Anti-Matter Created By Laser At Livermore

zootropole alerts us to a press release issued today by Lawrence Livermore National Laboratory, announcing the production of 'billions of particles of anti-matter.' "Take a gold sample the size of the head of a push pin, shoot a laser through it, and suddenly more than 100 billion particles of anti-matter appear. The anti-matter, also known as positrons, shoots out of the target in a cone-shaped plasma 'jet.' This new ability to create a large number of positrons in a small laboratory opens the door to several fresh avenues of anti-matter research, including an understanding of the physics underlying various astrophysical phenomena such as black holes and gamma ray bursts." The press release doesn't characterize the laser used in this experiment, but it may have been this one.

Hey!

[Robin47]

Watch where you point that thing!

Re:Hey!

[MarkRose]

Don't lase me, bro!

Re:

[Iamthecheese]

Anti-matter particle beam... AMPB..nah.. Beam of Antimatter Particles! thats it! BAP

Quick question for anyone with the knowledge

[Hojima]

Does anyone know if this might someday lead to antimatter plants? From a special on discovery, I heard that antimatter has a 100% mass to energy conversion, and uranium/plutonium is very expensive to enrich, so using gold for energy wouldn't be too impractical. This would be very exciting research if it does mean cheap energy at that scale with no pollution.

Re:Quick question for anyone with the knowledge

[nebaz]

No. While antimatter may have a 100% mass to energy conversion, it takes more energy to create it than it gives off.

Re:

[Pr0xY]

I don't necessarily think you are wrong here, but I have a doubt. The reason why is that you wouldn't necessarily be "gaining" energy if you got more out than you put in, because you are simply releasing the energy of the destroyed mass.

As long as the energy required to create the positrons is less than MC^2 (and I would imagine it would be) since anti-matter/matter has a approximate 100% mass to energy conversion, then there should be a net "gain".

Once again, I don't there energy is being "created" here, b

Re:Quick question for anyone with the knowledge

[hvm2hvm]

They created billions of positrons with a high power laser. The antimass(?) of a positron is the mass of an electron or 9.1E-31. Let's round it up and say we have 1E+12 positrons. Combine them with 1E+12 electrons, you get
9.1E-31*2E+12*(3E+8)^2=0.018 J.

Now I'm guessing the laser used is pretty powerful and that it consumes a lot of energy. If we take the specs of the laser linked in the summary, then it used 150J on one pulse which is not the true amount of energy they put into the device (it says it takes 30minutes between pulses at full power). The energy used is thousands or millions of times greater than the energy gained.

Of course, lasers might not be the most energy efficient way of creating antimatter but that doesn't change the fact that if you want to turn m matter into antimatter you will need at least 2*mc^2 energy (at least that's my intuitive guess).

Nuclear devices emit huge amount of energy with relatively small energy inputs because the reaction is selfsustaining, something inside the reaction keeps it alive. What you want is something that destabilizes matter and makes it turn into energy by, say, throwing a special particle at neutrons and/or protons. Turning it into antimatter only to collide it with matter afterwards is just a huge waste of energy.

Re:Quick question for anyone with the knowledge

[marcosdumay]

"The antimass(?) of a positron..."

Anti-matter has mass, ordinary mass, just like matter.

Re:Quick question for anyone with the knowledge

[sdpuppy]

Yes, this experiment accomplished - converting energy into antimatter

The point is having the ability to produce lots of these particles in a directed manner, capture and store them for further study.

Previously the main source for antimatter was certain types of radioactive decay and nuclear reactions.

(example: if you go to the hospital for PET imaging - they inject you with radioactive material that decays by emitting anti-electrons = positrons)

If you want something that could potentially produce energy, this is not it - although in studying the process and the particles we might eventually learn how to produce antimatter more efficiently (to store energy) or perhaps even with net gain by inducing some sort of nuclear reaction.

Re:

[Gromius]

You produce anti-matter in anti-matter-matter pairs. Ergo your idea can not work.

I spent a while thinking if you could exploit the W boson which produces anti-matter - matter pairs of different flavour but I couldnt think of a way. Regardless any way which somebody could come up with would give such a small theoretical energy gain that you would almost certainly lose it through efficiency loses.

Re:Quick question for anyone with the knowledge

[Deadplant]

You need to channel the matter and anti-matter streams through dilithium crystals.

I think you need to use anti-hydrogen though, not just anti-electrons.

