Authors: John Gribbin
Although the physics of the 1960s could not say what went on during the split second following that beginning of time, it could describe in great detail everything that had happened to the Universe in the 14 billion years (the most precise current measurement of the age of the Universe is 13.798±0.037 billion years, which we'll round up to 14 billion) beginning just a tenth of a second later. To an increasing number of cosmologists, the general theory did not really seem such a bad description of the Universe, if it could explain everything that has happened in the past 14 billion years except for the very first tenth of a second. This is what it told them.
One tenth of a second after the “beginning” (or after the “bounce,” as many cosmologists of the 1960s would have argued), the density of the Universe was 30 million times greater than the density of water. The temperature was 30
billion degrees,
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and the Universe consisted of a mixture of very high-energy radiation (photons) and material particles, including neutrons, protons, and electrons but also more exotic, unstable particles created ephemerally out of pure radiation. This is the ultimate example of the equivalence between mass and energy, expressed in Einstein's famous equation
E = mc
2
. On the Earth, in an atomic bomb, and inside the Sun, where nuclear reactions take place, tiny amounts of matter (
m
) are converted into large amounts of energy (
E
), because
c
is the speed of light, which is 300,000 kilometers a second, and
c
2
is a very large number indeed. (The
E
and
m
are in terms of joules and kilograms, respectively, and
c
is in terms of
meters
per second; 300,000,000
2
= 90 quadrillion.) But if you had enough energy to play with, you could actually make matter out of energy; and there was ample energy available to do the trick in the Big Bangâeven if many of the particles created in this way were unstable, destined to disappear again in a puff of radiation in far less than the blink of an eye.
One second later, 1.1 seconds after the beginning, the Universe had cooled dramaticallyâall the way down to 10 billion K. At that time, the density was just 380,000 times the density of water, and from then on the reactions between particles were very similar to the nuclear reactions that go on inside the Sun and other stars today.
At a temperature of 3 billion K, just under 14 seconds from the beginning, the first nuclei of deuterium could form, albeit temporarily. Hydrogen is the simplest atom, with just a single proton in its nucleus and one electron orbiting outside the nucleus. (In a sense, lone protons can be regarded as nuclei of hydrogen atoms.) The next most complicated atom is deuterium, which has a nucleus composed of one proton and one neutron, still with a single electron orbiting around it. Atoms that have the same number of electrons as each other but different numbers of neutrons still have identical chemical properties and are known as isotopes; deuterium is an isotope of hydrogen and is often known as “heavy hydrogen.”
Temperature is a measure of how fast, on average, the particles that make up matter are moving (which is why there can be no temperature colder than â273°C, at which atomic motion stops), and at temperatures above 3 billion K, protons and neutrons move too fast to do anything except bounce off each other. Some particles move faster than the average for a particular temperature and some slower, although most have speeds close to the average. So as the temperature fell below that value, some protons and neutrons were moving slowly enough to stick together when they collided. The thing that makes them stick is an attraction known as the strong force. As its name suggests, this is a powerful force of attraction that operates between all protons and neutrons. But it has a very short range, and fast-moving particles brush past or bounce off each other too quickly for the strong force to take hold of them during the brief time they are in range. At first, most of the deuterium nuclei produced in this way were knocked apart by collisions with faster-moving particles; but as the
fireball cooled still further, the deuterium nuclei had a better and better chance of survival.
Just 3 minutes and 2 seconds after the beginning, the temperature had cooled to below 1 billion Kâthe entire Universe was then only seventy times as hot as the heart of the Sun is today. At this point, almost all the deuterium nuclei were able to combine in pairs to form nuclei of helium. Helium nuclei each contain two protons and two neutrons, making four “nucleons” in all, so they are known as helium-4 nuclei (and helium atoms, of course, each have two electrons orbiting around the nucleus).
It happens that helium-4 nuclei are particularly stable. But there are no stable nuclei containing five nucleons (such as you might expect to get if you added a proton or a neutron to a nucleus of helium-4) or eight nucleons (such as you might expect to get if you stuck two helium-4 nuclei together). So the process of “nucleosynthesis” in the Big Bang stopped with the production of helium-4. Less than 4 minutes after the beginning, matter had settled down into a mixture of about 75 percent hydrogen nuclei and 25 percent helium, intermingling with fast-moving electrons and bathed in a sea of hot radiation.
Half an hour later, 34 minutes after the beginning, the temperature was down to 300 million K, and the density of the Universe was only 10 percent of the density of water. But it took a further 700,000 years for the Universe to cool enough to allow electrons to become attached to the nuclei and form stable atoms. Before then, as soon as a positively charged nucleus tried to latch on to a negatively charged electron, the electron would have been knocked away by an energetic photon. After 700,000 years, however, the temperature of the
Universe had fallen to about 4,000 K (roughly the temperature at the surface of the Sun today), and nuclei and electrons were at last able to hold together to form stable atoms.
For most of the past 14 billion years, protons, neutrons, and electrons have been bound up in stars and galaxies formed out of this primeval stuff, as gravity pulled clouds of gas together in space. The radiation left over from the Big Bang had nothing more to do with the matter, once it was no longer hot enough to separate electrons from their atomic nuclei and simply cooled steadily as the Universe expanded. But as we shall see, that background radiation, the echo of creation, had a key role to play in persuading cosmologists that one of their “model universes” might actually be telling them something deeply significant about the real Universe. And all this was happening while the person who was to become a key player in taking cosmology that step further in the 1970s, back to the beginning itself, was experiencing upheavals of his own, both personal and professional.
