Home > Press > New quantum computing architecture could be used to connect large-scale devices: Researchers have demonstrated directional photon emission, the first step toward extensible quantum interconnects
This image shows a module composed of superconducting qubits that can be used to directionally emit microwave photons.
Credits:Image: Krantz NanoArt |
Abstract:
Quantum computers hold the promise of performing certain tasks that are intractable even on the worlds most powerful supercomputers. In the future, scientists anticipate using quantum computing to emulate materials systems, simulate quantum chemistry, and optimize hard tasks, with impacts potentially spanning finance to pharmaceuticals.
New quantum computing architecture could be used to connect large-scale devices: Researchers have demonstrated directional photon emission, the first step toward extensible quantum interconnects
Cambridge, MA | Posted on January 6th, 2023
However, realizing this promise requires resilient and extensible hardware. One challenge in building a large-scale quantum computer is that researchers must find an effective way to interconnect quantum information nodes smaller-scale processing nodes separated across a computer chip. Because quantum computers are fundamentally different from classical computers, conventional techniques used to communicate electronic information do not directly translate to quantum devices. However, one requirement is certain: Whether via a classical or a quantum interconnect, the carried information must be transmitted and received.
To this end, MIT researchers have developed a quantum computing architecture that will enable extensible, high-fidelity communication between superconducting quantum processors. In work published in Nature Physics, MIT researchers demonstrate step one, the deterministic emission of single photons information carriers in a user-specified direction. Their method ensures quantum information flows in the correct direction more than 96 percent of the time.
Linking several of these modules enables a larger network of quantum processors that are interconnected with one another, no matter their physical separation on a computer chip.
Quantum interconnects are a crucial step toward modular implementations of larger-scale machines built from smaller individual components, says Bharath Kannan PhD 22, co-lead author of a research paper describing this technique.
The ability to communicate between smaller subsystems will enable a modular architecture for quantum processors, and this may be a simpler way of scaling to larger system sizes compared to the brute-force approach of using a single large and complicated chip, Kannan adds.
Kannan wrote the paper with co-lead author Aziza Almanakly, an electrical engineering and computer science graduate student in the Engineering Quantum Systems group of the Research Laboratory of Electronics (RLE) at MIT. The senior author is William D. Oliver, a professor of electrical engineering and computer science and of physics, an MIT Lincoln Laboratory Fellow, director of the Center for Quantum Engineering, and associate director of RLE.
Moving quantum information
In a conventional classical computer, various components perform different functions, such as memory, computation, etc. Electronic information, encoded and stored as bits (which take the value of 1s or 0s), is shuttled between these components using interconnects, which are wires that move electrons around on a computer processor.
But quantum information is more complex. Instead of only holding a value of 0 or 1, quantum information can also be both 0 and 1 simultaneously (a phenomenon known as superposition). Also, quantum information can be carried by particles of light, called photons. These added complexities make quantum information fragile, and it cant be transported simply using conventional protocols.
A quantum network links processing nodes using photons that travel through special interconnects known as waveguides. A waveguide can either be unidirectional, and move a photon only to the left or to the right, or it can be bidirectional.
Most existing architectures use unidirectional waveguides, which are easier to implement since the direction in which photons travel is easily established. But since each waveguide only moves photons in one direction, more waveguides become necessary as the quantum network expands, which makes this approach difficult to scale. In addition, unidirectional waveguides usually incorporate additional components to enforce the directionality, which introduces communication errors.
We can get rid of these lossy components if we have a waveguide that can support propagation in both the left and right directions, and a means to choose the direction at will. This directional transmission is what we demonstrated, and it is the first step toward bidirectional communication with much higher fidelities, says Kannan.
Using their architecture, multiple processing modules can be strung along one waveguide. A remarkable feature the architecture design is that the same module can be used as both a transmitter and a receiver, he says. And photons can be sent and captured by any two modules along a common waveguide.
We have just one physical connection that can have any number of modules along the way. This is what makes it scalable. Having demonstrated directional photon emission from one module, we are now working on capturing that photon downstream at a second module, Almanakly adds.
Leveraging quantum properties
To accomplish this, the researchers built a module comprising four qubits.
Qubits are the building blocks of quantum computers, and are used to store and process quantum information. But qubits can also be used as photon emitters. Adding energy to a qubit causes the qubit to become excited, and then when it de-excites, the qubit will emit the energy in the form of a photon.
However, simply connecting one qubit to a waveguide does not ensure directionality. A single qubit emits a photon, but whether it travels to the left or to the right is completely random. To circumvent this problem, the researchers utilize two qubits and a property known as quantum interference to ensure the emitted photon travels in the correct direction.
The technique involves preparing the two qubits in an entangled state of single excitation called a Bell state. This quantum-mechanical state comprises two aspects: the left qubit being excited and the right qubit being excited. Both aspects exist simultaneously, but which qubit is excited at a given time is unknown.
When the qubits are in this entangled Bell state, the photon is effectively emitted to the waveguide at the two qubit locations simultaneously, and these two emission paths interfere with each other. Depending on the relative phase within the Bell state, the resulting photon emission must travel to the left or to the right. By preparing the Bell state with the correct phase, the researchers choose the direction in which the photon travels through the waveguide.
