Tag Archives: Mark Brongersma

Using sound to sculpt light for better displays and imaging

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A July 31, 2025 Stanford University news release (also on EurekAlert) describes a nanodevice that can sculpt light, Note: Links have been removed,

Light can behave in very unexpected ways when you squeeze it into small spaces. In a new paper in the journal Science, Mark Brongersma, a professor of materials science and engineering at Stanford University, and doctoral candidate Skyler Selvin describe the novel way they have used sound to manipulate light that has been confined to gaps only a few nanometers across – allowing the researchers exquisite control over the color and intensity of light mechanically.

The findings could have broad implications in fields ranging from computer and virtual reality displays to 3D holographic imagery, optical communications, and even new ultrafast, light-based neural networks.

The new device is not the first to manipulate light with sound, but it is smaller and potentially more practical and powerful than conventional methods. From an engineering standpoint, acoustic waves are attractive because they can vibrate very fast, billions of times per second. Unfortunately, the atomic displacements produced by acoustic waves are extremely small – about 1,000 times smaller than the wavelength of light. Thus, acousto-optical devices have had to be larger and thicker to amplify sound’s tiny effect – too big for today’s nanoscale world.

“In optics, big equals slow,” Brongersma said. “So, this device’s small scale makes it very fast.”

Simplicity from the start

The new device is deceptively simple. A thin gold mirror is coated with an ultrathin layer of a rubbery silicone-based polymer only a few nanometers thick. The research team could fabricate the silicone layer to desired thicknesses – anywhere between 2 and 10 nanometers. For comparison, the wavelength of light is almost 500 nanometers tip to tail.

The researchers then deposit an array of 100-nanometer gold nanoparticles across the silicone. The nanoparticles float like golden beach balls on an ocean of polymer atop a mirrored sea floor. Light is gathered by the nanoparticles and mirror and focused into the silicone between – shrinking the light to the nanoscale.

To the side, they attach a special kind of ultrasound speaker – an interdigitated transducer, IDT – that sends high-frequency sound waves rippling across the film at nearly a billion times a second. The high‑frequency sound waves (surface acoustic waves, SAWs) surf along the surface of the gold mirror beneath the nanoparticles. The elastic polymer acts like a spring, stretching and compressing as the nanoparticles bob up and down as the sound waves course by.

The researchers then shine light into the system. The light gets squeezed into the oscillating gaps between the gold nanoparticles and the gold film. The gaps change in size by the mere width of a few atoms, but it is enough to produce an outsized effect on the light.

The size of the gaps determines the color of the light resonating from each nanoparticle. The researchers can control the gaps by modulating the acoustic wave and therefore control the color and intensity of each particle.

“In this narrow gap, the light is squeezed so tightly that even the smallest movement significantly affects it,” Selvin said. “We are controlling the light with lengths on the nanometer scale, where typically millimeters have been required to modulate light acoustically.”

Starry, starry sky

When white light is shined from the side and the sound wave is turned on, the result is a series of flickering, multicolored nanoparticles against a black background, like stars twinkling in the night sky. Any light that does not strike a nanoparticle is bounced out of the field of view by the mirror, and only the light that is scattered by the particles is directed outward toward the human eye. Thus, the gold mirror appears black and each gold nanoparticle shines like a star.

The degree of optical modulation caught the researchers off guard. “I was rolling on the floor laughing,” Brongersma said of his reaction when Selvin showed him the results of his first experiments. “I thought it would be a very subtle effect, but I was amazed how much nanometer changes in distance can change the light scattering properties so dramatically.”

The exceptional tunability, small form factor, and efficiency of the new device could transform any number of commercial fields. One can imagine ultrathin video displays, ultra-fast optical communications based on acousto-optics’ high-frequency capabilities, or perhaps new holographic virtual reality headsets that are much smaller than the bulky displays of today, among other applications.

“When we can control the light so effectively and dynamically,” Brongersma said, “we can do everything with light that we could want – holography, beam steering, 3D displays – anything.”

Here’s a link to and a citation for the paper,

Acoustic wave modulation of gap plasmon cavities by Skyler P. Selvin, Majid Esfandyarpour, Anqi Ji, Yan Joe Lee, Colin Yule, Jung-Hwan Song, Mohammad Taghinejad and Mark L. Brongersma. Science 31 Jul 2025 Vol 389, Issue 6759 pp. 516-520 DOI: 10.1126/science.adv1728

This paper is behind a paywall.

The subhead ‘Starry, starry sky’ reminded me of a song by Don McLean, ‘Starry, Starry Night’, a lyrical tribute to Vincent van Gogh and his painting, ‘The Starry Night’. First, ‘Starry, starry sky’,

How the nanoparticles look with and without the surface acoustic wave (SAW) activation. Brongersma compared it to a starry night sky. | Selvin et al., Supplementary Movie 1 from “Acoustic wave modulation of gap plasmon cavities,” Science (2025), ©2025 AAAS; courtesy of the authors [downloaded from https://news.stanford.edu/stories/2025/07/nanoscale-device-control-light-sound-acoustic-waves-imaging-communications]

Next, ‘The Starry Night’,

By Vincent van Gogh – Google Arts & Culture — bgEuwDxel93-Pg, Public Domain, https://commons.wikimedia.org/w/index.php?curid=25498286

As for Don McLean’s song ‘Starry, Starry Night’, I leave that to you. In days gone by, I would have embedded a YouTube version of the song but the owners have turned that site into one long commercial occasionally interrupted by content.

