Researchers at Purdue University have trapped alkali atoms (cesium) on an integrated photonic circuit, which behaves like a transistor for photons (the smallest energy unit of light) similar to electronic transistors. These trapped atoms demonstrate the potential to build a quantum network based on cold-atom integrated nanophotonic circuits. The team, led by Chen-Lung Hung, associate professor of physics and astronomy at the Purdue University College of Science, published their discovery in the American Physical Society's Physical Review X.
"We developed a technique to use lasers to cool and tightly trap atoms on an integrated nanophotonic circuit, where light propagates in a small photonic 'wire' or, more precisely, a waveguide that is more than 200 times thinner than a human hair," explains Hung, who is also a member of the Purdue Quantum Science and Engineering Institute. "These atoms are 'frozen' to negative 459.67 degrees Fahrenheit or merely 0.00002 degrees above the absolute zero temperature and are essentially standing still. At this cold temperature, the atoms can be captured by a 'tractor beam' aimed at the photonic waveguide and are placed over it at a distance much shorter than the wavelength of light, around 300 nanometers or roughly the size of a virus. At this distance, the atoms can very efficiently interact with photons confined in the photonic waveguide. Using state-of-the-art nanofabrication instruments in the Birck Nanotechnology Center, we pattern the photonic waveguide in a circular shape at a diameter of around 30 microns (three times smaller than a human hair) to form a so-called microring resonator. Light would circulate within the microring resonator and interact with the trapped atoms."
A key aspect function the team demonstrates in this research is that this atom-coupled microring resonator serves like a 'transistor' for photons. They can use these trapped atoms to gate the flow of light through the circuit. If the atoms are in the correct state, photons can transmit through the circuit. Photons are entirely blocked if the atoms are in another state. The stronger the atoms interact with the photons, the more efficient this gate is.
"We have trapped up to 70 atoms that could collectively couple to photons and gate their transmission on an integrated photonic chip. This has not been realized before," says Xinchao Zhou, graduate student at Purdue Physics and Astronomy. Zhou is also the recipient of this year's Bilsand Dissertation Fellowship.
The entire research team is based out of Purdue University in West Lafayette, Indiana. Hung served as principal investigator and supervised the project. Zhou performed the experiment to trap atoms on the integrated circuit, which was designed and fabricated in-house by Tzu-Han Chang, a former postdoc now working with Prof. Sunil Bhave at the Birck Nanotechnology Center. The critical portions of the experiment were set up by Zhou and Hikaru Tamura, a former postdoc at Purdue at the time of the research and now an assistant professor at the Institute of Molecular Science in Japan.
"Our technique, which we detailed in the paper, allows us to very efficiently laser cool many atoms on an integrated photonic circuit. Once many atoms are trapped, they can collectively interact with light propagating on the photonic waveguide," says Zhou. "This is unique for our system because all the atoms are the same and indistinguishable, so they could couple to light in the same way and build up phase coherence, allowing atoms to interact with light collectively with stronger strength. Just imagine a boat moving faster when all rowers row the boat in synchronization compared with unsynchronized motion. In contrast, solid-state emitters embedded in a photonic circuit are hardly 'the same' due to slightly different surroundings influencing each emitter. It is much harder for many solid-state emitters to build up phase coherence and collectively interact with photons like cold atoms. We could use cold atoms trapped on the circuit to study new collective effects," says Hung.
The platform demonstrated in this research could provide a photonic link for future distributed quantum computing based on neutral atoms. It could also serve as a new experimental platform for studying collective light-matter interactions and for synthesizing quantum degenerate trapped gases or ultracold molecules.
"Unlike electronic transistors used in daily life, our atom-coupled integrated photonic circuit obeys the principles of quantum superposition," explains Hung. "This allows us to manipulate and store quantum information in trapped atoms, which are quantum bits known as qubits. Our circuit may also efficiently transfer stored quantum information into photons that could 'fly' through the photonic wire and a fiber network to communicate with other atom-coupled integrated circuits or atom-photon interfaces. Our research demonstrates a potential to build a quantum network based on cold-atom integrated nanophotonic circuits."
The team has been working on this research area for several years and plans to pursue it with vigor. Their past research discovery tied to this work include recent breakthroughs such as the realization of the 'tractor beam' method in 2023 listing Zhou as first author, and the realization of highly efficient optical fiber-coupling to a photonic chip in 2022 with a pending US patent application. New research directions have opened up due to the team's successful demonstration of atoms being very efficiently cooled and trapped on a circuit. The future for this research is bright with many avenues to explore.
"There are several promising next steps to explore," says Hung. "We could arrange the trapped atoms in an organized array along the photonic waveguide. These atoms can collectively couple to the waveguide through constructive interference but cannot radiate photons into the surrounding free space due to destructive interference. We aim to build the first nanophotonic platform to realize the so-called 'selective radiance' proposed by theorists in recent years to improve the fidelity of photon storage in a quantum system. We could also try to form new states of quantum matter on an integrated photonic circuit to study few- and many-body physics with atom-photon interactions. We could cool the atoms closer to the absolute zero temperature to reach quantum degeneracy so that the trapped atoms could form a gas of strongly interacting Bose-Einstein condensate. We may also try synthesizing cold molecules from the trapped atoms with the enhanced radiative coupling from the microring resonator."
This work was supported by the U.S. Air Force Office of Scientific Research (Grant No. FA9550-22-1-0031) and the National Science Foundation (Grant No. PHY-1848316 and ECCS-2134931). This work was published with support from the Purdue University Libraries Open Access Publishing Fund. Quantum science and engineering is one of four dimensions within Purdue Computes, a major initiative that enables the university to advance to the forefront with unparalled excellence at scale.
About the Department of Physics and Astronomy at Purdue University
Purdue's Department of Physics and Astronomy has a rich and long history dating back to 1904. Our faculty and students are exploring nature at all length scales, from the subatomic to the macroscopic and everything in between. With an excellent and diverse community of faculty, postdocs and students who are pushing new scientific frontiers, we offer a dynamic learning environment, an inclusive research community and an engaging network of scholars.
Physics and Astronomy is one of the seven departments within the Purdue University College of Science. World-class research is performed in astrophysics, atomic and molecular optics, accelerator mass spectrometry, biophysics, condensed matter physics, quantum information science, and particle and nuclear physics. Our state-of-the-art facilities are in the Physics Building, but our researchers also engage in interdisciplinary work at Discovery Park District at Purdue, particularly the Birck Nanotechnology Center and the Bindley Bioscience Center. We also participate in global research including at the Large Hadron Collider at CERN, many national laboratories (such as Argonne National Laboratory, Brookhaven National Laboratory, Fermilab, Oak Ridge National Laboratory, the Stanford Linear Accelerator, etc.), the James Webb Space Telescope, and several observatories around the world.
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Contributors:
Chen-Lung Hung, associate professor of physics and astronomy at the Purdue University College of Science
Xinchao Zhou, graduate student at Purdue Physics and Astronomy
Written by Cheryl Pierce, Communications Specialist