WHITE MARS (24 page)

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Authors: Brian Aldiss,Roger Penrose

Tags: #Science fiction, #General, #Science Fiction - General, #Fiction, #Fiction - Science Fiction, #Mars (Planet), #Space colonies, #Twenty-first century, #Brian - Prose & Criticism, #Utopias, #Utopian fiction, #Aldiss

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Euclid: 'They were?'

'Even last century, a number of theoreticians had realised that the enigma of mass could not be resolved at the energy levels relevant to the Higgs. Why? Well, the very concept of mass is all tied up with gravitation. Gravitation ... Let me give you an analogy, Euclid.

'Another long-standing "mystery" in particle physics is the mystery of electrical charge. It's a mystery of a sort let's say, although a good number of physicists would claim they understand why electric charge comes about.

'The trouble is that although there are good reasons why electric charge always comes in whole-number multiples of one basic charge - which is one twelfth of the charge of an electron - there's no real understanding why the basic charge has the particular value it happens to have.

'I should say there was a time, late last century, when this basic value was believed to be one third of the electron's charge. Before that it was held to be the electron's charge itself. But the one-third value is the quark charge, and it was still thought that quarks were fundamental. Only after Henry M'Bokoko's theory of leptons and pseudo-leptons was it realised there were yet more elementary entities. Things called kliks and pseudo-kliks underlay these particles in the same way quarks underlie the hadrons.

'These kliks, pseudo-kliks and quarks, taken together, gave rise to the basic one-twelfth charge that we know today. A diagram will make that clear.'

He flashed a vidslide in the air. It hung before the audience, a skeletal Rubik's cube in three dimensions.

'Now, there are certain fundamental "natural units" for the universe - the units Nature herself uses to measure things in the universe. Sometimes these are called Planck units, after the German physicist who formulated them in the early years of last century.

'You see how one finding builds on the previous one. That's part of the fascination which keeps scientists working. In terms of these units, the basic value of the electric charge turns out to be the number 0.007, or thereabouts. This number has never been properly explained. So we don't, even yet, properly understand electric charge. There is, indeed, still a charge mystery. End of analogy!'

Euclid, unblinkingly: 'So what follows?'

'The point about the mass mystery - a point made by a few physicists even as long ago as last century - was that no one would seriously attempt to find a fundamental solution to the charge mystery without bringing the electric field into consideration. Electric charge is the source of the electric field. In the same way, so the argument went, it made little sense trying to solve the mystery of mass without bringing in the gravitational field. Mass is, of course, the source of the gravitational field.

'And yet, you see, the original hopes of resolving the mystery of mass in terms of finding the Higgs particle made absolutely no reference to gravitation.'

Euclid: 'What do you make of all this?'

'It was really a whole bag of wishful thinking. You see, Euclid, finding the Higgs particle was considered just about within the capabilities of the physicists of the time. So, if a solution to the mystery of mass could be found that way - why, then it would have been pretty well within their grasp.

'But if the issue of the role of gravity had to be seriously faced - there would not have been a hope in Hell of their finding an answer to the origin of mass experimentally. They were looking for God with a candle!

'The energy required would have been what we call the Planck energy - which is larger than the Higgs energy by a factor of at least - well, if we said a few thousand million million, we wouldn't be far out.

'Put it this way. Even a collider the length of the Earth's orbit would not have been enough.' His young-old face broke into a broad grin at the thought of it.

Euclid: 'Yet you tell us that they still did not give up. Why is that?'

'As I told you, it was all wishful thinking. They believed that finding the Higgs would be enough. Anyhow, science often proceeds by being over-optimistic. It's a way in which things do eventually get done. Eventually.

'So although the mass mystery remains unsolved, we now think our project here could well be close to doing so.'

Euclid: 'More over-optimism?'

'No, this time the case is pretty convincing. The thing is that we are now really facing up to the Planck energy problem.'

Euclid: 'I may be only an android, but as far as I know our experiment does not involve a collider of anything like that length. Or any collider at all.'

Jon released a 3D projection of something like a dark matrix motorway into the lecture room. He let it hang there as he spoke. On that infinite road, smudges shot off endlessly into distance. A cloud of other coloured spots sped after them.

'We're looking at a VR projection of a succession of different smudges, alpha-, beta-, gamma-, delta-smudges. Artist's impression only, of course. You're right, we have no collider on Mars. I've said there were a couple of encouraging breakthroughs. Those breakthroughs make our Mars project possible.

'First breakthrough. The realisation that there was no point in working through this whole gamut of smudges, at greater and greater energy levels, the list continuing for ever.'

He switched off the projection. The scatter of smudges died in their tracks.

The Icelandic physicist, Iki Bengtsoen, showed that when Einstein's theory of gravitation - already confirmed to an unprecedented degree of accuracy - was appropriately incorporated into the Chin-Hawkwood smudge theory, it became obvious that the energies of all the different smudges, alpha, beta, gamma and so on, did not just increase indefinitely, sans limit, but converged on the Planck energy limit.

'You see what this implies? All would be resolved if just a single experiment could be devised to explore the "ultimate" smudge, that limiting smudge, where all the lower energy smudges are supposed to converge. It's this putative ultimate smudge we call the
Omega Smudge.'

Euclid. 'So we have got to it at last.' He maintained an expression of goodwill. 'But maybe you can explain how an experiment out here, on Mars, can be of particular use in finding this Flying Dutchman of a smudge - supposing it to exist at all.'

'That's where our other breakthrough comes in. Harrison Rosewall argued convincingly that a completely different kind of detector could be used to find this Omega Smudge, supposing it to exist at all.

'This involves the phenomenon known as "hidden symmetry".'

Euclid: 'And what might that be?'

