I see a number of comments here misunderstanding the power of this laser. Laser facilities like this one are designed for incredibly short pulses that are femtoseconds long, and total energy per pulse is typically on the order of tens of joules, roughly equivalent to a few seconds of your phone flashlight. They can’t destroy much of anything on human scales. They are made to do physics research, and there is absolutely no pathway from a 2 petawatt laser that delivers a few joules a minute to a 2 petawatt laser that hits full output power for a few seconds: that would be 10^16 times more energy, and of course that brief pulse would use more electricity than all the US uses in a year and completely destroy the University of Michigan in spectacular fashion (very roughly equivalent to a five megaton nuclear explosion.)
If you’re interested in the most energy per pulse, you want the “most energetic” laser, which is the NIF at LLNL. That’s about 2 megajoules per pulse or half a kilowatt hour. Definitely enough to kill a mosquito, but it doesn’t even register on the scale of Death Star style lasers from fiction.
And if you want the most destructive power, those are all military lasers. Which can absolutely destroy things science fiction style, but on a fairly small scale and with some important limitations.
Fun fact: these laser pulses are so short they are no longer a single wavelength. They have a spectrum due to the uncertainty principle. And at this short of a time scale, it’s pretty broad.
>And if you want the most destructive power, those are all military lasers. Which can absolutely destroy things science fiction style, but on a fairly small scale and with some important limitations.
Once upon a time we tried developing a nuclear-pumped X-ray laser for use in strategic defense, which if my napkin math is correct was probably in the neighborhood of NIF in terms of energy output (despite the conversion efficiency being terrible). Notable is that NIF continues existing after it fires.
Back in graduate school, I TA'd an electrostatics course. We were going through the details of the basic parallel-plate capacitor, and so Prof. Peter Hagelstein (of the project you listed above) used the example of how much energy was stored in a football-field sized set of parallel-plate capacitors with oil as a high-breakdown dielectric.
The students were dutifully copying the lecture while I was sitting there with my mouth agape realizing that he was working through a simplified example of what energy storage was required for the X-ray laser. IIRC Those guys had their own substation, and would charge the capacitors. The switch would get thrown and the sublasers would shoot at the molybdenum target, which would laze in the X-ray spectrum (and the molybdenum would vaporize, I think.)
Afterwards, I asked him how on earth the energy was transferred from the caps to the sublasers: He just smiled and said "very carefully".
Also NIF is actually 192 laser beams with about 3 football fields of lab grade warehouse to house all those laser beams optics for beam pumping, shaping, etc.
Not sure you can move NIF like you would move excalibur
The article said 2 Petawatts for 25 quintillionths of a second. That's about 50mJ.
That's about the amount of power used in your phone's flash when taking a picture, not a few seconds, but the LED being on for about 50-100 milliseconds.
Not sure if the article is accurate (the accuracy of numbers in written text took a nosedive concurrent with the rise of LLMs), but the capabilities page of the laser’s website claims 23 femtoseconds pulse duration, 2 PW power, 50 J energy, and 1 shot per minute. 50 J is roughly a 3W light for 15 seconds.
> Not sure if the article is accurate (the accuracy of numbers in written text took a nosedive concurrent with the rise of LLMs)
Written text accuracy took a nosedive in the early '00s as newspapers couldn't afford to hire journalists with a scientific background, followed by universities not hiring scientists to write press releases any more. GIGO - garbage in, garbage out.
I understand that you're being silly, but even in this silly theory land how is that supposed to work? While the laser is in a loop it's not hitting anything, and if you let it out it's the same as when you put it in.
I figure it's a matter of stacking/charging the laser in that loop with a lot of pulses, then letting that all out at once? Like, what if we shot pulses into the orbit of a mini black hole, but then managed to unwind it back out into a single direction?
In that case the problem is you're only charging the loop with about 1 watt of laser on average. It's going to take two weeks just to reach a megajoule. So you can do one really cool shot, and then you have to wait months.
Laser facilities like this one are designed for incredibly short pulses that are femtoseconds long
"Look at the facts. Very high power, portable, limited firing time, unlimited range. All you'd need is a big spinning mirror and you could vaporize a human target from space."
I got a tour of the lab during construction. As a software engineer, what I found most incredible about the project was how well they stuck to their delivery proposal and timeline over the course of five years of development.
How's that compare to the peak power output of a bubble collapsing in a liquid, over similar timescales? A genuine question, as I know bubbles pack quite a punch (can cause fusion) but can't find any numbers.
