Researchers Demonstrate 'Un-Hackable' Quantum Encryption
Academic researchers are taking lessons from quantum computing to create theoretically hack-proof forms of quantum data encryption.
Quantum encryption techniques may be one step closer to wide-scale use thanks to a new system developed by scientists at Duke University, The Ohio State University (OSU) and Oak Ridge National Laboratory. It’s capable of creating and distributing encryption codes at megabit-per-second rates, which is five to 10 times faster than existing methods and on par with current internet speeds when running several systems in parallel.
The researchers also demonstrated that the technique is secure from common attacks, even in the face of equipment flaws that could open up leaks.
"We are now likely to have a functioning quantum computer that might be able to start breaking the existing cryptographic codes in the near future," said Daniel Gauthier, a professor of physics at OSU. "We really need to be thinking hard now of different techniques that we could use for trying to secure the internet."
Typically, online purchases, bank transactions, medical records and other sensitive information is protected by encryption keys. Personal information sent over the web is first scrambled using one of these keys, and then unscrambled by the receiver using the same key.
For this system to work, both parties must have access to the same key, and it must be kept secret. Quantum key distribution (QKD) takes advantage of one of the fundamental properties of quantum mechanics—measuring tiny bits of matter like electrons or photons automatically changes their properties—to exchange keys in a way that immediately alerts both parties to the existence of a security breach.
Though QKD was first theorized in 1984 and implemented shortly thereafter, the technologies to support its wide-scale use are only now coming online. The research noted that companies in Europe now sell laser-based systems for QKD, and in a highly-publicized event last summer, China used a satellite to send a quantum key to two land-based stations located 1200 km apart.
The problem with many of these systems, said Nurul Taimur Islam, a graduate student in physics at Duke, is that they can only transmit keys at relatively low rates—between tens to hundreds of kilobits per second—which are too slow for most practical uses on the internet.
"At these rates, quantum-secure encryption systems cannot support some basic daily tasks, such as hosting an encrypted telephone call or video streaming," Islam said.
Like many QKD systems, Islam's key transmitter uses a weakened laser to encode information on individual photons of light. But they found a way to pack more information onto each photon, making their technique faster.
By adjusting the time at which the photon is released, and a property of the photon called the phase, their system can encode two bits of information per photon instead of one. This trick, paired with high-speed detectors developed by Clinton Cahall, graduate student in electrical and computer engineering, and Jungsang Kim, professor of electrical and computer engineering at Duke, powers their system to transmit keys five to 10 times faster than other methods.
"It was changing these additional properties of the photon that allowed us to almost double the secure key rate that we were able to obtain if we hadn't done that," said Gauthier, who began the work as a professor of physics at Duke before moving to OSU.
In a perfect world, QKD would be perfectly secure. Any attempt to hack a key exchange would leave errors on the transmission that could be easily spotted by the receiver. But real-world implementations of QKD require imperfect equipment, and these imperfections open up leaks that hackers can exploit.
The researchers carefully characterized the limitations of each piece of equipment they used. They then worked with Charles Lim, professor of electrical and computer engineering at the National University of Singapore, to incorporate these experimental flaws into the theory.
"We wanted to identify every experimental flaw in the system, and include these flaws in the theory so that we could ensure our system is secure and there is no potential side-channel attack," Islam said.
Though their transmitter requires some specialty parts, all of the components are currently available commercially. Encryption keys encoded in photons of light can be sent over existing optical fiber lines that burrow under cities, making it relatively straightforward to integrate their transmitter and receiver into the current internet infrastructure.
"All of this equipment, apart from the single-photon detectors, exist in the telecommunications industry, and with some engineering we could probably fit the entire transmitter and receiver in a box as big as a computer CPU," Islam said.
Some are taking the news with a grain of salt.
"We often encounter these new ‘hack-proof’ promises,” said Ofer Maor, director of enterprise solutions at Synopsys, via email. “While the technology does indeed sound interesting, touting a hack-proof title is dangerous and somewhat presumptuous. We have seen time and again claims for new hack-proof technology, that was shortly after hacked. Only technologies that withstood a long series of hack attempts by leading encryption experts, hackers and governments, can have a reasonable claim at that, and even that is not always the case. Moreover, even if the theory is indeed hack-proof, we have seen that in many cases, when this is implemented to become a usable commercial product, implementation flaws introduce new security weaknesses that can later be taken advantage of, ending in an embarrassing compromise to the ‘unbreakable’ theme."
Source: Information Security Magazine