US Air Force wants to merge classical and quantum physics

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The US Air Force wants to merge classical and quantum physics for practical purposes according to a May 5, 2014 news item on Azonano,

The Air Force Office of Scientific Research has selected the Harvard School of Engineering and Applied Sciences (SEAS) to lead a multidisciplinary effort that will merge research in classical and quantum physics and accelerate the development of advanced optical technologies.

Federico Capasso, Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering, will lead this Multidisciplinary University Research Initiative [MURI] with a world-class team of collaborators from Harvard, Columbia University, Purdue University, Stanford University, the University of Pennsylvania, Lund University, and the University of Southampton.

The grant is expected to advance physics and materials science in directions that could lead to very sophisticated lenses, communication technologies, quantum information devices, and imaging technologies.

“This is one of the world’s strongest possible teams,” said Capasso. “I am proud to lead this group of people, who are internationally renowned experts in their fields, and I believe we can really break new ground.”

A May 1, 2014 Harvard University School of Engineering and Applied Sciences news release, which originated the news item, provides a description of project focus: nanophotonics and metamaterials along with some details of Capasso’s work in these areas (Note: Links have been removed),

The premise of nanophotonics is that light can interact with matter in unusual ways when the material incorporates tiny metallic or dielectric features that are separated by a distance shorter than the wavelength of the light. Metamaterials are engineered materials that exploit these phenomena, producing strange effects, enabling light to bend unnaturally, twist into a vortex, or disappear entirely. Yet the fabrication of thick, or bulk, metamaterials—that manipulate light as it passes through the material—has proven very challenging.

Recent research by Capasso and others in the field has demonstrated that with the right device structure, the critical manipulations can actually be confined to the very surface of the material—what they have dubbed a “metasurface.” These metasurfaces can impart an instantaneous shift in the phase, amplitude, and polarization of light, effectively controlling optical properties on demand. Importantly, they can be created in the lab using fairly common fabrication techniques.

At Harvard, the research has produced devices like an extremely thin, flat lens, and a material that absorbs 99.75% of infrared light. But, so far, such devices have been built to order—brilliantly suited to a single task, but not tunable.

This project, however,is focused on the future (Note: Links have been removed),

“Can we make a rapidly configurable metasurface so that we can change it in real time and quickly? That’s really a visionary frontier,” said Capasso. “We want to go all the way from the fundamental physics to the material building blocks and then the actual devices, to arrive at some sort of system demonstration.”

The proposed research also goes further. A key thrust of the project involves combining nanophotonics with research in quantum photonics. By exploiting the quantum effects of luminescent atomic impurities in diamond, for example, physicists and engineers have shown that light can be captured, stored, manipulated, and emitted as a controlled stream of single photons. These types of devices are essential building blocks for the realization of secure quantum communication systems and quantum computers. By coupling these quantum systems with metasurfaces—creating so-called quantum metasurfaces—the team believes it is possible to achieve an unprecedented level of control over the emission of photons.

“Just 20 years ago, the notion that photons could be manipulated at the subwavelength scale was thought to be some exotic thing, far fetched and of very limited use,” said Capasso. “But basic research opens up new avenues. In hindsight we know that new discoveries tend to lead to other technology developments in unexpected ways.”

The research team includes experts in theoretical physics, metamaterials, nanophotonic circuitry, quantum devices, plasmonics, nanofabrication, and computational modeling. Co-principal investigator Marko Lončar is the Tiantsai Lin Professor of Electrical Engineering at Harvard SEAS. Co-PI Nanfang Yu, Ph.D. ’09, developed expertise in metasurfaces as a student in Capasso’s Harvard laboratory; he is now an assistant professor of applied physics at Columbia. Additional co-PIs include Alexandra Boltasseva and Vladimir Shalaev at Purdue, Mark Brongersma at Stanford, and Nader Engheta at the University of Pennsylvania. Lars Samuelson (Lund University) and Nikolay Zheludev (University of Southampton) will also participate.

The bulk of the funding will support talented graduate students at the lead institutions.

The project, titled “Active Metasurfaces for Advanced Wavefront Engineering and Waveguiding,” is among 24 planned MURI awards selected from 361 white papers and 88 detailed proposals evaluated by a panel of experts; each award is subject to successful negotiation. The anticipated amount of the Harvard-led grant is up to $6.5 million for three to five years.

For anyone who’s not familiar (that includes me, anyway) with MURI awards, there’s this from Wikipedia (Note: links have been removed),

Multidisciplinary University Research Initiative (MURI) is a basic research program sponsored by the US Department of Defense (DoD). Currently each MURI award is about $1.5 million a year for five years.

I gather that in addition to the Air Force, the Army and the Navy also award MURI funds.