antiMatter
A matter-antimatter annihilation due to an atom of antihydrogen in the ATHENA experiment at CERN. The antiproton produces four charged pions (yellow), whose positions are given by silicon microstrips (pink) before depositing energy in CsI crystals (yellow cubes). The positron also annihilates to produce back-to-back gamma rays (red) (Image: CERN)
IT WAS not so long ago that we were hearing how CERN’s Large Hadron Collider would produce planet-destroying black holes. Now Dan Brown’s blockbuster, due to hit the big screen next month, provides us with another supposed danger emanating from the particle physics laboratory near Geneva, Switzerland: antimatter, the seed of a weapon of unsurpassed destructive power.
While Brown’s take on antimatter is fictional, the stuff certainly isn’t. We see its signature in cosmic rays, and it is routinely made in high-energy collisions inside particle smashers the world over. In hospitals, radioactive molecules that emit antimatter particles are used for imaging in the technique known as positron emission tomography.
Brown was right about one thing, though: if you want answers to the burning questions of antimatter, CERN is the place to go.
Where is all the antimatter?
If you were to list the imperfections of the standard model – physicists’ remarkably successful description of matter and its interactions – pretty high up would have to be its prediction that we don’t exist.
According to the theory, matter and antimatter were created in equal amounts at the big bang. By rights, they should have annihilated each other totally in the first second or so of the universe’s existence. The cosmos should be full of light and little else.
And yet here we are. So too are planets, stars and galaxies; all, as far as we can see, made exclusively out of matter. Reality 1, theory 0.
There are two plausible solutions to this existential mystery. First, there might be some subtle difference in the physics of matter and antimatter that left the early universe with a surplus of matter. While theory predicts that the antimatter world is a perfect reflection of our own, experiments have already found suspicious scratches in the mirror. In 1998, CERN experiments showed that one particular exotic particle, the kaon, turned into its antiparticle slightly more often than the reverse happened, creating a tiny imbalance between the two.
That lead was followed up by experiments at accelerators in California and Japan, which in 2001 uncovered a similar, more pronounced asymmetry among heavier cousins of the kaons known as B mesons. Once the LHC at CERN is back up and running later this year, its LHCb experiment will use a 4500-tonne detector to spy out billions of B mesons and pin down their secrets more exactly.
But LHCb won’t necessarily provide the final word on where all that antimatter went. "The effects seem too small to explain the large-scale asymmetry," says Frank Close, a particle physicist at the University of Oxford.
The second plausible answer to the matter mystery is that annihilation was not total in those first few seconds: somehow, matter and antimatter managed to escape each other’s fatal grasp. Somewhere out there, in some mirror region of the cosmos, antimatter is lurking and has coalesced into anti-stars, anti-galaxies and maybe even anti-life.
"It’s not such a daft idea," says Close. When a hot magnet cools, he points out, individual atoms can force their neighbours to align with magnetic fields, creating domains of magnetism pointing in different directions. A similar thing could have happened as the universe cooled after the big bang. "You might initially have a little extra matter over here and a little extra antimatter somewhere else," he says. Those small differences could expand into large separate regions over time.
These antimatter domains, if they exist, are certainly not nearby. Annihilation at the borders between areas of stars and anti-stars would produce an unmistakable signature of high-energy gamma rays. If a whole anti-galaxy were to collide with a regular galaxy, the resulting annihilation would be of unimaginably colossal proportions. We haven’t seen any such sign, but then again there’s a lot of universe that we haven’t looked at yet – and whole regions of it that are too far away ever to see.
Finding anti-helium or other anti-atoms heavier than hydrogen would be concrete evidence for an anti-cosmos. It would imply that anti-stars are cooking up anti-atoms through nuclear fusion, just as regular stars fuse normal atoms. The Alpha Magnetic Spectrometer is a $1.5 billion piece of kit built to scour cosmic rays for just such signs. It is grounded at the moment, waiting for a lift up to the International Space Station, but will hopefully hitch a ride on one of NASA’s final space shuttle launches in 2010 or 2011.
How do you make antimatter?
If we really wish to fathom the mysteries of antimatter, we must first get to grips with the stuff itself. Easier said than done. How on earth do you pin down a substance that vanishes the moment it touches anything?
Two CERN experiments, ATRAP and ALPHA, are grappling with that question. Their aim is to make antihydrogen – the simplest anti-atom possible, just an antiproton and a positron bound together – in sufficient quantity and for long enough to compare the spectrum of light it emits with that of regular hydrogen. Even the slightest difference between the two would shake up the standard model.
The experiments require a near-perfect vacuum, as encountering a mere atom of air would spell the end for any antiparticle, and there must be some way of trapping the antiparticles: not in a conventional container, but using electric and magnetic fields.
