MIT physicists have developed a new technique to position atoms at unprecedentedly close distances of just 50 nanometers, enhancing magnetic interactions by a thousandfold. This breakthrough allows for the observation of new quantum phenomena, such as synchronized oscillations and thermalization between atomic layers, opening new avenues for the development of quantum materials and computing.
MIT physicists developed a technique to arrange atoms (represented as spheres with arrows) in much closer proximity than previously possible, down to 50 nanometers. The group plans to use the method to manipulate atoms into configurations that could generate the first purely magnetic quantum gate — a key building block for a new type of quantum computer. In this image, the magnetic interaction is represented by the colorful lines.
(Source: Courtesy of the researchers; MIT News)
Proximity is key for many quantum phenomena, as interactions between atoms are stronger when the particles are close. In many quantum simulators, scientists arrange atoms as close together as possible to explore exotic states of matter and build new quantum materials.
They typically do this by cooling the atoms to a stand-still, then using laser light to position the particles as close as 500 nanometers apart — a limit that is set by the wavelength of light. Now, MIT physicists have developed a technique that allows them to arrange atoms in much closer proximity, down to a mere 50 nanometers. For context, a red blood cell is about 1,000 nanometers wide.
Gallery
The physicists demonstrated the new approach in experiments with dysprosium, which is the most magnetic atom in nature. They used the new approach to manipulate two layers of dysprosium atoms, and positioned the layers precisely 50 nanometers apart. At this extreme proximity, the magnetic interactions were 1,000 times stronger than if the layers were separated by 500 nanometers.
What’s more, the scientists were able to measure two new effects caused by the atoms’ proximity. Their enhanced magnetic forces caused “thermalization,” or the transfer of heat from one layer to another, as well as synchronized oscillations between layers. These effects petered out as the layers were spaced farther apart.
“We have gone from positioning atoms from 500 nanometers to 50 nanometers apart, and there is a lot you can do with this,” says Wolfgang Ketterle, the John D. MacArthur Professor of Physics at MIT. “At 50 nanometers, the behavior of atoms is so much different that we’re really entering a new regime here.”
Ketterle and his colleagues say the new approach can be applied to many other atoms to study quantum phenomena. For their part, the group plans to use the technique to manipulate atoms into configurations that could generate the first purely magnetic quantum gate — a key building block for a new type of quantum computer.
The team has published their results today in the journal Science. The study’s co-authors include lead author and physics graduate student Li Du, along with Pierre Barral, Michael Cantara, Julius de Hond, and Yu-Kun Lu — all members of the MIT-Harvard Center for Ultracold Atoms, the Department of Physics, and the Research Laboratory of Electronics at MIT.
Conventional techniques stop at 500 nanometers, limited not by the atoms but by the wavelength of light. We have found now a new trick with light where we can break through that limit.
Wolfgang Ketterle, Professor of Physics at MIT
Peaks and Valleys
To manipulate and arrange atoms, physicists typically first cool a cloud of atoms to temperatures approaching absolute zero, then use a system of laser beams to corral the atoms into an optical trap.
Laser light is an electromagnetic wave with a specific wavelength (the distance between maxima of the electric field) and frequency. The wavelength limits the smallest pattern into which light can be shaped to typically 500 nanometers, the so-called optical resolution limit. Since atoms are attracted by laser light of certain frequencies, atoms will be positioned at the points of peak laser intensity. For this reason, existing techniques have been limited in how close they can position atomic particles, and could not be used to explore phenomena that happen at much shorter distances.
“Conventional techniques stop at 500 nanometers, limited not by the atoms but by the wavelength of light,” Ketterle explains. “We have found now a new trick with light where we can break through that limit.”
The team’s new approach, like current techniques, starts by cooling a cloud of atoms — in this case, to about 1 microkelvin, just a hair above absolute zero — at which point, the atoms come to a near-standstill. Physicists can then use lasers to move the frozen particles into desired configurations.
Then, Du and his collaborators worked with two laser beams, each with a different frequency, or color, and circular polarization, or direction of the laser’s electric field. When the two beams travel through a super-cooled cloud of atoms, the atoms can orient their spin in opposite directions, following either of the two lasers’ polarization. The result is that the beams produce two groups of the same atoms, only with opposite spins.
Date: 08.12.2025
Naturally, we always handle your personal data responsibly. Any personal data we receive from you is processed in accordance with applicable data protection legislation. For detailed information please see our privacy policy.
