In a world first, scientists have filmed atoms in motion, capturing their thermal vibrations in real-time with stunning clarity.

The breakthrough, led by Yichao Zhang, an assistant professor at the University of Maryland’s Department of Materials Science and Engineering, reveals an entirely new kind of motion inside quantum materials that could reshape the future of ultrathin electronics and quantum devices.

Using a next-generation imaging method called electron ptychography, Zhang and her team captured the first microscopy images of moiré phasons, the elusive, coordinated vibrations that emerge in twisted two-dimensional (2D) materials. These subtle, heat-driven movements of atoms were previously invisible to researchers.

Sharper eyes, subtler motion

The technique achieved a resolution better than 15 picometers, making it sensitive enough to detect the minute blurring of individual atoms caused by thermal motion.

These vibrations, once only predicted by theory, are now visible, confirming long-held hypotheses about how heat travels through 2D materials and interacts with atomic-scale patterns.

At the heart of the discovery are moiré phasons, spatially localized vibrations formed when two atomic layers are twisted slightly against each other. They influence everything from thermal conductivity to superconductivity in next-generation devices—and until now, had never been imaged directly.

“This is like decoding a hidden language of atomic motion,” said Zhang. “Electron ptychography lets us see these subtle vibrations directly. Now we have a powerful new method to explore previously hidden physics, which will accelerate discoveries in two dimensional quantum materials.”

Paving the way for smarter quantum tech

This achievement marks the first time researchers have directly imaged how moiré phasons govern thermal vibrations in twisted 2D materials.

Two-dimensional materials, just a few atoms thick, have attracted intense interest for their potential in next-generation quantum and electronic devices due to their exotic physical properties.

However, understanding how heat moves through these ultra-thin structures remained limited by a lack of visualization tools.

Zhang’s method not only reveals atomic-scale motion with unprecedented clarity but also establishes electron ptychography as a new frontier in microscopy.

By capturing how atoms behave under thermal influence, the team has laid the groundwork for decoding complex behaviors like heat dissipation and quantum coherence at the nanoscale.

Zhang’s team now plans to investigate how thermal vibrations are affected by defects and interfaces, a key step toward designing materials with custom thermal, electronic, and optical properties.

That level of control could power advances in quantum computing, energy-efficient chips, and nanoscale sensors.

With this visual confirmation of moiré phasons in hand, scientists now have the tools to engineer quantum materials from the atomic level up, using not just structure, but motion itself, as a design principle.

The movement of atoms has now been documented in a study published on July 24 in Science.