Re:Quick question for anyone with the knowledge

[severoon]

Wow...reading this thread makes me a bit sad, and I can only hope that all the participants in this conversation up to now were not exclusively schooled in the US. (Sadly, I suspect it is so.)

Physics is the study of manifestations and transformations of energy. One of the basic laws of physics is that energy is conserved. If you pump so many GeV of energy in the form of coherent radiation into gold atoms, it seems from this article that some fraction of that energy is converted into positrons. When those positrons collide with electrons in equal numbers (as they're sure to do in this universe given even a very short period of time), the matter-antimatter pair annihilate each other and mass is converted back to radiation energy.

The amount of energy released in this annihilation is equal to the amount used to create the positrons in the first place, which is necessarily less than the energy of the laser light incident on the gold atoms. Some of that incident light is going to be lost knocking electrons off, knocking gold atoms out, heating the gold, getting absorbed and re-emitted as a different frequency of light, etc. We've only been looking at the actual point of energy transformation, too...if we go even further back in the chain, we have to look into the efficiency of the laser itself. Certainly less than 100% of the energy consumed by the device is emitted as a coherent light beam even before we look at how this beam is interacting with the gold.

So, by definition, antimatter cannot be a first energy source in this universe. Antimatter could be useful as a means of storing a large amount of energy, but not as an ultimate source. (Unless we find a naturally occurring, ready source of antimatter that we can harvest, which would probably require a wormhole to an alternate universe and a means of controlling that wormhole. Uh oh, queue up the Star Trek / Stargate SG-1 nerds...)

Re:

[KasperMeerts]

Sorry,the energy you get from the antimatter, if you can collect every single bit, it still even lower than the energy needed to fire the laser. That's conservation of energy for ya.

Re:Quick question for anyone with the knowledge

[CroDragn]

You can't generate a net positive energy source with antimatter. Best you can hope for is to use the antimatter as a form of energy storage (think battery, fuel, etc). Of course, storage problems make it impractical for nearly every use, so don't expect anti-matter cars... ever. Space travel, however, would greatly benefit from a decent means of generating antimatter, since fuel mass trumps most other concerns in that field and anti-matter provides the most thrust/mass of any theoretical substance.

Re:Quick question for anyone with the knowledge

[ultranova]

You can't generate a net positive energy source with antimatter.

Make hydrogen containers with very thin gold walls - or more likely frozen pellets coated with gold. Bombard the gold with a laser, turning the surface layer into antimatter. Antimatter annihilates with the matter below it and creates an explosion, which heats and compresses the hydrogen, igniting a fusion reaction.

It is, essentially, the equivalent of a fission-initiated fusion, which is proven to work and work well. The difference is that there's no lower bound to the size of an antimatter explosion - even a single electron and positron annihilate - so you can make the explosion be of suitable size for a power plant. And of course annihilation, as the name implies, doesn't leave behind radioactive materials, just gamma rays.

Besides, Laser Antimatter Fusion is pretty much the epitome of cool ;).

Re:

[rubycodez]

inertial confinement fusion with deuterium pellets surrounded by gold has already been done, but antimatter isn't a significant part of the fusion process. Even in this article, the amount of antimatter produced is miniscule

Re:

[Corporate Troll]

Where? In some natural magnetic field? Even, then... how are you going to extract it?

Re:Quick question for anyone with the knowledge

[Elladan]

I heard on TV that an omnipotent sky monkey plans to torture us all in a volcano forever because some woman made out of a guy's rib ate a snack with a talking snake.

And that was supposed to be an education show!

Re:

[kaizokuace]

One step closer to developing the matter/anti-matter reactor. Star Trek will become reality!

Not enough anti-sunlight

[Anonymous Coward]

> Does anyone know if this might someday lead to antimatter plants?

Nah, there isn't enough anti-sunlight for them to grow....

Holy Mackerel!

[AKAImBatman]

Does anyone know how much energy this takes? They mentioned the previous petawatt laser experiment that was decommissioned, but I didn't see where it mentioend the power required for this experiment. If the laser guess by kdawson is correct, we could be looking at a mere 400 joules per 1E11 positrons. Which (if I'm not mistaken) would be an unheard of efficiency for creating antimatter! (Can someone verify? My brain is fried at the moment.)

What I find interesting is that this level of production is competitive with Fermilab [fnal.gov]. Even if they ran this twice an hour, they'd handily meet or outstrip Fermilab production.

