An exciting new study linking cosmology and quantum computing — indicates that entangled qubits could be used to investigate the interiors of black holes.
Physicists have used a seven-qubit quantum computer to simulate the scrambling of information inside a black hole, heralding a future in which entangled quantum bits — qubits — might be used to probe the mysterious interiors of these space-time objects.
Scrambling is what happens when matter disappears inside a black hole. The information attached to that matter — the nature of its constituent particles including their energy and momentum — is chaotically mixed with all the other matter and information inside the singularity at the centre of the black hole, making it impossible to retrieve.
Since quantum mechanics says that information is never lost, even when that information disappears inside a black hole, this leads to a so-called “black hole information paradox.”
So, while some physicists claim that information falling through the event horizon of a black hole is lost forever, others argue that this information can be reconstructed, but only after waiting an inordinate amount of time — until the black hole has shrunk to nearly half its original size.
Cosmologists believe this shrinking could result from the emission of Hawking radiation, caused by quantum mechanical fluctuations at the very edge of the black hole — named after the late physicist Stephen Hawking.
As Hawking predicted that larger black holes would ‘leak’ Hawking radiation at a much slower rate, a black hole with the mass of our sun would far, far longer than the age of the universe to evaporate — whilst micro black holes would dissipate within a fraction of a second.
However, there is a loophole. It may be possible to retrieve this infalling information significantly faster by measuring subtle entanglements between the black hole and the Hawking radiation it emits.
Qubits and quantum computing.
Two bits of information — like the quantum bits, or qubits, in a quantum computer — are entangled when they are so closely linked that the quantum state of one automatically determines the state of the other, no matter how far apart they are.
Einstein famously referred to this as “spooky action at a distance” but it is more precise to consider this a property of the mathematics used to describe quantum systems. Measurements of entangled qubits can lead to the “teleportation” — or instant transmission — of quantum information from one qubit to another.
Norman Yao, a UC Berkeley assistant professor of physics, says: “One can recover the information dropped into the black hole by doing a massive quantum calculation on these outgoing Hawking photons.
“This is expected to be really, really hard, but if quantum mechanics is to be believed, it should, in principle, be possible. That’s exactly what we are doing here, but for a tiny three-qubit `black hole’ inside a seven-qubit quantum computer.”
By dropping an entangled qubit into a black hole and querying the emerging Hawking radiation, you could theoretically determine the state of a qubit inside the black hole, providing a window into the abyss.
Yao — who is interested in understanding the nature of quantum chao — and his colleagues at the University of Maryland and the Perimeter Institute for Theoretical Physics in Waterloo, Ontario, Canada, will report their results in a paper appearing in the March 6 issue of the journal Nature.
Yao learned from friend and colleague, Beni Yoshida — a theorist at the Perimeter Institute — that recovering quantum information falling into a black hole is possible if the information is scrambled rapidly inside the black hole. The more thoroughly it is mixed throughout the black hole, the more reliably the information can be retrieved via teleportation. Based on this insight, Yoshida and Yao proposed last year an experiment to provably demonstrate scrambling on a quantum computer.
Yao says: “With our protocol, if you measure a teleportation fidelity that is high enough, then you can guarantee that scrambling happened within the quantum circuit.”
Yao drafted the help of Chris Monroe, a physicist at the University of Maryland in College Park who heads one of the world’s leading trapped-ion quantum information groups. The group implemented the protocol proposed by Yoshida and Yao and effectively measured an out-of-time-ordered correlation function.
These peculiar correlation functions — called OTOCs — are created by comparing two quantum states that differ in the timing of when certain kicks or perturbations are applied. The key is being able to evolve a quantum state both forward and backwards in time to understand the effect the second kick has on the first kick.
Monroe’s group created a scrambling quantum circuit on three qubits within a seven-qubit trapped-ion quantum computer and characterized the resulting decay of the OTOC. While the decay of the OTOC is typically taken as a strong indication that scrambling has occurred, to prove that they had to show that the OTOC didn’t simply decay because of decoherence — that is, that it wasn’t just poorly shielded from the noise of the outside world, which also causes quantum states to fall apart.
Yao and Yoshida proved that the greater the accuracy with which they could retrieve the entangled or teleported information, the more stringently they could put a lower limit on the amount of scrambling that had occurred in the OTOC.
Monroe and his colleagues measured a teleportation fidelity of approximately 80% — meaning that perhaps half of the quantum state was scrambled and the other half decayed by decoherence. Nevertheless, this was enough to demonstrate that genuine scrambling had indeed occurred in this three-qubit quantum circuit.
Yao explains the significance of this: “One possible application for our protocol is related to the benchmarking of quantum computers, where one might be able to use this technique to diagnose more complicated forms of noise and decoherence in quantum processors.”
Yao is also working with a UC Berkeley group led by Irfan Siddiqi to demonstrate scrambling in a different quantum system, superconducting qutrits — quantum bits that have three, rather than two, states.
Siddiqi, a UC Berkeley professor of physics, also leads the effort at Lawrence Berkeley National Laboratory to build an advanced quantum computing testbed, says: “At its core, this is a qubit or qutrit experiment, but the fact that we can relate it to cosmology is because we believe the dynamics of quantum information is the same.
“The U.S. is launching a billion-dollar quantum initiative, and understanding the dynamics of quantum information connects many areas of research within this initiative: quantum circuits and computing, high energy physics, black hole dynamics, condensed matter physics and atomic, molecular and optical physics. The language of quantum information has become pervasive for our understanding of all these different systems.”