Superconducting Quantum Bit Light-Conducting Fiber

Secret to Constructing Superconducting Quantum Computer systems With Huge Processing Energy

Superconducting Quantum Bit Light-Conducting Fiber

NIST physicists measured and managed a superconducting quantum bit (qubit) utilizing light-conducting fiber (indicated by white arrow) as a substitute of metallic electrical cables just like the 14 proven right here inside a cryostat. Through the use of fiber, researchers may doubtlessly pack 1,000,000 qubits right into a quantum laptop relatively than just some thousand. Credit score: F. Lecocq/NIST

Optical Fiber May Increase Energy of Superconducting Quantum Computer systems

The key to constructing superconducting quantum computer systems with large processing energy could also be an peculiar telecommunications know-how — optical fiber. 

Physicists on the Nationwide Institute of Requirements and Know-how (NIST) have measured and managed a superconducting quantum bit (qubit) utilizing light-conducting fiber as a substitute of metallic electrical wires, paving the best way to packing 1,000,000 qubits right into a quantum laptop relatively than just some thousand. The demonstration is described within the March 25 challenge of Nature.

Superconducting circuits are a number one know-how for making quantum computer systems as a result of they’re dependable and simply mass produced. However these circuits should function at cryogenic temperatures, and schemes for wiring them to room-temperature electronics are advanced and liable to overheating the qubits. A common quantum laptop, able to fixing any kind of drawback, is predicted to want about 1 million qubits. Standard cryostats — supercold dilution fridges — with metallic wiring can solely help 1000’s on the most.

Optical fiber, the spine of telecommunications networks, has a glass or plastic core that may carry a excessive quantity of sunshine indicators with out conducting warmth. However superconducting quantum computer systems use microwave pulses to retailer and course of info. So the sunshine must be transformed exactly to microwaves. 

To unravel this drawback, NIST researchers mixed the fiber with a couple of different commonplace parts that convert, convey and measure mild on the degree of single particles, or photons, which may then be simply transformed into microwaves. The system labored in addition to metallic wiring and maintained the qubit’s fragile quantum states.

“I believe this advance can have excessive influence as a result of it combines two completely totally different applied sciences, photonics and superconducting qubits, to unravel an important drawback,” NIST physicist John Teufel mentioned. “Optical fiber may carry way more information in a a lot smaller quantity than standard cable.”

Usually, researchers generate microwave pulses at room temperature after which ship them by coaxial metallic cables to cryogenically maintained superconducting qubits. The brand new NIST setup used an optical fiber as a substitute of metallic to information mild indicators to cryogenic photodetectors that transformed indicators again to microwaves and delivered them to the qubit. For experimental comparability functions, microwaves might be routed to the qubit by both the photonic hyperlink or an everyday coaxial line.

The “transmon” qubit used within the fiber experiment was a tool generally known as a Josephson junction embedded in a three-dimensional reservoir or cavity. This junction consists of two superconducting metals separated by an insulator. Below sure circumstances {an electrical} present can cross the junction and should oscillate forwards and backwards. By making use of a sure microwave frequency, researchers can drive the qubit between low-energy and excited states (1 or 0 in digital computing). These states are based mostly on the variety of Cooper pairs — certain pairs of electrons with reverse properties — which have “tunneled” throughout the junction. 

The NIST staff performed two kinds of experiments, utilizing the photonic hyperlink to generate microwave pulses that both measured or managed the quantum state of the qubit. The strategy relies on two relationships: The frequency at which microwaves naturally bounce forwards and backwards within the cavity, known as the resonance frequency, will depend on the qubit state. And the frequency at which the qubit switches states will depend on the variety of photons within the cavity.

Researchers typically began the experiments with a microwave generator. To manage the qubit’s quantum state, gadgets known as electro-optic modulators transformed microwaves to increased optical frequencies. These mild indicators streamed by optical fiber from room temperature to 4 kelvins (minus 269 C or minus 452 F) down to twenty millikelvins (thousandths of a kelvin), the place they landed in high-speed semiconductor photodetectors, which transformed the sunshine indicators again to microwaves that have been then despatched to the quantum circuit.

In these experiments, researchers despatched indicators to the qubit at its pure resonance frequency, to place it into the specified quantum state. The qubit oscillated between its floor and excited states when there was ample laser energy. 

To measure the qubit’s state, researchers used an infrared laser to launch mild at a selected energy degree by the modulators, fiber and photodetectors to measure the cavity’s resonance frequency.

Researchers first began the qubit oscillating, with the laser energy suppressed, after which used the photonic hyperlink to ship a weak microwave pulse to the cavity. The cavity frequency precisely indicated the qubit’s state 98% of the time, the identical accuracy as obtained utilizing the common coaxial line.

The researchers envision a quantum processor through which mild in optical fibers transmits indicators to and from the qubits, with every fiber having the capability to hold 1000’s of indicators to and from the qubit.

Reference: “Management and readout of a superconducting qubit utilizing a photonic hyperlink” by F. Lecocq, F. Quinlan, Okay. Cicak, J. Aumentado, S. A. Diddams and J. D. Teufel, 24 March 2021, Nature.
DOI: 10.1038/s41586-021-03268-x

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