Even more interesting is the possibility for mass manufacture of antimatter. By using mass-produced gold targets, you could rotate the materials in and out of the machine every few seconds, creating previously unseen amounts of antimatter. Such a process could easily provide materials for an antimatter catalyzed fission drive [wikipedia.org]. Possibly even enough to power new forms of interplanetary propulsion.

Am I the only one who's getting really excited about this? /dreamer

Re:Holy Mackerel!

[theheadlessrabbit]

...Such a process could easily provide materials for an antimatter catalyzed fission drive. Possibly even enough to power new forms of interplanetary propulsion...

Am I the only one who's getting really excited about this?

probably. they still haven't been able to crystallize di-lithium yet.

Re:Holy Mackerel!

[Kagura]

Does anyone know how much energy this takes? They mentioned the previous petawatt laser experiment that was decommissioned, but I didn't see where it mentioend the power required for this experiment.

The great thing about this for spaceflight isn't that it takes a lot or a little to produce antimatter, but rather that the density of usable energy is orders upon orders of magnitude greater than chemical or electric rockets. Denser energy leads to more fuel carried leads to greater delta v leads to semi-relativist flight leads to hate leads to suffering. These can even be used within the atmosphere to launch rockets from the ground easier than you can say "prompt gamma ray output".

Re:Holy Mackerel!

[FlyByPC]

Even more interesting is the possibility for mass manufacture of antimatter. By using mass-produced gold targets, you could rotate the materials in and out of the machine every few seconds, creating previously unseen amounts of antimatter.

If true, this is the 1940s all over again -- only on a larger scale. A thimbleful of antimatter would make any H-bomb look like a popgun. (...and yeah, I know we're not yet talking about anywhere near that order of magnitude. Yet.) It would certainly help with space exploration -- but we humans can't even be completely trusted with gunpowder and jet airplanes yet. *sigh*

Re:Holy Mackerel!

[AKAImBatman]

If true, this is the 1940s all over again -- only on a larger scale

Not really. We've already done the whole Cold War/Mutually Assured Destruction thing. Our weapons are already far, far larger than we could ever deploy here on Earth. Making them that much bigger only makes them that much more useless. At best, the only real advantage would be that they could be scaled down.

Until we start looking at warfare on an interplanetary or interstellar scale, our existing nukes and possible antimatter warheads are going to sit in their silos and go unused. Or in the case of antimatter bombs, I simply hope they're not built. The idea of a large-scale antimatter warhead being prevented from detonation by mere magnetic fields maintained by the nearest power plant is not an appealing idea. Just disrupt the power infrastructure for long enough and we'll blow ourselves to kingdom come. :-/

Re:

[Boronx]

Until we start looking at warfare on an interplanetary or interstellar scale, our existing nukes and possible antimatter warheads are going to sit in their silos and go unused.

Nukes have already been used, and do to dangerous attitudes like yours, which seem to proliferate as more time passes since the last use, they are likely to be used again.

Re:Holy Mackerel!

[AKAImBatman]

Nukes have already been used

Yeah, once. (Twice if you want to be pedantic.) Then never again. The whole point was that the display of force showed that the weapons were too dangerous to use. As long as the various sides have them pointed at each other, no one dares use them.

The only reason why the Cold War was so terrible was that the USA and the USSR were both waiting for the other to attack. Since neither one liked each other much (for both idealogical and practical reasons) the chance that an armed conflict would happen between the two powers was pretty darn high. Except that an armed conflict might precipitate into a nuclear war should either side feel backed into a corner.

Thus the reason why the US didn't win Vietnam. The chance of starting a nuclear war was too great to risk pressing the war to a conclusion. Which raised the (very legitimate) question of why we were even in the conflict to begin with.

Re:

[Boronx]

The only reason why the Cold War was so terrible was that the USA and the USSR were both waiting for the other to attack. Since neither one liked each other much (for both idealogical and practical reasons) the chance that an armed conflict would happen between the two powers was pretty darn high. Except that an armed conflict might precipitate into a nuclear war should either side feel backed into a corner.

You are misinformed about how close and how often the US and USSR came to nuclear exchange, and at th

Re:Holy Mackerel!

[Whiteox]

It wasn't a war, it was a police action.

Re:

[skavenger]

Pedantic? Really?

To say nukes were only used once or twice is terribly misleading. Nukes were only used in a military capacity twice. Even more accurately, they were only used in a military capacity against strategic targets twice. They've been used for political posturing and military advancement approximately 2,000 times [wikipedia.org] in various settings and with varied payloads.