There's a Youtube channel looking for a low cost laser backstop material. They have 10-100?kW class single mode fiber lasers that can burn holes in almost anything Real Genius style. https://youtu.be/n3ssikDQva0
In this very interesting video, a Russian drone developer gives his thoughts about laser weapons. In theory they work, they test it always on ideal atmospheric conditions. In practice, they don't.
To kill a mosquito, you need "a few tens of millijoules, delivered within a few milliseconds" [0], so let's say 10W. To destroy the Earth (so that it turns into scattered dust and never reforms) you need about 10^32 J [1]; if we assume this is applied over maybe 100s, the laser would be 10^30W.
So the log10 scale goes from 1–30, where mosquitos die at 1 and the Earth dies at 30. The 2 PW in the article is about a 15.3. The Vulcan 20-20 project (set to complete in 2029) will register at about 20PW, or a 16.3 on the mosquito-Death Star scale [2].
So on a log scale, we're over halfway to building the Death Star.
I think this is the crux of the assumption right here. It sounds like this is apply for well under a nanosecond.
I think we're closer to maybe killing a mosquito than "half way to building a Death Star on a log scale" (which, I guess is already much closer to a mosquito than a planet).
I’m still not sure what 15.3 on the MDS scale can destroy but I am sure the Emperor will be pleased to hear that we are half-way to building the Death Star.
They used log10, so each step is 10x the previous, so in a linear sense, it would double when going from about 29.7 to 30. But it seems that humans tend to improve tech at exponential rates, where we are constantly making improvements here and there that keep stacking up, when it comes to things that are actually in a developmental stage anyways.
Say your "endstage" goal is GPU with 200 billion transistors. Using linear scale, the current biggest GPU is only halfway there, and it took all of human civilization to get this far, and it will take another civilization to get to 200b. In reality, we'll have that in a couple years with our current civilization.
A hypothetical "death star" project like this would require improvements in energy generation/storage capacity/etc., which haven't improved in nearly the way transistor production has (and are also much more limited by physical realities, such as the specific heat, enthalpy of combustion etc. of materials).
Yes, extremely high sustained power lasers still have a hard time competing with hypersonic projectiles in energy delivered. The difference in being able to throw nuclei at the problem.
Well, mass scales as the cube of radius, and we have 15 orders of magnitude to work with, so I guess it should be an object on the order of hundreds of meters in radius. But as noted, the duration of firing matters as well. Given https://news.ycombinator.com/item?id=44054239, the actual laser can only vaporize much smaller things.
> Optical devices called diffraction gratings stretch it out in time so that when the pump lasers dump power into the pulse, it doesn’t get so intense that it starts tearing the air apart.
Oh,my.
> "The crystal that we’re going to get in the summer will get us to 3 petawatts, and it took four and a half years to manufacture"
This entire thing is beyond cool. I hope the rest of the process goes smoothly for the teams involved!
I was hoping I could hear it make noise but it operates for millionths of nanoseconds. Human ears have trouble with anything less than 30 ms so when it runs a trillion times longer we’ll be able to hear it make a sound.
Big powerful lasers can actually be quite noisy. Once I was talking on the phone with a friend who was working on one of the big lasers (don't remember which one, but it was in the bay area) and he said,"What? What? I'm sorry I can't hear you over the sound of my laser!". When he could hear me, I told him that was one of the coolest things I'd ever heard anyone say.
china is on track to have a 100pettawatt laser operating this year called "The Station of Extream Light", SEL for short, which is going to be used to try and seperate energy and matter by breaking
empty space.
think that this links to the place building it
http://english.siom.cas.cn/Newsroom/rp/202207/t20220701_3071...
all in all good to have a competitive environment in reseach.......though the US government, cough, cough, might, nudge, think about, some funding there
Laser pulses can ablate materials and the shorter the pulse the crisper the edges. Back in the 90’s or early 00’s they demonstrated pulses laser cutting of tissue where the heat damage to surrounding tissue had a width of a single cell.
Yeah and I think this and radiological tools are why chemo tattoos exist. The system has to react to the twitch you can’t control when a weird noise happens next to your head. Instead of stabbing bolts into your skull through your skin with a device Torquemada would have been proud of, they target versus the dots and if the dots move? Well this is where my knowledge runs out. Either they shut down the beam or they target in realtime. But either way the payload is delivered where it’s supposed to be or not at all.