Consent to the use of data for promotional purposes
I hereby consent to Vogel Communications Group GmbH & Co. KG, Max-Planck-Str. 7-9, 97082 Würzburg including any affiliated companies according to §§ 15 et seq. AktG (hereafter: Vogel Communications Group) using my e-mail address to send editorial newsletters. A list of all affiliated companies can be found here
Newsletter content may include all products and services of any companies mentioned above, including for example specialist journals and books, events and fairs as well as event-related products and services, print and digital media offers and services such as additional (editorial) newsletters, raffles, lead campaigns, market research both online and offline, specialist webportals and e-learning offers. In case my personal telephone number has also been collected, it may be used for offers of aforementioned products, for services of the companies mentioned above, and market research purposes.
Additionally, my consent also includes the processing of my email address and telephone number for data matching for marketing purposes with select advertising partners such as LinkedIn, Google, and Meta. For this, Vogel Communications Group may transmit said data in hashed form to the advertising partners who then use said data to determine whether I am also a member of the mentioned advertising partner portals. Vogel Communications Group uses this feature for the purposes of re-targeting (up-selling, cross-selling, and customer loyalty), generating so-called look-alike audiences for acquisition of new customers, and as basis for exclusion for on-going advertising campaigns. Further information can be found in section “data matching for marketing purposes”.
In case I access protected data on Internet portals of Vogel Communications Group including any affiliated companies according to §§ 15 et seq. AktG, I need to provide further data in order to register for the access to such content. In return for this free access to editorial content, my data may be used in accordance with this consent for the purposes stated here. This does not apply to data matching for marketing purposes.
Right of revocation
I understand that I can revoke my consent at will. My revocation does not change the lawfulness of data processing that was conducted based on my consent leading up to my revocation. One option to declare my revocation is to use the contact form found at https://contact.vogel.de. In case I no longer wish to receive certain newsletters, I have subscribed to, I can also click on the unsubscribe link included at the end of a newsletter. Further information regarding my right of revocation and the implementation of it as well as the consequences of my revocation can be found in the data protection declaration, section editorial newsletter.
Each laser beam formed a standing wave, a periodic pattern of electric field intensity with a spatial period of 500 nanometers. Due to their different polarizations, each standing wave attracted and corralled one of two groups of atoms, depending on their spin. The lasers could be overlaid and tuned such that the distance between their respective peaks is as small as 50 nanometers, meaning that the atoms gravitating to each respective laser’s peaks would be separated by the same 50 nanometers.
But in order for this to happen, the lasers would have to be extremely stable and immune to all external noise, such as from shaking or even breathing on the experiment. The team realized they could stabilize both lasers by directing them through an optical fiber, which served to lock the light beams in place in relation to each other.
“The idea of sending both beams through the optical fiber meant the whole machine could shake violently, but the two laser beams stayed absolutely stable with respect to each others,” Du says.
As a first test of their new technique, the team used atoms of dysprosium — a rare-earth metal that is one of the strongest magnetic elements in the periodic table, particularly at ultracold temperatures. However, at the scale of atoms, the element’s magnetic interactions are relatively weak at distances of even 500 nanometers. As with common refrigerator magnets, the magnetic attraction between atoms increases with proximity, and the scientists suspected that if their new technique could space dysprosium atoms as close as 50 nanometers apart, they might observe the emergence of otherwise weak interactions between the magnetic atoms.
“We could suddenly have magnetic interactions, which used to be almost negligible but now are really strong,” Ketterle says.
The team applied their technique to dysprosium, first super-cooling the atoms, then passing two lasers through to split the atoms into two spin groups, or layers. They then directed the lasers through an optical fiber to stabilize them, and found that indeed, the two layers of dysprosium atoms gravitated to their respective laser peaks, which in effect separated the layers of atoms by 50 nanometers — the closest distance that any ultracold atom experiment has been able to achieve.
At this extremely close proximity, the atoms’ natural magnetic interactions were significantly enhanced, and were 1,000 times stronger than if they were positioned 500 nanometers apart. The team observed that these interactions resulted in two novel quantum phenomena: collective oscillation, in which one layer’s vibrations caused the other layer to vibrate in sync; and thermalization, in which one layer transferred heat to the other, purely through magnetic fluctuations in the atoms.
“Until now, heat between atoms could only by exchanged when they were in the same physical space and could collide,” Du notes. “Now we have seen atomic layers, separated by vacuum, and they exchange heat via fluctuating magnetic fields.”