This isn't intended to devalue the magnitude of the decision to effectively annihilate large numbers of human populations or suggest th

Re:

[NatasRevol]

Twice?

For the record, we've dropped nuclear bombs on four countries.

Japan, Spain, US, Greenland.

Not all of them were on purpose, but that doesn't mean they weren't dropped.

http://en.wikipedia.org/wiki/List_of_military_nuclear_accidents [wikipedia.org]

Three of the four countries still have radioactive material on the ground from them. And they just couldn't find it in Greenland.

Re:Holy Mackerel!

[techno-vampire]

Nuclear devices in the megatons have only been deployed and detonated in a theater of openly declared war twice.

If you're referring to Hiroshima and Nagasaki, you're wrong. Both of those devices were in the kilotons, not megatons.

Re:

[AKAImBatman]

We learned an invaluable lesson out of Vietnam. We learned that the Cold War was not going to be won on military might. Which eventually lead to the solution of bankrupting the USSR. (Something which would have eventually happened anyway, just much slower.) The part that hurts is that we learned the lesson at the cost of millions of lives. At that high of a price, we may as well have dropped a nuclear bomb.

Don't get me wrong. I do not have a particular position on the war. In fact, many South Vietnamese are

Re:

[Alex Belits]

Which eventually lead to the solution of bankrupting the USSR. (Something which would have eventually happened anyway, just much slower.)

Or, to be exact, it didn't happen [slashdot.org].

Re:

[EdIII]

it is a representative democracy

LOL!!! ROFL!! I laughed so hard my drink came out my nose!

Representative Democracy? In what possibly way could you misconstrue that? The ruling elite (Elites, Politicians, Corporations, Military Industrial Complex) pass laws ALL THE TIME that no American wants.

The fact that a small percentage of us voted was just the decision being made between a Douche and a Turd Sandwich. Senators and Congressmen create and pass laws and funding measures all the time that only benefit th

Re:

[linzeal]

The US military has already started demanding one [noahshachtman.com]. Which means some other country has a program as well, my bet is Russia. The only peaceful use for such power that I can conceive of would be to restart the core of a planet like Mars to give it a magnetic field.

Re:

[CarpetShark]

Our weapons are already far, far larger than we could ever deploy here on Earth. Making them that much bigger only makes them that much more useless.

One could argue that all wars are worse than useless. Doesn't stop them happening. In fact, the US Air Force has already shown interest in anti-matter weapons:

http://www.sfgate.com/cgi-bin/article.cgi?file=/c/a/2004/10/04/MNGM393GPK1.DTL [sfgate.com]

http://en.wikipedia.org/wiki/Antimatter_weapon [wikipedia.org]

Re:

[Pr0xY]

I believe you are mistaken. Everything I've hear suggests that a teaspoon of the stuff could level a city.

Re:Holy Mackerel!

[zippthorne]

60e6*1e3 kcal / c^2= 2.8 kg [google.com] of antimatter will give any H-bomb look like.. uh.. something that's the same size as an H-bomb. H-bombs have been proposed (and postulated to have been built) that are larger than 60 MT, and a pop-gun typically has only a few Joules, so you'd need many orders of magnitude more than 2 kg of antimatter to make an H-bomb look like a pop-gun. something like.. four times the mass of mount Everest, in antimatter.

Re:Holy Mackerel!

[techno-vampire]

It's even worse than that. During a panel at LACon II, back in '84, Dr. Robert Forward said that according to the best calculations, if you dropped a lump of anti-matter on the floor, it wouldn't vanish in a flash of gamma rays, it would sizzle like a drop of water on a hot griddle. You see, the anti-matter can only interact with its environment and annihilate on its surface, and there's this little thing called the "cube-square law" that says that very little of it is going to be on the surface.

Re:Holy Mackerel!

[Rayban]

What would happen if you aerosolized said cube with a small explosive?

Re:Holy Mackerel!

[techno-vampire]

Good question. I presume that the reaction would be somewhat more energetic, but nobody thought to ask, and he didn't say.

Re:Holy Mackerel!

[Klaus_1250]

(60e6 * 1e3 kcal) / (c^2) = 2.7931967 grams. That is about a factor 1000 less.

The largest H-bomb ever build/detonated, the russian Tsar Bomb, was about 50MT, but capable of 100MT. I never heard of anything larger, but is/was there?