ATRAP and ATHENA, ALPHA’s forerunner, did successfully isolate antihydrogen in 2002, bringing together antiprotons from a particle accelerator and positrons from a sodium radioactive source in a magnetic trap. Unfortunately, such success is fleeting: magnetic traps work just fine for charged particles such as antiprotons and positrons, but antihydrogen is neutral, so it can slip right through the containing field lines.
It’s a problem ATRAP and ALPHA are still working on. "Capturing antihydrogen atoms is the current frontier, and it’s a challenge," says Rolf Landua, a physicist at CERN who advised on the Angels and Demons movie and is rumoured to be the inspiration for Leonardo Vetra, an antimatter scientist in the original story. "So far nobody has managed to do it, but I’m pretty sure we will." Still, encasing a smouldering chunk of antimatter in a portable antihydrogen trap as happens in the book is a quite a way off, he says.
Does antimatter fall up?
Gravity, we think, works the same way on all matter. But what about antimatter?
AEGIS, a CERN experiment that has just been given the go-ahead, is designed to find out. Gravity is a relatively weak force, so the experiment will use uncharged particles to prevent electromagnetic forces drowning out gravitational effects. It will first build highly unstable pairings of electrons and positrons, known as positronium, then excite then with lasers to prevent them annihilating too quickly. Clouds of antiprotons will rip these pairs apart, stealing their positrons to create neutral antihydrogen atoms.
Pulses of these anti-atoms shot horizontally through two grids of slits will create a fine pattern of impact and shadow on a detector screen. By measuring how the position of this pattern is displaced, the strength – and direction – of the gravitational force on antimatter can be measured.
It’s a clever idea, but the devil is in the detail, says AEGIS spokesman Michael Doser. "No one has ever made controlled positronium like this, nobody has ever made a positronium excited state with lasers in an environment like this and nobody has ever made an antihydrogen pulse like this."
If the researchers succeed, it will be well worth the effort. If gravity does affect antimatter differently, it will tell us something not just about antimatter but also about the fundamental theories that underpin modern physics. Einstein’s general relativity, the currently favoured theory of gravity, tells us that the force should work identically on any type of matter. Equally, the standard model predicts that matter and antimatter are identical to all intents and purposes. "If we find that either of these things differ," says Landua, "then we have found something extremely important."
Doser is hedging his bets. "I’ll wager a crate of champagne that we won’t see a difference," he says. "But I’d gladly lose that crate."
Can we make an anti-world?
At the moment physicists are having enough difficulty just taming antihydrogen, the simplest possible anti-atom. Can we ever expect them to make antihelium, and then organic antimolecules made from anticarbon and a whole anti-periodic table, too?
The problem here is that every anti-atom has to be built one subatomic antiparticle at a time. For example, if you want to make antideuterium – like antihydrogen, but with an added antineutron – you first have to make the antineutron. Antineutrons are neutral, making them impossible to steer in the conventional way with electromagnetic fields, so you just have to make great numbers of them and hope that for every million or so antineutrons you make, one ends up in the right place to make an antideuterium atom. "And for every further antineutron or antiproton you add, you lose another factor of a million," says Doser.
While no one’s cracked that problem yet, one experiment at CERN is making use of a neat short cut to at least make something other than antihydrogen. ASACUSA has created atoms of "antiprotonic helium", in which one of the electrons orbiting a helium nucleus is replaced by an antiproton. By studying the light spectra emitted by this composite matter-antimatter atom, the electrical and magnetic properties of the antiproton can be measured with great precision – and compared with those of a regular proton.
As for our chances of making anything more complex, Close is pessimistic, saying it will take a billion years, give or take. "It depends on how long the human race lasts," he says. It seems that our best bet for spying more exotic elements of the anti-periodic table is to look up at the sky – and hope that somewhere antistars are busy churning them out for us.
What about antimatter bombs?
The idea that humanity might one day harness the annihilative power of antimatter for destructive purposes has a ghastly fascination – and it’s a central part of the Angels and Demons plot, in which a bomb containing just a quarter of a gram of antimatter threatens to obliterate the Vatican.
Relax, says Landua. There’s a very good reason why nothing like that is going to happen any time soon. "If you add up all the antimatter we have made in more than 30 years of antimatter physics here at CERN, and if you were very generous, you might get 10 billionths of a gram," he says. "Even if that exploded on your fingertip it would be no more dangerous than lighting a match." Patients undergoing PET scans have natural radioactive atoms in their bloodstreams emitting tens of millions, if not more, positrons to no ill effect.
Even if physicists could make enough antimatter to build a viable bomb, the cost would be astronomical. "A gram might cost a million billion dollars," says Landua. "That’s probably more than Barack Obama wants to invest right now." Close points out the time problem, too. "It would take us 10 billion years to assemble enough anti-stuff to make the bomb Dan Brown talks about," he says.
If that seems reassuring, unfortunately the same kind of reasoning does for antimatter as a clean, green energy source. "Maybe it would work if there were lumps of antimatter that nature had spent 15 billion years making for us," says Close. As it is, we would have to make them one anti-atom at a time, which costs far more energy to make it than we would get out of it – about a billion times more, says Landua.
