This crafty tool can eavesdrop on 6G wireless signals
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With a tool made out of simple materials like office paper and a metallic foil transfer, attackers can listen in on 6G transmissions between two users, researchers said.
Hackers could make a tool to eavesdrop on some 6G wireless signals with just office paper, an inkjet printer, a metallic foil transfer, and a laminator.
The researchers who discovered the wireless security hack presented their findings and demonstrated the attack in San Antonio at ACM WiSec 2022, the Association for Computing Machinery’s annual conference on security and privacy in wireless and mobile networks.
“Awareness of a future threat is the first step to counter that threat,” says study coauthor Edward Knightly, professor of electrical and computer engineering at Rice University. “The frequencies that are vulnerable to this attack aren’t in use yet, but they are coming and we need to be prepared.”
‘Metasurface in the middle’
In the study, Knightly, Brown University engineering professor Daniel Mittleman, and colleagues showed an attacker could easily make a sheet of office paper covered with 2D foil symbols—a metasurface—and use it to redirect part of a 150 gigahertz” pencil beam” transmission between two users.
They dubbed the attack “Metasurface-in-the-Middle” as a nod to both the hacker’s tool and the way it is wielded. Metasurfaces are thin sheets of material with patterned designs that manipulate light or electromagnetic waves.” Man-in-the-middle” is a computer security industry classification for attacks in which an adversary secretly inserts themself between two parties.
The 150 gigahertz frequency is higher than is used in today’s 5G cellular or Wi-Fi networks. But Knightly says wireless carriers are looking to roll out 150 gigahertz and similar frequencies known as terahertz waves or millimeter waves over the next decade.
“Next-generation wireless will use high frequencies and pencil beams to support wide-band applications like virtual reality and autonomous vehicles,” says Knightly, who will present the research with coauthor Zhambyl Shaikhanov, a graduate student in his lab.
How the attack would work
In the study, the researchers use the names Alice and Bob to refer to the two people whose communications are hacked. The eavesdropper is called Eve.
To mount the attack, Eve first designs a metasurface that will diffract a portion of the tight-beam signal to her location. For the demonstration, the researchers designed a pattern with hundreds of rows of split rings. Each looks like the letter C, but they are not identical. The open part of each ring varies in size and orientation.
“Those openings and orientations are very specifically done to get the signal to diffract in the exact direction Eve wants,” Shaikhanov says. “After she designs the metasurface, she prints it on a regular laser printer, and then she uses a hot stamping technique that’s used in crafting. She places a metal foil on the printed paper, feeds it through a laminator and the heat and pressure create a bond between the metal and the toner.”
Mittleman and study coauthor Hichem Guerboukha, a postdoctoral research fellow at Brown, show in a 2021 study that the hot-stamping method could be used to make split-ring metasurfaces with resonances up to 550 GHz.
“We developed this approach in order to lower the barrier for fabrication of metasurfaces, so that researchers could test many different designs quickly and inexpensively,” Mittleman says. “Of course, this lowers the barrier for eavesdroppers too.”
Better to know this now than later
The researchers say they hope the study will dispel a common misperception in the wireless industry that higher frequencies are inherently secure.
“People have been quoted saying millimeter-wave frequencies are ‘covert’ and ‘highly confidential’ and that they ‘provide security,'” Shaikhanov says. “The thinking is, ‘If you have a super narrow beam, nobody can eavesdrop on the signal because they would have to physically get between the transmitter and the receiver.’ What we’ve shown is that Eve doesn’t have to be obtrusive to mount this attack.”
The research shows that the attack would be difficult for Alice or Bob to detect today. And while the metasurface must be placed between Alice and Bob, “it could be hidden in the environment,” Knightly says. “You could conceal it with other sheets of paper, for instance.”
Knightly says now that wireless researchers and equipment manufacturers know about the attack, they can further study it, develop detection systems, and build those into terahertz networks up front.
“If we had known from day one, when the internet first came out, that there would be denial-of-service attacks and attempts to take down web servers, we would have designed it differently,” Knightly says. “If you build first, wait for attacks, and then try to repair, that is a much more costly and expensive path than designing securely up front.”
“Millimeter-wave frequencies and metasurfaces are new technologies that can each be used to advance communication, but any time we get a new capability for communication we have to ask the question, ‘What if the adversary has this technology? What new capabilities will it give them that they didn’t have in the past? And how can we realize a secure network against a strong adversary?'”
Support for the research came from Cisco, Intel, the National Science Foundation, and the Army Research Laboratory.
This article was originally published in Futurity. It has been republished under the Attribution 4.0 International license.