Re:Holy Mackerel!

[Ann Coulter]

It should be (60e6 * 1e3 kcal) / (2*c^2) = 1.39659835 since the normal matter that will also be annihilated will contribute to the mass-energy conversion.

Re:

[khallow]

You're using the wrong calorie. Should be roughly 2.8 kg. Here's the calculation:

1 ton TNT == 4.184*10^9 J
mass equivalent m = 60 megatons TNT/c^2 = 2.5104*10^17 J / (9*10^16 m^2/s^2) ~ 2.8 kg.

It's commonly misunderstood just how much mass in a nuclear bomb is converted to energy.

Re:

[Thanshin]

Indeed, the manufacture of antimatter bombs would most certainly accelerate space exploration.

Re:

[shma]

If true, this is the 1940s all over again -- only on a larger scale.

Calm down. The energy released by annihilating 100 billion positrons doesn't even come to 10 millijoules. Let me put it another way. According to Wikipedia, 0.6 g of matter was transformed into energy in the first uranium bomb explosion. This amount of anti-matter weighs 10^-16 g. That's 16 orders of magnitude less energy released. On top of that, there's no way to contain antimatter for long periods of time, so there's no way to gather enough anti-matter to make a bomb. But even if that technology were dis

Re:

[Pr0xY]

except that anti-matter/matter collisions have a FAR more efficient conversion to energy so you need much less of it.

Re:Holy Mackerel!

[magarity]

Possibly even enough to power new forms of interplanetary propulsion
 
Yeah, because NASA (and similar agencies around the world) have whopping piles of cash laying around for this.
 
Reporter: What's it like to fly the new spaceship?
Pilot: Like burning a load of gold as fast as I can!
 
Yeah, and you think the class warfare rhetoric between the rich and poor nations is bad now?!?

Re:Holy Mackerel!

[AKAImBatman]

Yeah, because NASA (and similar agencies around the world) have whopping piles of cash laying around for this.

Yeah, research dollars would never fund anything like that. Except when they [wikipedia.org] do [wikipedia.org].

Is it really so hard to click through the links? :-/

FWIW, there are quite a few antimatter engines on the drawing board. They're only missing one key component: Antimatter. And this new technology may be the key to providing it in spades. (Relatively speaking, of course.)

Re:

[frieko]

Bah!! We can't trust NASA to burn our gold, there's special agencies [theonion.com] for dealing with this sorta thing!

Re:Holy Mackerel!

[Joe The Dragon]

Just use a zpm to power it.

Re:

[Quantum Jim]

I don't think this compares with Fermilab. The fine article is talking about creating positrons, not anti-protons. This isn't the first time I've heard about creating positrons from a laser shown upon a gold foil target. Here are two (from 2004 and 2001 respectively) that I just found on Google Scholar describing a result and a theory behind the positron production:

http://llacolen.ciencias.uchile.cl/~vmunoz/download/papers/wclpp05.pdf [uchile.cl]
http://www-project.slac.stanford.edu/lc/local/PolarizedPositrons/doc/Class [stanford.edu]

Re:

[AKAImBatman]

Thank you sir, you are my hero. (Even if you did just burst my balloon. :-P) Now I'm off to get some rest. By morning all the math should make sense again and I'm sure I'll be kicking myself with a "why didn't I see that?"

Thanks again! It really is appreciated. :-)

Re:Holy Mackerel!

[AKAImBatman]

Why is everyone so hung up on an energy-positive reaction? Antimatter is the ultimate in fuel for space-propulsion as it produces the highest theoretical amount of energy for the least possible mass. (i.e. 100% conversion - losses to nuetrinos that cannot be captured) This plays well into the rocket formula, giving antimatter drives a specific impulse unattainable with other rocket methodologies. In fact, the far-flung future may see c-ships [fourmilab.ch] traveling the stars based on matter-antimatter drives.

What I want verified is not if this process is energy efficient or not. I want to know if this process is several orders of magnitude more efficient than the current Fermilab and CERN processes.

Sure, you could use the antimatter to fuel some other reaction as you suggested, but then again we already have fission reactors which produce net positive energy.

Once again, antimatter catalyzation makes the fuel more efficient for its weight and thus plays well into the rocket formula.

Re:

[Kagura]

There's nothing wrong with your post--I'm just pointing out that it's still not close [wikipedia.org] to 100% conversion:

Not all of that energy can be utilized by any realistic technology, because as much as 50% of energy produced in reactions between nucleons and antinucleons is carried away by neutrinos, so, for all intents and purposes, it can be considered lost.

