Paul Corkum Google Scholar Jun 2026
One of Corkum's most significant contributions to the field of laser-matter interactions is his work on high-harmonic generation (HHG). In the 1990s, Corkum, along with other researchers, discovered that when a strong laser pulse interacts with a gas, it can generate high-harmonic radiation. This phenomenon occurs when the laser field ionizes the gas, creating a burst of electrons that then recombine with their parent ions, emitting high-energy photons in the process.
These numbers place Corkum in the upper echelon of active physicists globally. For context, an h-index above 100 is considered the hallmark of a scientific giant. Corkum’s profile shows that thousands of researchers across optics, chemistry, and condensed matter physics rely on his work daily.
Based on his profile, the following works represent his most significant contributions to the field: paul corkum google scholar
How does Paul Corkum stack up against his peers using Google Scholar data?
Corkum’s work on High Harmonic Generation (HHG) is the practical engine of attosecond science. His papers explaining the "recollision" process are the most frequently downloaded and cited items on his profile. One of Corkum's most significant contributions to the
By setting up a for "Paul Corkum," you can receive daily or weekly updates whenever a new paper cites his work. This is a powerful way to stay at the forefront of ultrafast science. Simply:
Before Corkum’s intervention, the physics of strong-field ionization was murky. This paper introduced a simple, intuitive model that described how an electron tunnels out of an atom and is then accelerated by a laser field. It has been cited tens of thousands of times. These numbers place Corkum in the upper echelon
Dr. Paul Corkum is a Professor at the University of Ottawa and a Principal Research Officer at the National Research Council of Canada (NRC). He is best known for the "re-collision model," which explains how high-harmonic generation works. This discovery essentially gave scientists a "camera" fast enough to capture the movement of electrons, which occur on the attosecond scale (one quintillionth of a second). Navigating the Google Scholar Profile
Following these co-authors from Corkum’s page allows you to map the entire social network of ultrafast science.
Citations: ~5,673.
