terms of things like flexible working," said Ms Williams.

The Royal Society, which did not allow female fellows to join until 1945, is using its 350th anniversary year to highlight the work of women scientists, such as Rosalind Franklin, whose work on DNA led directly to the discovery of the structure of the DNA molecule, and Dorothy Hodgkin, a Nobel prize-winner for chemistry. Despite the negative experiences of many female scientists, some believe that the situation is improving. "The number of women science professors rose from 8 per cent of the total in 2004 to 11 per cent now. I think we had something to do with that," said Ms Williams. While women may be under-represented in science, few are in favour of "quotas" of jobs being reserved for women. "Affirmative action can be very damaging. Women don't want to be appointed because they are women, they want to be appointed because they are good," said Professor Donald. "But if you advertise a job, you should have a proper search, and encourage women to come forward, not just appoint someone you know."

The Royal Society Top 10

1. Caroline Herschel (1750-1848)

As an assistant to her brother, a royal astronomer, Herschel discovered eight comets and catalogued star clusters. She was the first woman scientist to receive a salary and was awarded many honours.



2. Mary Somerville (1780-1872)

The Scottish scientist was only the second woman to receive recognition in the UK for her scientific experiments, which were on magnetism. Her popular renditions of the French astronomer Laplace's book Traité de Mécanique Céleste made her famous.



3. Mary Anning (1799-1847)

The daughter of poor Dis- senters, the palaeontologist made a number of important finds in Lyme Regis, including the first correctly identified ichthyosaur skeleton and the first two plesiosaur skeletons ever found. She also discovered important fish fossils.



4. Elizabeth Garrett Anderson (1836-1917)

Denied entry to medical school, Garrett Anderson instead passed the Society of Apothecaries examination to become the first English female doctor. She founded the New Hospital for Women in London and was influential in the passing of an Act permitting women to enter the medical profession in 1876.



5. Hertha Ayrton (1854-1923)

Working with her husband, Professor William Ayrton, Ayrton published several papers on the electric arc. In 1902 she became the first woman to be nominated as a fellow of the Royal Society, although as a married woman she could not accept.



6. Kathleen Lonsdale (1903-1971)

A pioneer of X-ray crystallography - the study of molecule shapes - in 1945 she and Marjory Stephenson were the first women to be admitted as fellows to the Royal Society. She was the first female professor at University College London, and the first woman to be president of the British Association for the Advancement of Science.



7. Elsie Widdowson (1908-2000)

Her work with Professor R A McCance revolutionised the way the world assessed nutritional values and how mammalian development was perceived. She worked on nutritional problems during the Second World War, and on treating the effects of starvation suffered by concentration camp victims.



8. Dorothy Hodgkin (1910-1994)

Hodgkin discovered the structure of penicillin and of vitamin B12. She was awarded the Nobel prize for her work, and was made a member of the Order of Merit. She devoted much of her later life to championing scientists in developing countries.



9. Rosalind Franklin (1920-1958)

Her work on the X-ray diffraction images of DNA was used to formulate Crick and Watson's 1953 hypothesis of the structure of DNA. She led the pioneering work on the tobacco mosaic and polio viruses.



10. Anne McLaren (1927-2007)

McLaren produced the first litter of mice grown from eggs that had been developed in tissue culture and transferred to a surrogate mother, paving the way for human in vitro fertilisation.



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