Re:

[AKAImBatman]

That would probably be why I said, "i.e. 100% conversion - losses to nuetrinos that cannot be captured". Apologies for mixing in the minus sign rather than spelling it out. As I mentioned previously, it's late and my frain is bried. ;-)

Re:

[Kagura]

Well, in my mind 50% loss is quite a lot, but I said there's really nothing fundamentally wrong with your post. Just thought it was an interesting enough fact. ;)

Re:

[lysergic.acid]

that's a pretty interesting concept. it seems very far-fetched, but they've obviously put a lot of thought into the technical and logistical problems such a ship would face. here's an excerpt of my favorite part:

Shield
Our ship is icy-white in colour for the very excellent reason that its exterior is made of water ice, one of the most abundant substances in the universe. When we travel at extreme velocities, dust particles impact our ship with the energy of a nuclear bomb, and even hydrogen atoms erode her

Re:Holy Mackerel!

[JohnFluxx]

I did the calculations for an earlier post:

If you accelerate at 9.8m/s^2 for half the journey and -9.8m/s^2 for the second half of the journey (so that it's just like earth's gravity) then you would arrive at the planet after:

1.94 arccosh(n/1.94 + 1) years

For n=10.5 light years, this gives 4.9 years.

For other values of distance:
4.3 ly nearest star 3.6 years
27 ly Vega 6.6 years
30,000 ly Center of our galaxy 20 years
2,000,000 ly Andromeda galaxy 28 years

(For distances bigger than about a thousand million light years, the formulas given here is inadequate because the universe is expanding. General Relativity would have to be used to work out those cases.)

So for someone in the rocket, they could arrive at the planet in 4.9 years.

If you had an 100% efficient engine (using anti-matter/matter), the fuel required would be:

d Stopping at: M
4.3 ly Nearest star 38 kg
27 ly Vega 886 kg
30,000 ly Center of our galaxy 955,000 tonnes
2,000,000 ly Andromeda galaxy 4.2 thousand million tonnes

I find it fascinating that within a human lifetime (for the people in the rocket) we could travel to another galaxy.

(I'm a theoretical particle physicist)

Re:

[clonan]

Umm, all the time frames were quoted as from the point of view of the guy on the rocket.

He never said the rocket was traveling faster than light.

Re:Holy Mackerel!

[JohnFluxx]

> you didn't account at all for relativistic effects at all.

It fully takes into account SR effects.

> A big question is how come you can travel faster than light
It doesn't. All times as for the people in the spaceship, as I stated. The reason it takes less time is because of time dilation.

> when you get to Vega everyone who sent you will be long dead.
Indeed.

Re:Holy Mackerel!

[JohnFluxx]

Time dilation and distance contraction. This are special relativity effects.

For the people on earth, the ship takes 4 million years to travel 4 million light years at close to the speed of light. But for people in the rocket, it can be a very short amount of time.

Re:

[JohnFluxx]

> You left out where the energy to sustain 1 gee is going to come from

I gave the calculations for the energy/mass required to sustain 1g.

> Also with \gamma>>50 the blue shifted microwave background is not looking so nice.....

Shields :-)

Re:

[ravenshrike]

Bzzt, wrong. Converting M into AM takes a certain amount of energy which may or may not be(probably is) less than the energy released by a M/AM annihilation event.

doh!

[Digitus1337]

Take a gold sample the size of the head of a push pin, shoot a laser through it, and suddenly more than 100 billion particles of anti-matter appear.

It's so simple, I wish I'd thought of it!

Re:

[gaspyy]

Take a gold sample the size of the head of a push pin, shoot a laser through it, and suddenly more than 100 billion particles of anti-matter appear.

It's so simple, I wish I'd thought of it!

Don't worry, someone probably already has a patent on it.

Lasers

[Chuck Chunder]

Is there anything they can't do?

Re:Lasers

[superdave80]

It's even more amazing when you consider that when lasers were first developed, no one thought they would have much practical use. They were "A solution looking for a problem."
http://www.press.uchicago.edu/Misc/Chicago/284158_townes.html [uchicago.edu]

Now, try to imagine modern technology without lasers...

Re:

[syousef]

Is there anything they can't do?

Yes, there is! That is what the sharks are for!