That’s not to say we can’t harness antimatter in new ways. In 2007, physicists David Cassidy and Allen Mills of the University of California, Riverside, made the first molecules comprised of more than one positronium atom. Positronium atoms quickly annihilate into high-energy gamma rays, so pack lots of them together, and it should be possibly to get them annihilating and emitting light in synchrony – creating an enormously high-powered "gamma-ray annihilation laser" that could be used to image objects as small as atomic nuclei, or to set off nuclear fusion in reactors.
Bibliography
- Antimatter by Frank Close (Oxford University Press, 2009)
Antimatter: A Briefing
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Every particle has an antiparticle with the same mass but the opposite electric charge. The proton has the negatively charged antiproton; the electron has the positively charged anti-electron, or positron.
Neutral particles can have antiparticles, too. The neutron might have no charge, but quarks – the smaller particles that make it up – do. Turn these quarks into antiquarks by flipping their charges, and you’ve made an antineutron.
The possibility of antimatter first surfaced in equations formulated by British theoretical physicist Paul Dirac in 1928 – four years before American experimenter Carl Anderson found positrons in cosmic rays.
Notoriously, matter and antimatter destroy each other, or annihilate, whenever they come into contact. An electron and a positron mutually destruct in a puff of light consisting of two photons sent out in precisely opposite directions, each with an energy corresponding exactly to the mass of the electron (and positron).
Aliens have arrived!
Mysterious red cells might be aliens
By Jebediah Reed
Popular Science
Friday, June 2, 2006; Posted: 12:36 p.m. EDT (16:36 GMT)
Scientists have yet to identify these unusual red particles.
Manage Alerts What Is This? (PopSci.com) — As bizarre as it may seem, the sample jars brimming with cloudy, reddish rainwater in Godfrey Louis’s laboratory in southern India may hold, well, aliens.
In April, Louis, a solid-state physicist at Mahatma Gandhi University, published a paper in the prestigious peer-reviewed journal Astrophysics and Space Science in which he hypothesizes that the samples — water taken from the mysterious blood-colored showers that fell sporadically across Louis’s home state of Kerala in the summer of 2001 — contain microbes from outer space.
Specifically, Louis has isolated strange, thick-walled, red-tinted cell-like structures about 10 microns in size. Stranger still, dozens of his experiments suggest that the particles may lack DNA yet still reproduce plentifully, even in water superheated to nearly 600 degrees Fahrenheit . (The known upper limit for life in water is about 250 degrees Fahrenheit .)
So how to explain them? Louis speculates that the particles could be extraterrestrial bacteria adapted to the harsh conditions of space and that the microbes hitched a ride on a comet or meteorite that later broke apart in the upper atmosphere and mixed with rain clouds above India.
If his theory proves correct, the cells would be the first confirmed evidence of alien life and, as such, could yield tantalizing new clues to the origins of life on Earth.
Last winter, Louis sent some of his samples to astronomer Chandra Wickramasinghe and his colleagues at Cardiff University in Wales, who are now attempting to replicate his experiments; Wickramasinghe expects to publish his initial findings later this year.
Meanwhile, more down-to-earth theories abound. One Indian government investigation conducted in 2001 lays blame for what some have called the “blood rains” on algae.
Other theories have implicated fungal spores, red dust swept up from the Arabian peninsula, even a fine mist of blood cells produced by a meteor striking a high-flying flock of bats.
Louis and his colleagues dismiss all these theories, pointing to the fact that both algae and fungus possess DNA and that blood cells have thin walls and die quickly when exposed to water and air.
More important, they argue, blood cells don’t replicate. “We’ve already got some stunning pictures — transmission electron micrographs — of these cells sliced in the middle,” Wickramasinghe says. “We see them budding, with little daughter cells inside the big cells.”
Louis’s theory holds special appeal for Wickramasinghe. A quarter of a century ago, he co-authored the modern theory of panspermia, which posits that bacteria-riddled space rocks seeded life on Earth.
“If it’s true that life was introduced by comets four billion years ago,” the astronomer says, “one would expect that microorganisms are still injected into our environment from time to time. This could be one of those events.”
The next significant step, explains University of Sheffield microbiologist Milton Wainwright, who is part of another British team now studying Louis’s samples, is to confirm whether the cells truly lack DNA. So far, one preliminary DNA test has come back positive.
“Life as we know it must contain DNA, or it’s not life,” he says. “But even if this organism proves to be an anomaly, the absence of DNA wouldn’t necessarily mean it’s extraterrestrial.”
Louis and Wickramasinghe are planning further experiments to test the cells for specific carbon isotopes. If the results fall outside the norms for life on Earth, it would be powerful new evidence for Louis’s idea, of which even Louis himself remains skeptical.