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Physicists measure temperature in degrees kelvin, denoted by the letter K. This scale of measurement starts from the absolute zero of temperature, at â273°C, where all thermal motion of atoms stops. But a little matter of 273 degrees is neither here nor there when we are measuring temperatures in billions of degrees, so for all practical purposes the temperatures given for the fireball are the same as degrees Celsius.
T
he mid-sixties turned out to be one of the most important times in Stephen Hawking's life. Having become engaged to Jane, he realized that he would need to find a job very quickly if they were to be married. After obtaining a doctorate, the next stage in the career of any academic is usually to secure a fellowship, accompanied by a grant, in order to continue research. Much like the transition from undergraduate studies to postgraduate research, applications for fellowships
are usually made while working on a Ph.D. rather than leaving things until afterward. So while in the throes of writing his thesis, and with a wedding planned for the coming summer, Hawking had to look around for available posts. Fortunately he did not have to look far. He heard about a theoretical physics fellowship being offered by another college at the university, Caius,
*
to begin that autumn. Without hesitating, he began to organize his application. However, getting such a relatively simple thing off the ground did not turn out to be as easy as he had hoped.
At this stage of his illness, he was unable to write and had planned to ask Jane to type his application during her next visit to Cambridge the coming weekend. But when his fiancée stepped off the train, she greeted him with her arm in plaster up to the elbow. She had had an accident the previous week, breaking her arm. Hawking admits that he was not as sympathetic toward her as perhaps he should have been when he saw the state she was in, but hurt feelings were quickly mended and together they tried to work out how they could get the application written. Jane's left arm had been broken and she is right-handed, so Hawking dictated the information and she was able to write the application by hand. They then managed to get a friend in Cambridge to type it up for them.
However, that was not the end of Hawking's problems. As a requirement of the application he had to give two references. Obviously Dennis Sciama was his first referee; he was, naturally, very supportive, and suggested Hermann Bondi as the second. Hawking had met Bondi on several occasions at
the King's College seminars given by Roger Penrose earlier that year, and Bondi had communicated to him a paper he had written to the Royal Society a few months earlier. Encouraged by this, Hawking decided, with near-catastrophic consequences, to ask Bondi to give him a reference. As Hawking puts it:
I asked him after a lecture he gave in Cambridge. He looked at me in a vague way, and said, yes he would. Obviously, he didn't remember me, for when the College wrote to him for a reference, he replied that he had not heard of me.
1
If such a serious blow had happened today, he would almost certainly not have had a hope of getting his fellowship. In the sixties, however, competition for academic posts was not quite as fierce as it is now, and the authorities at Caius showed great tolerance in writing to tell him of the embarrassing situation. Sciama came to the rescue again and contacted Bondi to refresh his memory about the promising young researcher. Bondi then gave Hawking a glowing reference, possibly far kinder than one he might originally have written.
The college council at Caius meets annually during the Lent term to elect new fellows. There are usually six or seven positions on offer, covering the full spectrum of subjects, and if elected, the successful applicant joins the seventy-odd fellows already in residence at the college. The council consists of around a dozen senior fellows, headed by the college master. In 1965 the master was the famous historian of Chinese science, Joseph Needham. Hawking came with good
recommendations, and a number of the science fellows on the council, including Needham, had heard of him via the early reputation he had already gained in Cambridge academic circles. As Shakespeare says, “Sweet are the uses of adversity,” and maybe this has never been truer than in Hawking's case. Despite the confusion over references, the council favored him over his competitors, and he received his fellowship at Caius. As far as Hawking's career was concerned, he and Jane could now look to the future with a degree of confidence.
The duties of fellows are minimal beyond the basic condition that they continue with their research. They are required to do a little student supervision, but the level to which this is taken varies enormously. The role of the fellow, like many other things at Cambridge University, has changed little since Sir Isaac Newton's time. Fellowship is considered a great honor and a means by which academics may continue with their research and be paid for it. In return, a college gains prestige if one of its fellows turns out to be highly successful.
Possessing more than his fair share of cheek, Hawking nearly blew it again after having secured his fellowship at Caius. He managed this feat by almost pushing things too far with the Bursar. On a whim, he decided to ask him what he would be paid for his new position and was rebuked for his impertinence. Although he could not foresee it at the time, soon after they were married, this
faux pas
would cause him and Jane still further problems.
The couple was married in July 1965 in the chapel of Hawking's postgraduate college, Trinity Hall. It was not a typical “academic” wedding, but neither was it, by any means, a society occasion. Both sets of parents were ordinary,
middle-class people. Jane's father, George Wilde, was a civil servant, and the Wilde family had known the Hawkings for some time before their children had met, so the wedding arrangements were perhaps a little less fraught with arguments than they might have been. Around a hundred guests attended, and the service was followed by a reception with all the usual speeches and champagne toasts to the happy couple. Brandon Carter remembers the wedding as the first occasion on which he met the Hawking family. He recalls Frank Hawking as a tall, slim man with a quiet and dignified air about him. Hawking's mother, Isobel, was instantly friendly and chirpy, a lively, gregarious character who delighted in meeting Stephen's friends and accepting them into the fold.
Despite the fact that the groom had to lean on a cane for the wedding photographs, the couple looked much the same as any other on their wedding day. In the black-and-white photographs, Hawking is wearing a dark suit and a thin, neatly knotted tie, his dark-rimmed glasses and thin face giving him an owlish look. Jane stands beside him, hands clutching a bouquet of flowers, her veil pushed back to reveal shoulder-length hair curled outward above the neckline of her short wedding dress in the fashion of the day. Hawking looks at the camera with a proud expression, a stare of deep-rooted determination and ambitionâa stance that says “This is just the beginning.” Jane smiles happily at the lens, equally sure, in her own gentler way, that they will make out and overcome all adversity.