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14 Entangled Photons Dispel Quantum Computing Bottleneck

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Physicists at the Max Planck Institute of Quantum Optics developed a method that could facilitate the construction of powerful and robust quantum computers, as well as the secure transmission of data. The physicists generated up to 14 entangled photons, in an optical resonator, which could be prepared into specific quantum physical states in a targeted and efficient manner.

To use a quantum computer profitably, a large number of entangled particles must work together, as qubits in the quantum system. Until now, the entanglement of photons usually took place in special, nonlinear crystals. The shortcoming with this method is that the photons are essentially created randomly and in a way that cannot be controlled. This also limits the number of particles that can be bundled into a collective state.

The newly developed method allowed basically any number of entangled photons to be generated, the researchers said.

According to Philip Thomas, a doctoral student at the Max Planck Institute of Quantum Optics, to the best of the scientists’ knowledge, the 14 interconnected light particles are the largest number of entangled photons that have been generated in a laboratory.
Photons are well suited for entanglement  because they are robust by nature and easy to manipulate, he said.

The research team used a single atom to emit the photons and interweave them in a specific way. To do this, the researchers placed a rubidium atom at the center of an optical cavity. 
With laser light of a specific frequency, the state of the atom could be precisely addressed. Using an additional control pulse, the researchers also specifically triggered the emission of a photon that is entangled with the quantum state of the atom.

Setup of an optical resonator in a vacuum. A single rubidium atom is trapped between the conically shaped mirrors inside the holder. Courtesy of MPQ.


Setup of an optical resonator in a vacuum. A single rubidium atom is trapped between the conically shaped mirrors inside the holder. Courtesy of MPQ.

“We repeated this process several times and in a previously determined manner,” Thomas said. In between, the atom was rotated. In this way, it was possible to create a chain of up to 14 photons that were entangled with each other by the atomic rotations and brought into a desired state.

More than the quantity of the entangled photons marking a major step toward the development of powerful quantum computers is the importance of the way that they were generated, which was also very different from conventional methods. "Because the chain of photons emerged from a single atom, it could be produced in a deterministic way,” Thomas said. This means that, in principle, each control pulse actually delivered a photon with the desired properties.

Experimental setup with vacuum chamber on an optical table. Courtesy of MPQ.


Experimental setup with vacuum chamber on an optical table. Courtesy of MPQ.

Additionally, the method is efficient — another important measure for potential future technical applications. “By measuring the photon chain produced, we were able to prove an efficiency of almost 50%,” Thomas said. This means that almost every second “push of a button” on the rubidium atom delivered a usable light particle — far more than has been achieved in previous experiments.

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“All in all, our work removes a longstanding obstacle on the path to scalable, measurement-based quantum computing,” said Gerhard Rempe, director at the Max Planck Institute of Quantum Optics.
Setup of an optical resonator in a vacuum. A single rubidium atom is trapped between the conically shaped mirrors inside the holder. Courtesy of MPQ.


Setup of an optical resonator in a vacuum. A single rubidium atom is trapped between the conically shaped mirrors inside the holder. Courtesy of MPQ.

The scientists want to remove another hurdle. Complex computing operations for instance would require at least two atoms as photon sources in the resonator. The quantum physicists speak of a two-dimensional cluster state. “We are already working on tackling this task,” Thomas said.

He said that possible technical applications extend beyond quantum computing. “Another application example is quantum communication,” he said.

For example, using the method, quantum information could be packaged in entangled photons and could also survive a certain amount of light loss, and enable secure communication over greater distances.

The research was published in Nature (www.doi.org/10.1038/s41586-022-04987-5).


Published: August 2022
Glossary
quantum
The term quantum refers to the fundamental unit or discrete amount of a physical quantity involved in interactions at the atomic and subatomic scales. It originates from quantum theory, a branch of physics that emerged in the early 20th century to explain phenomena observed on very small scales, where classical physics fails to provide accurate explanations. In the context of quantum theory, several key concepts are associated with the term quantum: Quantum mechanics: This is the branch of...
photon
A quantum of electromagnetic energy of a single mode; i.e., a single wavelength, direction and polarization. As a unit of energy, each photon equals hn, h being Planck's constant and n, the frequency of the propagating electromagnetic wave. The momentum of the photon in the direction of propagation is hn/c, c being the speed of light.
resonator
A resonator is a device or system that exhibits resonance, which is a phenomenon that occurs when an external force or stimulus is applied at a specific frequency, causing the system to oscillate with increased amplitude. Resonators are found in various fields and can take different forms depending on the type of waves involved, such as mechanical waves, acoustic waves, electromagnetic waves, or optical waves. Key points about resonators: Resonance: Resonance is a condition where a...
Research & Technologyquantumentangledphotonphotonsrubidiumatomgenerationentanglementquantum computingMax Planck Institute for Quantum Opticsquantum communicationsLasersOpticsresonatorEuropeTechnology News

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