Mod parent up

[shrikel]

Yeah. Now just imagine a nanotube laser! That's probably what modified photon torpedos are made out of.

Hot plasma jets!

[Dutchmaan]

The anti-matter, also known as positrons, shoots out of the target in a cone-shaped plasma 'jet.'

Apparently, it seems I can create anti-matter from eating too much TacoBell.

All or Nothing

[Jheralack]

I always wondered if they could assemble enough anti-matter to perform a Cavendish experiment if it would prove to be repulsive to regular matter gravitationally. I know the current theory doesn't call for it, but hey, that's why we do the experiments. Very symmetrical (in comparison to the electrostatic force equation), and very cool, if it turned out to be true. On the other hand, somebody should stop these fools now. The next thing they will want to do is bottle the stuff, and regular nukes would be

Re:

[maugle]

Oh, that's a fun thought. On the other hand, I don't really see anyone trying to build an antimatter bomb any time soon, since just keeping one on hand would be incredibly risky:

Something goes wrong storing a nuke: Area sealed off, that particular spot possibly radioactive
Something goes wrong storing an antimatter bomb: Area vaporized, that particular spot the center of a city-sized crater

Wow PET scans anyone?

[Billy the Mountain]

This may open the possibility of cheaper PET scans. Currently, the limitation of PET scans is the answer to this question: "How far away is the nearest Cyclotron?" The half life of the radioactive material used in Positron Emission Tomography, typically Flourine-18, is ~110 minutes. With a laser that can generate positrons, you could have a mobile PET scan unit that would only need to rely on being able to connect to the grid.

BTM

Re:

[Atlantis-Rising]

I believe, although I am certainly no expert, that hospitals and places that do PET scans do not take delivery of the radioactive materials with such short half-lives directly; they keep on hand material that will decay into the materials they need, which allows them to keep it on hand for longer.

Re:

[krysith]

No, I don't think so. F-18 is usually used as part of FDG (Flourodeoxyglucose), a biologically active molecule, so that the positrons are emitted from where glucose is consumed. Having random positrons flying throughout your body won't make for a very effective PET scan.

Also, wouldn't it be more effective to just use Ga-68 if you are far from a cyclotron? It has a 68 minute half-life and is produced from Ge-68 generators, which have a 271 day half-life. I have a NIST traceable sample of Ge-68/Ga-68 in eq

interesting implications

[erbbysam]

From what I can gather from the comments and the article, this could become a stable fissionable reaction which would, hypothetically(assuming you can build up and store this stuff) produce an almost unlimited amount of energy? or is the gold(if there are no alternatives)/energy consumptions be too great?

Wow!

[Profane MuthaFucka]

I am hoping that they can produce enough anti-matter to make a weapon of some kind. An anti-matter bomb would be many many thousands of times more powerful than even a hydrogen bomb, and it gives me great hope to think that a bomb that huge would make America even safer than thousands of nuclear warheads already make it.

Oh wait, that was just me getting into touch with my inner-Teller.

Re:

[ravenshrike]

No, an AM bomb would be much more efficient than a thermonuclear device, which is currently the most efficient energy generation system available.

Where's the boom?

[TheBlunderbuss]

Where are the anti matter particles now?
I would think they're touching matter, since they didn't just harmlessly disappear.

Isn't there supposed to be an enormous explosion when matter and anti-matter meet?
Or is that fiction? or friction? Or fission? Or fusion? or confusion?

Re:

[Boronx]

You just missed it.

Re:

[SanityInAnarchy]

My understanding is, they probably did harmlessly disappear -- matter/antimatter annihilation turns matter directly into photons. Intuitively, I assumed a positron and an electron will turn into two photons -- Wikipedia confirms that this is what usually happens, though there can be more.

So, billions of particles means probably billions of photons.

Now, Google the number of photons put out by a simple 100-watt light bulb...

The point is, well, look at how many atoms are in a thimble -- and each of those atoms

Re:Where's the boom?

[compro01]

You are fantastically overestimating how much they made. 100 billion particles seems like a lot, but it's actually only about 9.1x10^-17 grams (91 attograms). You could likely be physically standing right in front of the thing, in the middle of the spray of particles, and not notice anything.

Its time

[gmuslera]

Intel should use those lasers to start to make processors that use positrons instead of electrons. Robots based on those positronic "brains" will have a big potential, and could last eons.