I don’t know if they are using laser scalpels in surgery. My medical fascination mostly ends at diagonostics and experimental procedures. If I don’t know anyone with a disorder I tend not to hear about new procedures. My friend in college was helping a prof work on picosecond violet lasers and now we are on femtosecond.
Yeah, or even if it were some more reasonable amount of energy that doesn't self-destruct it, there are probably applications where you want to hit a small area quickly without burning things around it.
Seems like you always start somewhere. First you have 25E-18, then bump it up to 1e-15, and maybe someday you are at 1e-9 and are doing inertial confinement fusion.
It doesn't make any sense to measure joules alone. _Any_ laser can output 2 petajoules. The only question is how long it takes to do that: hence Watts.
The president is refusing to spend over half of the money Congress has given to the NSF. (Justifications from those in the administration have focused on the fact that funding science supports their, quote, "ideological" enemies, universities.) In response, Congress has the right to make the NSF more independent, or to specify statutorily what the money has to be spent on. Under normal circumstances the fact that Congresspeople themselves were the ones who appropriated the funds would guarantee their support for seeing that their will was put into effect, but in these times there's no telling under what pressures they find themselves to abandon their positions.
Technically the budget has not been cut, and there is enough time for Congress to rescue it - but only if they believe the interest of the responsible public outweighs the risk of being seen to defect from Trumpism that would face them in the upcoming primary election.
Unlike the NIH situation, people are not directly dying from cancelled trials and perishables aren't being tossed out of refrigerators. There is still time to save American hard science from Trumpsim, if Congress could have a little pride and stand up for themselves. Otherwise the attack on our chemistry and physics laboratories will be a lot bigger than anything that has ever happened in a war.
I can't steelman the position that "the topic of the article might disappear at any moment because of funding cuts" is unrelated to the article. If it were a post about a startup releasing a new product, and the top comment was "hey FYI, this startup has filed for Chapter 11 bankruptcy", would that be off-topic too?
And: the article itself puffs about how this is attracting physics research to the US; how can contradicting claims the article makes be off-topic to discussion about self-same article? It can't be a "they're allowed to speak but we're not allowed to contradict"—this is HN! Discussion is the whole point!
That university has made cuts due to Trump policies and the funding for that laser has come
from The National Science Foundation, which has had its funding cut.
> “The French researcher in question was in possession of confidential information on his electronic device from Los Alamos National Laboratory — in violation of a non-disclosure agreement— something he admitted to taking without permission and attempted to conceal,” she wrote on social platform X, in response to a post from a French analyst.
It’s possible that Tricia McLaughlin is just lying, but Philippe Baptiste’s comments come across as grandstanding:
> “Freedom of opinion, free research and academic freedom are values that we will continue to proudly uphold,” he added. “I will defend the possibility for all French researchers to be faithful to them, in compliance with the law.”
Do you have any other examples? Most of the stories I have read about researchers having trouble with immigration have involved Chinese nationals who frankly never should have been allowed near public research facilities in the first place.
I am going to double down on this person and the Lebanese person who was also deported (for which you responded on).
Having classified information from a laboratory that was given to you by that laboratory on a device that was not sanctioned by the lab… and he was hesitant to let anyone have access to the device (because it contained classified information) and should not be given to someone else… this is not a crime. Just a low level breach of a civil agreement, and rightfully hesitant to share with others.
A person who was at a Hezbollah funeral (like thousands were because they are among the leaders of the country) is not a ground for deportation.
When laws are not followed as they should be, and law enforcement makes their own judgment, this is the outcome: an unpredictable behavior of people who are simply looking to get offended.
Unlike some others here, I'm not saying this isn't happening, just that the comment doesn't belong here. Like you said, people have awareness, and there doesn't need to be a comment about science being at risk in the US on every science-related article (which is half of HN).
> In one, a kidney transplant specialist at Brown University in Providence, Rhode Island, was deported to Lebanon after trying to re-enter the United States with a valid visa. It was later reported that pictures on her phone had linked her with Hezbollah, which US authorities consider a foreign terrorist organization.
If you’re interested in the most energy per pulse, you want the “most energetic” laser, which is the NIF at LLNL. That’s about 2 megajoules per pulse or half a kilowatt hour. Definitely enough to kill a mosquito, but it doesn’t even register on the scale of Death Star style lasers from fiction.
And if you want the most destructive power, those are all military lasers. Which can absolutely destroy things science fiction style, but on a fairly small scale and with some important limitations.
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