Scientists Have Discovered a Shape That Blocks All Sound

Scientists have developed an "acoustic meta-material" that can catch certain frequencies passing through the air and reflect them back toward their source. When a loudspeaker was placed into one end of a PVC pipe with a 3D-printed ring of the metamaterial, the ring "cut 94% of the sound blasting from the speaker, enough to make it inaudible to the human ear," reports Fast Company. From the report: Typical acoustic paneling works differently, absorbing sound and turning the vibrations into heat. But what's particularly trippy is that this muffler is completely open. Air and light can travel through it -- just sound cannot. The implications for architecture and interior design are remarkable, because these metamaterials could be applied to the built environment in many different ways. For instance, they could be stacked to build soundproof yet transparent walls. Cubicles will never be the same.

The researchers also believe that HVAC systems could be fitted with these silencers, and drones could have their turbines muted with such rings. Even in MRI machines, which can be harrowingly loud for patients trapped in a small space, could be quieted. There's really no limit to the possibilities, but it does sound like these silencers will need to be tailored to circumstance. "The idea is that we can now mathematically design an object that can blocks the sounds of anything," says Boston University professor Xin Zhang, in a press release. You can see a demo of the noise cancellation device here.

Re:What about flow restrictions?

[viperidaenz]

rtfa: yes it allows air flow.

BS article and summary

[LynnwoodRooster]

It's a band reject filter, been used in acoustics for around 100 years. A narrow-band Helmholtz radiator that cuts ~1/30th of an octave in bandwidth. So it's great for a specific tone - but not broadband. And the dimensions of the elements (neck diameter, neck length, size of constrained volume) are proportional to wavelength, so what works in the demo at 1 kHz is massive at 100 Hz - and beyond house-sized at 20 Hz. This is just someone going "oh wow they can notch out a single frequency think about the impact!" when acoustics NVH guys have been doing it for 10 decades...

The shape of a husband's ear?

[Jason+Straight]

Works for me.

Re:Make sure to test it on...

[fahrbot-bot]

...a bawling kid at night in an airplane at 35,000ft.
If you could blot _that_ out I'd be well impressed.

Ya, but stuffing a kid into a PVC pipe might be going a bit too far, unless, of course, you're on United.

Here is the actual information

[Okian+Warrior]

*sigh*

Since the editor and submitter didn't do it,

here is the BU research alert, which includes an image of the new material, and

here is a link to the published paper, from which you can get a DOI number if you want to read about their work.

The acoustic suppressor looks like thick a 3-d printed bushing.

Re:That sounds like a two-stroke exhaust

[thrich81]

I hope you aren't being snarky back to the AC (who deserves it) so I don't subsequently look like a moron in what follows, but on the off chance you aren't... The exhaust from a piston engine consists of high pressure, very hot bursts of gas at the exhaust ports. Hot, high pressure, and bursty going into relatively cool outside air -- perfect combination to create a lot of sound. Exhaust manifolds and mufflers combine and smooth out the exhaust bursts to create a smoother flowing, more uniform in time exhaust flow resulting in less noise. There are all kinds of pressure and flow reflections in a good exhaust system to help scavenge the exhaust gases during the exhaust stroke and reduce noise. Even a smooth flow is loud if it is fast and hot enough -- as exemplified by jet engine exhaust, which (I think) makes its noise from turbulent mixing in itself and with the outside air.

Link to the paper

[paazin]

Here's the paper published in Phys. Rev. B 99 in case anyone is interested: https://journals.aps.org/prb/abstract/10.1103/PhysRevB.99.024302