They can use this same technique, but in reverse, to receive the photon at another module.
The photon has a certain frequency, a certain energy, and you can prepare a module to receive it by tuning it to the same frequency. If they are not at the same frequency, then the photon will just pass by. Its analogous to tuning a radio to a particular station. If we choose the right radio frequency, well pick up the music transmitted at that frequency, Almanakly says.
The researchers found that their technique achieved more than 96 percent fidelity this means that if they intended to emit a photon to the right, 96 percent of the time it went to the right.
Now that they have used this technique to effectively emit photons in a specific direction, the researchers want to connect multiple modules and use the process to emit and absorb photons. This would be a major step toward the development of a modular architecture that combines many smaller-scale processors into one larger-scale, and more powerful, quantum processor.
The research is funded, in part, by the AWS Center for Quantum Computing, the U.S. Army Research Office, the Department of Energy Office of Science National Quantum Information Science Research Centers, the Co-design Center for Quantum Advantage, and the Department of Defense.
###
Written by Adam Zewe, MIT News Office
####
For more information, please click here
Contacts:
Abby Abazorius
Massachusetts Institute of Technology
Office: 617-253-2709
Copyright © Massachusetts Institute of Technology
If you have a comment, please Contact us.
Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.
Quantum chemistry
News and information
Electricity harvesting from evaporation, raindrops and moisture inspired by nature January 6th, 2023
Lithium-sulfur batteries are one step closer to powering the future January 6th, 2023
Wafer-scale 2D MoTe₂ layers enable highly-sensitive broadband integrated infrared detector January 6th, 2023
Govt.-Legislation/Regulation/Funding/Policy
Lithium-sulfur batteries are one step closer to powering the future January 6th, 2023
New method addresses problem with perovskite solar cells: NREL researchers provide growth approach that boosts efficiency, stability December 29th, 2022
New method of reducing carbon dioxide could be a golden solution to pollution December 9th, 2022
Possible Futures
Development of bio-friendly transparent temperature sensor technology that precisely measures temperature changes by light January 6th, 2023
Dual-site collaboration boosts electrochemical nitrogen reduction on Ru-S-C single-atom catalyst January 6th, 2023
Chip Technology
Wafer-scale 2D MoTe₂ layers enable highly-sensitive broadband integrated infrared detector January 6th, 2023
New X-ray imaging technique to study the transient phases of quantum materials December 29th, 2022
Experimental nanosheet material marks a step toward the next generation of low-power, high-performance electronics December 9th, 2022
Tin selenide nanosheets enables to develop wearable tracking devices December 9th, 2022
Quantum Computing
New X-ray imaging technique to study the transient phases of quantum materials December 29th, 2022
Quantum receiver enhanced by adaptive learning December 9th, 2022
NISTs grid of quantum islands could reveal secrets for powerful technologies November 18th, 2022
Discoveries
Electricity harvesting from evaporation, raindrops and moisture inspired by nature January 6th, 2023
Lithium-sulfur batteries are one step closer to powering the future January 6th, 2023
Wafer-scale 2D MoTe₂ layers enable highly-sensitive broadband integrated infrared detector January 6th, 2023
New nanowire sensors are the next step in the Internet of Things January 6th, 2023
Announcements
Electricity harvesting from evaporation, raindrops and moisture inspired by nature January 6th, 2023
Lithium-sulfur batteries are one step closer to powering the future January 6th, 2023
Wafer-scale 2D MoTe₂ layers enable highly-sensitive broadband integrated infrared detector January 6th, 2023
New nanowire sensors are the next step in the Internet of Things January 6th, 2023
Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters
Electricity harvesting from evaporation, raindrops and moisture inspired by nature January 6th, 2023
Lithium-sulfur batteries are one step closer to powering the future January 6th, 2023
Wafer-scale 2D MoTe₂ layers enable highly-sensitive broadband integrated infrared detector January 6th, 2023
New nanowire sensors are the next step in the Internet of Things January 6th, 2023
Military
An on-chip time-lens generates ultrafast pulses: New device opens the doors to applications in communication, quantum computing, astronomy November 18th, 2022
Rice turns asphaltene into graphene for composites: Flashed byproduct of crude oil could bolster materials, polymer inks November 18th, 2022
How 2D materials expand: New technique that accurately measures how atom-thin materials expand when heated could help engineers develop faster, more powerful electronic devices November 18th, 2022
Grants/Sponsored Research/Awards/Scholarships/Gifts/Contests/Honors/Records
The National Space Society Congratulates NASA on the Success of Artemis I Same-day Launch of the Hakuto-R Lunar Landing Mission will Help Support Future Lunar Crews December 12th, 2022
Rice turns asphaltene into graphene for composites: Flashed byproduct of crude oil could bolster materials, polymer inks November 18th, 2022
How 2D materials expand: New technique that accurately measures how atom-thin materials expand when heated could help engineers develop faster, more powerful electronic devices November 18th, 2022
New insights into energy loss open doors for one up-and-coming solar tech November 18th, 2022