The team’s results introduce a new technique that can be used to position many types of atom in close proximity. They also show that atoms, placed close enough together, can exhibit interesting quantum phenomena, that could be harnessed to build new quantum materials, and potentially, magnetically-driven atomic systems for quantum computers.
“We are really bringing super-resolution methods to the field, and it will become a general tool for doing quantum simulations,” Ketterle says. “There are many variants possible, which we are working on.”
Original Article: Atomic physics on a 50 nm scale: Realization of a bilayer system of dipolar atoms; Science; DOI:10.1126/science.adh3023
:quality(80)/p7i.vogel.de/wcms/06/a1/06a11f1d752afb35854aa9e1afb62e98/0129209625v2.jpeg "“Unsinkable\" metal tube made from chemically-etched aluminum floats in distilled water at the lab of University of Rochester professor Chunlei Guo. (Source: J. Adam Fenster / University of Rochester)")
:quality(80)/p7i.vogel.de/wcms/6d/df/6ddf023361ec7f8fbfb6c56521577960/0129056554v2.jpeg "The evolution of carburization (depicted by the spheres) under kinetic control (illustrated by the surface contours). The molecular beams represent gas evolution under synthesis conditions while the fiery sphere highlights the formation of the pure tungsten semi-carbide phase with additional molecular beams at the top to illustrate its catalytic performance. (Source: Sinhara M. H. D. Perera)")
:quality(80)/p7i.vogel.de/wcms/26/3d/263d97f8f2797267ecf2781b56882758/0129056451v1.jpeg "A study by the Complexity Science Hub finds that AI systems are already involved in nearly one-third of newly written software code, with rapid adoption in the United States and Europe and measurable productivity gains mainly for experienced developers. (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/63/0c/630cf9ab0cafdcdd9b33802d53c5b943/0128938770v1.jpeg "A microscopic close-up of the bubbles in foam, whose movements mathematically mirror the process of deep learning, used to train modern AI systems. (Source: Crocker Lab)")
:quality(80)/p7i.vogel.de/wcms/21/03/21030cc2541c455da0769decca8d1f82/0129146048v2.jpeg "Vyon porous plastics from Porvair Sciences are the perfect material for filtration applications in the healthcare and medical device market. (Source: Porvair Sciences)")
:quality(80)/p7i.vogel.de/wcms/bd/aa/bdaae5b9d381e2471ab37f479ad43d79/0129143884v2.jpeg "The Solvent Line Monitor from Testa Analytical is a true plug-and-play addition to any HPLC system designed to detect when one or more of its pump solvent reservoirs are empty and automatically shut-off the system. (Source: Testa Analytical)")
:quality(80)/p7i.vogel.de/wcms/8f/66/8f66b8acbb3037ca8e6b320bcad1c817/0129118043v2.jpeg "The Plasmaquant 9200 series is ideal for applications in research, trace analysis and quality control. (Source: Analytik Jena )")
:quality(80)/p7i.vogel.de/wcms/66/82/66825163ab842baded640db1a484e729/0129117548v2.jpeg "Biotech Fluidics has announced the Smartsaver solvent recycling unit which is designed to recover up to 90 % of your mobile phase by redirection of the pure solvent to the solvent reservoir during isocratic HPLC. (Source: Biotech Fluidics )")
:quality(80)/p7i.vogel.de/wcms/90/f8/90f8c3152a59205a7cac1cc182eb186b/0129209634v2.jpeg "Nitrate in drinking water linked to increased dementia risk while nitrate from vegetables is linked to a lower risk, researchers find . (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/53/ac/53acd3796c0d43ad0f7cfd80dd7ab82e/0129209615v1.jpeg "Prenatal exposure to NO2, black carbon, and PM2.5 may reduce recognition memory in newborns, with effects more pronounced in boys than in girls. (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/a3/cd/a3cdc440f6f0f426b85042082678018f/0129165252v2.jpeg "People exposed to wildfire smoke have a higher risk of suffering a stroke, according to research published in the European Heart Journal recently. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/6c/15/6c15f7685b6076b906f2d572f6c71bb8/0129103298v2.jpeg "Although only 2 % of U.S. homes rely on wood as their primary heating source, residential wood burning accounts for more than one-fifth of Americans’ wintertime exposure to outdoor fine particulate matter (PM2.5), the new study found. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/d1/3c/d13c2ad34af600dbd360c0bb0990b922/0129045715v2.jpeg "Replacing animal products with plant-based foods helps reduce the risk of heart disease and type 2 diabetes, finds a new review by the Physicians Committee for Responsible Medicine. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/e1/b3/e1b3e26d03101ba93b76b304da150c9a/0129025388v2.jpeg "The research reanalyzed data from a seminal clinical trial, led by US National Institutes of Health veteran Dr Kevin Hall, which first exposed how eating exclusively UPFs results in excessive calorie consumption and weight gain. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/75/db/75db8afe45607bee750df705e22b60e9/0128938816v1.jpeg "A new academic review suggests that bamboo shoots could offer significant health benefits, including improved blood sugar control, gut health and antioxidant activity. (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/85/42/85423f3382c25d1ae0ac5645e969cd36/0128898289v2.jpeg "Dr Arya Gopinath Madathil Pulikkal (left) and Asst Prof Andy Tay (right) in front of a small greenhouse containing Choy Sum plants. (Source: NUS)")
:quality(80)/p7i.vogel.de/wcms/f1/ea/f1eac0379480f4aa25ab2db9e0a396ed/0129209654v2.jpeg "Roe deer in study plot (Source: Walter Di Nicola)")
:quality(80)/p7i.vogel.de/wcms/34/a4/34a44fab2ba6af4b5f7cb8c3ecfc6362/0129207768v1.jpeg "AI generated image of the New Zealand cave (Source: P Scofield, Canterbury Museum)")
:quality(80)/p7i.vogel.de/wcms/a4/12/a412474313fc7d83bc51a4b99ef0af73/0129189645v2.jpeg "Around age 35, men’s risk for cardiovascular risk began to rise faster and stayed higher through midlife. (Source: Pixabay)")
:quality(80)/images.vogel.de/vogelonline/bdb/1710600/1710675/original.jpg "Discover how to set yourself up for success when performing balance-based density determination of solids such as jewelry and precious metals. (Mettler Toledo)")
:quality(80)/images.vogel.de/vogelonline/bdb/1682500/1682579/original.jpg "The new XPR Analytical balance redesigned to meet the needs of laboratory technicians of working fast and lean. (Mettler Toledo)")
:quality(80)/images.vogel.de/vogelonline/bdb/1677000/1677080/original.jpg "Enhance your weighing accuracy, comfort and productivity with the redesigned XPR Analytical balance. (Mettler Toledo)")
:quality(80)/p7i.vogel.de/wcms/b5/62/b562078e731ae0d3361e2c9ee684d12f/0118262054.jpeg "MIT physicists developed a technique to arrange atoms (represented as spheres with arrows) in much closer proximity than previously possible, down to 50 nanometers. The group plans to use the method to manipulate atoms into configurations that could generate the first purely magnetic quantum gate — a key building block for a new type of quantum computer. In this image, the magnetic interaction is represented by the colorful lines.(Source: Courtesy of the researchers; MIT News)")
:quality(80)/p7i.vogel.de/wcms/bd/42/bd42e9ea43276634f01846be5ec8fdef/0118262056.jpeg "Graduate students Li Du, left, and Yu-Kun Lu adjust the control electronics of the laser systems.(Source: Courtesy of the researchers)")
:quality(80)/p7i.vogel.de/wcms/1b/20/1b2027d60d30e78b2ae137b13707e95f/0118262055.jpeg "Lasers of different colors are used for cooling and capturing dysprosium atoms.(Source: Pierre Barral/ Courtesy of the researchers)")
:quality(80)/p7i.vogel.de/wcms/9f/9f/9f9f4f0042477ae7547a3b2fb9783f4a/0117970180.jpeg "Resource-efficient multi-photon processor based on an optical fiber loop. (Source: Marco Di Vita)")
:quality(80)/p7i.vogel.de/wcms/51/0e/510e0827dcf7d230d6f5bbce7c889d8b/0122804903v1.jpeg "By monitoring how giant Rydberg atoms interact with heat in their environment, Noah Schlossberger and colleagues can measure temperature with remarkable accuracy. (Source: R. Jacobson/ Nist)")
:quality(80)/p7i.vogel.de/wcms/32/ae/32ae11ef4154e0a95f766875fd10ad47/0124884486v2.jpeg "An intercrystal formed by overlaying twisted graphene on hexagonal boron nitride. (Source: Andrei Lab/ Rutgers University)")