alpb 5 years ago

In practice, scientists are rarely baffled. But titles like these just help things make it to the news.

  • darkerside 5 years ago

    I'd say, scientists are continually baffled. It's their job to mine the outer edges of human knowledge.

perl4ever 5 years ago

"Because FRBs last only a thousandth of a second or so, any object producing them couldn’t be much bigger than 200 miles across"

I read this sort of thing now and then over the years, and I'm not sure I understand it, or if it is misleading.

What is an "object"? Could an "object" be part of a stellar object, or is it necessarily the whole thing? It seems like surely some event can happen on the Sun in less time than it takes for light to pass across it, just like radio waves on earth can be modulated in less time than it takes for them to pass across the planet.

Maybe it's obvious what an "object" is, but I feel like the statement that it has to be under 200 miles wide is promoting the assumption that it has to be a neutron star, or perhaps a black hole. But does it?

rpmisms 5 years ago

I really really hope it's aliens. I want to be alive for that discovery.

  • AnIdiotOnTheNet 5 years ago

    Me too, but in the same way that I hope someone invents a drug that lets me eat whatever I want and not gain weight. The probability of actually seeing such a thing in our lifetime is infinitesimal.

  • tiku 5 years ago

    Just wait until the 20th of september

    • waterheater 5 years ago

      out of curiousity...why the 20th?

      • dsfyu404ed 5 years ago

        It's a joke about the Area 51 memes that have gone viral

        • waterheater 5 years ago

          oh yeah, that. Didn't see any info about it, so i figured it had already passed.

  • ggggtez 5 years ago

    FRBs are almost certainly just a natural occurrence.

tiborsaas 5 years ago

TLDR: They are still baffled.

The article only refers to repeating FBR-s but that's a known things for years now.

  • jfengel 5 years ago

    The subhead is slightly more informative: "The recent discovery of eight new signals means astronomers may finally have all the clues they need to solve a longstanding mystery." Which could perhaps be shortened to "Eight new signals provide data on fast radio bursts".

    • newsreview1 5 years ago

      how in the world do FRB's "release enough energy to power the world for three centuries." If we don't know how and when they are happening, how can we measure their energy? Can someone explain?

      • RedOrGreen 5 years ago

        We measure the energy of signals received at our radio telescopes - our units are Janskys, which correspond to 10^-26 watts per square metre per hertz of bandwidth, and we can calibrate our telescopes using noise diodes or known sources in the sky.

        So for FRBs, we get the received brightness, and if we can measure the distance, we can use the basic inverse square scaling to estimate how much energy it had at the source. (Why inverse square? Because the area of a sphere is 4 pi R^2 - if you go twice as far away, the signal is spread out over 4 times the area, and so on.)

        The key problem is a distance estimate for the FRBs - we have a pretty precise measurement for FRB 121102 because we identified its host galaxy and measured the redshift to that galaxy, so we know how far away it is. That's now been done for 2 other sources. For the rest, we can use the pulse dispersion, which measures the integrated column density of electrons along the line of sight, along with models for our galaxy and the intergalactic medium, to get some idea. It's not as good, but better than nothing.

        • bdamm 5 years ago

          This assumes a spherical signal propagation. But signals from antennas, and even from many natural emitters, aren't spherical. It's also possible that the signal is highly directional, like a jet. So, I'm pretty skeptical of these power estimates. For sure the transmitter has a lot of power, but how much exactly? I don't think we can really tell.

          • RedOrGreen 5 years ago

            Sure, that's an excellent point. In case you read late replies: we recognize this, and parameterize the burst energy [1] by a beaming scale factor, \Delta\Omega/4\pi. (It still drops off as the inverse square, though, as long as you're not in the near field.)

            The problem is, while you can reduce the energy requirement by making the beams narrow, that increases the total number of sources by the same factor. When we say that there are between 5000-10,000 FRBs all over the sky every single day, we are referring to FRBs beamed towards us. If you apply a 10% beam, your energy requirement drops by 10x, sure, but the source count goes up by 10x.

            Right now, we don't have a large enough plausible progenitor population, even at 1x, for these FRBs. It's a really fun problem.

            [1] See, e.g, the Methods section in https://www.nature.com/articles/nature20797 (or https://arxiv.org/abs/1701.01098)

            • bdamm 5 years ago

              That is really interesting! I didn't realize how unresolved this truly is.

          • penagwin 5 years ago

            To be fair though the bar wasn't set vary high.

            > power the world for three centuries

            Our sun for example is emitting enough energy in all directions to power the world for 300 years (over the course of 300 years), and most of it misses us.

            Our sun isn't particularly impressive in terms of energy and such compared to other astro-objects, so I feel like these kinda of events releasing so much energy are to be expected.

            • perl4ever 5 years ago

              "Our sun for example is emitting enough energy in all directions to power the world for 300 years (over the course of 300 years), and most of it misses us"

              I think you're saying any amount of energy can be produced by any amount of power, if the amount of time is unspecified. Which is true, but not substantive.

        • newsreview1 5 years ago

          Fascinating. Thanks for taking the time to explain.