MH370 Latest: How Underwater Microphones Listening Out for Nuclear Bombs Could Be Used to Find Missing Plane

Indian Ocean
The Indian Ocean seen from space. NASA

This article was originally published on The Conversation. Read the original article.

Looking at the ocean, a lake, or even a pond, you may wonder what happens to the waves you see when they "disappear." These surface waves tend to become smaller and smaller until you can't see them anymore. But they keep traveling through the water at a lower depth. These "acoustic-gravity waves" can travel for thousands of miles undisturbed, and even cross an entire ocean.

These compression waves are generated by a sudden change in the water pressure. They can be caused by anything from submarines, earthquakes and landslides, to falling meteorites or other objects impacting the sea surface. And although they are "acoustic" waves, they are below the range of human hearing—the only way to pick up and record them is using hydrophones, special microphones that work underwater.

The Comprehensive Nuclear-Test-Ban Treaty Organization (CTBTO) has hydrophone stations dotted in oceans across the world. They are used by the organization to detect shock waves that may be a consequence of an underwater nuclear test—but we have found a way to use these signals, to find where and when acoustic waves are originally generated.

Searching with sound

Some of the organization's stations, such as HA01, located off Cape Leeuwin in south-west Australia, have three hydrophones. This configuration lets us calculate the direction of the waves quite accurately because the incoming waves hit the hydrophones in a particular order, similar to how soundwaves hit human ears. But unlike sounds processed by our brain, hydrophones alone cannot easily tell how far away the event was generated, or what generated it.

To do this, we used mathematical tools which consider the way acoustic-gravity waves behave. As these waves travel through the water, they disperse. This means that groups of waves created by a source start off being close together, but tend to become more spread apart as they travel further—this is because lower frequency soundwaves are a bit slower than those at higher frequency. By looking at how frequencies disperse, we can estimate how far the wave has traveled, and this can give us an estimate of where they originated from.

Our study was initially motivated by a desire to gain more knowledge about the incident involving missing flight MH370. To confirm that our idea worked, we targeted two 5.1 magnitude earthquakes, which had already been localized by seismometers, and tried to find their location with our method. The accuracy was quite good (with errors of around 62-93 miles), considering that the signals traveled for 1,240 miles in one case and 3,100 miles in the other, and that the hydrophones picked up other noises due to surface wind, boats, and other underwater sources.

In our search we also found a very interesting signal coming from an area near the Antarctic circle. This signal looks surprisingly similar to one which we obtained by dropping a heavy sphere in a large tank, 40 meters deep, during a set of experiments. We think the ocean signal could have been caused by a meteorite, but have yet to confirm this with NASA.


MH370 vigil
Students in China light candles to pray for passengers aboard Malaysia Airlines flight MH370, March 10, 2014. Stringer/Reuters

Since confirming that the technique worked, we have used advanced automated methods to find signals buried inside the hours of data recorded by the hydrophone station off Cape Leeuwin before the time flight MH370 was believed to have run out of fuel. We were able to find and localize two very faint signals—one ten minutes after the last satellite communication with the plane—but far from the probable location arc, and another almost one hour later, closer to the last area where the plane last communicated with a satellite.

Though we have located two points around the time of MH370's disappearance, we cannot say with any real certainty that these have any association with the aircraft. Just like in a busy restaurant, it gets more and more difficult to pick up individual voices as the noise in the room gets louder. What we do know is that the hydrophones picked up remarkably weak signals at these locations and that the signals, according to our calculations, accounted for some sort of source in the Indian Ocean.

All of this information has been passed onto the Australian Transport Safety Bureau—the government body which was leading the search for MH370 until it was suspended on January 17, 2017. We anticipate that both now, and in the future, this new source of information could be used in conjunction with a whole host of other data that is at the disposal of the authorities in the search for missing objects at sea.

Davide Crivelli is a Lecturer in Mechanical Engineering at Cardiff University and Usama Kadri is Lecturer of Applied Mathematics at Cardiff University, U.K.