New laser technique images quantum world in a trillionth of a second

December 10, 2019

Ultrafast pulses of ultraviolet light in a gas jet are visible as blue dots on a phosphor screen (UBC).

For the first time, researchers have been able to record, frame-by-frame, how an electron interacts with certain atomic vibrations in a solid. The technique captures a process that commonly causes electrical resistance in materials while, in others, can cause the exact opposite—the absence of resistance, or superconductivity.

“The way electrons interact with each other and their microscopic environment determines the properties of all solids,” said MengXing Na, a University of British Columbia (UBC) PhD student and co-lead author of the study, published last week in Science. “Once we identify the dominant microscopic interactions that define a material’s properties, we can find ways to ‘turn up’ or ‘down’ the interaction to elicit useful electronic properties.”

Controlling these interactions is important for the technological exploitation of quantum materials, including superconductors, which are used in MRI machines, high-speed magnetic levitation trains, and could one day revolutionize how energy is transported.

At tiny scales, atoms in all solids vibrate constantly. Collisions between an electron and an atom can be seen as a ‘scattering’ event between the electron and the vibration, called a phonon. The scattering can cause the electron to change both its direction and its energy. Such electron-phonon interactions lie at the heart of many exotic phases of matter, where materials display unique properties.

With the support of the Gordon and Betty Moore Foundation, the team at UBC’s Stewart Blusson Quantum Matter Institute (SBQMI) developed a new extreme-ultraviolet laser source to enable a technique called time-resolved photoemission spectroscopy for visualizing electron scattering processes at ultrafast timescales.

“Using an ultrashort laser pulse, we excited individual electrons away from their usual equilibrium environment,” said Na. “Using a second laser pulse as an effective camera shutter, we captured how the electrons scatter with surrounding atoms on timescales faster than a trillionth of a second. Owing to the very high sensitivity of our setup, we were able to measure directly—for the first time—how the excited electrons interacted with a specific atomic vibration, or phonon.”

The researchers performed the experiment on graphite, a crystalline form of carbon and the parent compound of carbon nanotubes, Bucky balls and graphene. Carbon-based electronics is a growing industry, and the scattering processes that contribute to electrical resistance may limit their application in nanoelectronics.

The approach leverages a unique laser facility conceived by David Jones and Andrea Damascelli, and developed by co-lead author Arthur Mills, at the UBC-Moore Centre for Ultrafast Quantum Matter. The study was also supported by theoretical collaborations with the groups of Thomas Devereaux at Stanford University and Alexander Kemper at North Carolina State University.

“Thanks to recent advances in pulsed-laser sources, we’re only just beginning to visualize the dynamic properties of quantum materials,” said Jones, a professor with UBC’s SBQMI and department of Physics and Astronomy.

“By applying these pioneering techniques, we’re now poised to reveal the elusive mystery of high-temperature superconductivity and many other fascinating phenomena of quantum matter,” said Damascelli, scientific director of SBQMI.

The work was supported by the Gordon and Betty Moore Foundation’s EPiQS Initiative (Grant GBMF4779 to A.D. and D.J.J.), the Natural Sciences and Engineering Research Council, Canada Foundation for Innovation, the B.C. Knowledge Development Fund, and the Canada First Research Excellence Fund.


For more information, contact…

Chris Balma

balma@science.ubc.ca 604-822-5082
  • Quantum Physics
  • Physics and Astronomy

Musqueam First Nation land acknowledegement

We honour xwməθkwəy̓ əm (Musqueam) on whose ancestral, unceded territory UBC Vancouver is situated. UBC Science is committed to building meaningful relationships with Indigenous peoples so we can advance Reconciliation and ensure traditional ways of knowing enrich our teaching and research.

Learn more: Musqueam First Nation

Faculty of Science

Office of the Dean, Earth Sciences Building
2178–2207 Main Mall
Vancouver, BC Canada
V6T 1Z4
UBC Crest The official logo of the University of British Columbia. Urgent Message An exclamation mark in a speech bubble. Arrow An arrow indicating direction. Arrow in Circle An arrow indicating direction. A bookmark An ribbon to indicate a special marker. Calendar A calendar. Caret An arrowhead indicating direction. Time A clock. Chats Two speech clouds. External link An arrow pointing up and to the right. Facebook The logo for the Facebook social media service. A Facemask The medical facemask. Information The letter 'i' in a circle. Instagram The logo for the Instagram social media service. Linkedin The logo for the LinkedIn social media service. Lock, closed A closed padlock. Lock, open An open padlock. Location Pin A map location pin. Mail An envelope. Mask A protective face mask. Menu Three horizontal lines indicating a menu. Minus A minus sign. Money A money bill. Telephone An antique telephone. Plus A plus symbol indicating more or the ability to add. RSS Curved lines indicating information transfer. Search A magnifying glass. Arrow indicating share action A directional arrow. Spotify The logo for the Spotify music streaming service. Twitter The logo for the Twitter social media service. Youtube The logo for the YouTube video sharing service.