Re:

[FooAtWFU]

That sounds dangerous. I, for one, am not willing to welcome our new robotic overlords! (Or regular human overlords with robot armies). Intel would need to come up with a scheme to keep the robots from harming people. Some sort of set of axioms... rules... laws, even... that would apply to all the robots they made, in order to keep them in line. Otherwise it would never work.

iDebt

[Tablizer]

Shoot a laser at the 700b bailout money, and see if a surplus appears.
       

"Great Heavens! That's a laser!"

[Antique Geekmeister]

"Yes, Dr. Scott. A laser capable of emitting a beam of pure anti-matter." It looks like we can no longer shout back 'Then it's not a laser!' Yes, some of us are old enough to remember going to the Rocky Horror Picture Show before it was a cult classic.

Alien Spacecraft Use Element 115 instead of Gold

[Junior Samples]

According to Robert Lazar, former Area 51 physicist, element 115 is used as fuel generating antimatter in an Annihilation Reactor which powers the craft. http://www.boblazar.com/closed/index.html [boblazar.com]

Details of Annihilation Reactor operation are here: http://www.boblazar.com/closed/reactor.htm [boblazar.com]

Re:

[Xiroth]

No. We will not be able to get energy out of this than it costs to generate the anti-matter. With regards to energy, at best this will be a energy storage device. However, its unique nature may prove useful for various future applications - now that this sort of potential is available, people will start to think about how to use it.

Science Journalism Critique FAIL

[Anonymous Coward]

Either that, or he/she just isn't a good writer -- that statement implies that all positrons are anti-matter and all anti-matter is positrons. Only the first statement is true.

Nice try, but not true. Your argument would be correct if the statement had read "Anti-matter, also know as positrons...", but it does not. Rather the author says "The antimiater, also known as positrons...".

This sentence only refers to the antimatter created during this experiment. And, near as I can tell, positrons are indeed the only form of antimatter produced in the experiment.

The lesson here - don't post smug messages denouncing someones incorrect grammar when their grammar is in fact correct. Check your facts.

Re:

[pavon]

that statement implies that all positrons are anti-matter and all anti-matter is positrons.

Okay, I guess I don't understand anti-matter as well as I thought I did, and reading the link didn't help. So, I'll ask - why is the first half of that statement not true?

Re:

[Valacosa]

I never took particle, so I can't go into the same depth as some of my friends could. But basically, there's this whole zoo of particles most of which you've heard of. Electrons, protons, etc. Most* of these particles have a corresponding antiparticle. The proton has the antiproton. The neutron has the antineutron. And the electron has the positron. If it helps, you can think of it as the "mirror universe" of the particle zoo -- the antiproton is a proton with an evil streak and a goatee.

Matter is made u

Re:

[DMUTPeregrine]

The first half is true, as he said. And it doesn't imply that all antimatter is positrons, merely that all antimatter created by this process is positrons.

Re:

[kmac06]

As the other poster mentioned, they would repel each other, but that's not really the end of the answer. If they could be brought close enough together (which they certainly could), they still wouldn't annihilate, because of conservation laws. For one, charge would not be conserved (two positive charges would disappear). Lepton number conservation (think number of electrons conserved) and baryon number conservation (think number of protons conserved) would also be violated. It's for these same sort of conse

Re:

[SQLGuru]

I for one welcome our shark overlords with anti-matter rays strapped to their head?

Layne

Re:

[Kagura]

As far as I was aware, one of the major roadblocks to that was the

Nah, after you defeat the Onett Chief of Police, they open up the roadblock down the path that leads to Twoson.

Re:

[compro01]

If the summery is right about what laser they used and the energy use for such (400J), and the count of the particles (~100 billion), and we were able to capture all energy from the annihilation (E=mc^2), we're looking at about 0.004% efficiency.

We're a looooooooooooooong way from having antimatter as a viable energy storage solution.

Re:

[Patrik_AKA_RedX]

I tried that last summer and I can tell you shouldn't do this. My parents still have a hard time believing they lived there for 12 years and never noticed the 500m wide lake behind the house.

Magnetic containment won't work

[Kupfernigk]

You may not have noticed that same-charge particles repel. Otherwise you could create magnetic containment boxes full of ordinary electrons or nuclei. A simple experiment with a school Van Der Graaf generator will quickly show you just how strong that repulsion gets when even a tiny quantity of electrons are persuaded to gather in one place. To get a significant quantity of positrons or anti-protons, you are ideally going to need a large, geologically stable area, some very big metalwork and a huge budget.