Jon stood gazing at the low ceiling, as if seeking inspiration. Then he said, 'Every part of the explanation takes us deeper. These facts should have been part of everyone's education, rather than learning about past wars and histories of ancient nations. Well, I don't want to go into details, Euclid, but a hidden symmetry is a sort of theoretical symmetry which is dual in a certain sense, to a more manifest symmetry than might exist in theory. The idea goes back to some hypotheses popular late last century, although at that time the correct context for the hidden-symmetry idea was not found.

'What was important for Rosewall's scheme was that there can be things called monopoles associated with hidden-symmetry fields.

'A magnetic monopole would be a particle that has only a magnetic north pole or south pole assigned to it. As you know, an ordinary ferroperm magnet has a north pole at one end and a south pole at the other. Neither north nor south poles exist singly.

'But the great twentieth-century physicist, Paul Dirac, showed that the charge values had to be integer multiples of
something.
If you could find even a single example of a separate north or south pole, then - as we have since discovered to be the case - all electric charges would have to come in whole-number multiples of a basic charge.

'So, a number of years later, experimenters set to work to find such magnetic monopoles. If just one was found, then a major part of the mystery of electric charge would be solved. One group of experimenters even argued that the most likely place to find these things would be inside
oysters.
Of which, as we know, there's a considerable shortage on Mars.'

Euclid: 'Any luck?'

'No. No one has ever found a magnetic monopole, even to this day. But, in Rosewall's case, the hidden symmetry refers to a dual on the gravitational field. Rosewall made an impressive case that a hidden-symmetry gravitational monopole - known as a HIGMO -
ought
actually to exist. In fact there is a solution to the Einstein gravitational equations - found in the early 1960s, I believe - which describes the classical version of this monopole.

'This was Rosewall's brainwave. He realised that if you built a large ring-shaped tube, filled with an appropriate superfluid - argon 36 is what we use, under reduced pressure - then whenever a HIGMO passed through the ring, it would be detectable - just barely detectable - as a kind of "glitch" appearing in the superfluid.'

A voice from the audience asked, 'Why argon 36 and not 40?'

'Proton and neutron numbers are equal in argon 36, which underlies the reason for its remarkable superfluidity under reduced pressure. A technical advantage is the low pressure of the Martian atmosphere. Fortunately, argon 36 is not radioactive. Okay?'

At this point, he projected a vidslide of a scene I recognised. There lay the massive inflated tube, protected by its lid. There stood Dreiser, delivering his little speech. I had been a part of that historic scene!

'Obviously, this is a large-scale but delicate experiment. No other disturbances of any kind must affect the super-fluid in the tube. You have to do the best you can to shield the superfluid from external vibrations, because any significant outside activity is liable to ruin the experiment.

'No place on Earth is going to be remotely quiet enough for such an experiment. Never mind human activity, the magma under Earth's crust is itself active, like a giant tummy rumbling. Earth is an excitable planet.'

Euclid: 'What about Luna?'

'The Moon proved no longer possible. Too much tourist activity and mining was already taking place. Maybe forty years ago the Moon could still have been used, but not now, certainly not since they began building the transcore subway.

'But Mars ... Mars is ideal for the Omega Smudge experiment. No moving tectonic plates, vulcanism dead ... That is, it's ideal provided that human activity is kept down to present levels.'

Euclid: 'No terraforming?'

Thorgeson laughed. 'The UN did a trade-off. No terraforming for a few years. The hidden agenda was that this would give a breathing space for the Omega Smudge experiment. The gun at our heads is that we have to get results.'

At this there were rumblings from the audience, and an angry voice called, 'So how long is "a few years"? Tell us!'

After a moment's pause, Thorgeson said, 'There was to be a stand-off of thirty years - four years from now -before they began to bombard the Martian surface with CFC gases, to start the warming-up process. This was the deal pushed through by Thomas Gunther.'

This statement provoked angry interjections from the audience. Thorgeson calmed things down with a wave of his hand.

'Obviously the collapse of EUPACUS has altered all such arrangements.

'The experiment we're now getting under way involves only a relatively small ring, sixty kilometres in diameter. Will we discover any HIGMOs? That depends on the HIGMO density in the universe, of which there are only estimates so far. We need results. Otherwise - who knows -the terraformers take over, the CFC gases rain down...'

'Get on with it, then!' came a shout from the audience, followed by roars of support.

Thorgeson said, 'The terrestrial economy is still in meltdown. Don't worry.

'Our present experiment is basically a pilot project, partly to test out how we work in adverse conditions. Maybe we can manage with this. If not, we hope to build a superfluid ring around the entire planet.'

'Another way of ruining Mars!' yelled a voice.

'We need to solve the problem at last. With the planet ringed, the answer to the vexed question of mass will finally be answered. Maybe Mars was formed precisely to enable us to find that solution.'

'Victorianism!' came a cry from a now restive audience.

Thorgeson answered this cry directly. 'Okay, tell me what else is Mars good for? You invited me here. Listen to what I have to say. I'll take sensible questions afterwards. Till then, keep quiet, please.'

As if to back him up, Euclid spoke. 'Say why it is so important to solve the mystery of mass. If a few physicists satisfy their curiosity in this respect, what good does that do ordinary people?'

'It is always difficult to justify curiosity-driven research in terms of its ultimate benefit to society. We can't tell ahead of time. Nevertheless the effect of such research, which seems entirely abstract to the lay person, can be tremendous. An obvious example is Alan Turing's analysis of theoretical computing machines done in the 1930s. It changed the world in which we live. We are on Mars because of it.'

Euclid: 'You must have some idea as to the value of this immensely costly research in areas other than particle physics.'

'Smudge research will have an important impact on other areas of physics and astrophysics. After all, it is concerned with the deepest issues of the very building bricks of the universe, the particles of which we are all composed, and their constituent elements.

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