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Illuminating Electron Dynamics: How Intense Lasers Reveal Liquid Secrets

An intense laser pulse (in red) hits a flow of water molecules, inducing an ultrafast dynamics of the electrons in the liquid. Credit: Joerg M. Harms / MPSD

Researchers employed intense laser fields to uncover unique electron dynamics in liquids, providing new insights into the high-harmonic spectrum and revealing the significance of the electron’s mean free path in determining photonA photon is a particle of light. It is the basic unit of light and other electromagnetic radiation, and is responsible for the electromagnetic force, one of the four fundamental forces of nature. Photons have no mass, but they do have energy and momentum. They travel at the speed of light in a vacuum, and can have different wavelengths, which correspond to different colors of light. Photons can also have different energies, which correspond to different frequencies of light.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>photon energy limits.

The behavior of electrons in liquids plays a big role in many chemical processes that are important for living things and the world in general. For example, slow electrons in liquid have the capacity to cause disruptions in the DNADNA, or deoxyribonucleic acid, is a molecule composed of two long strands of nucleotides that coil around each other to form a double helix. It is the hereditary material in humans and almost all other organisms that carries genetic instructions for development, functioning, growth, and reproduction. Nearly every cell in a person’s body has the same DNA. Most DNA is located in the cell nucleus (where it is called nuclear DNA), but a small amount of DNA can also be found in the mitochondria (where it is called mitochondrial DNA or mtDNA).” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>DNA strand.

But electron movements are extremely hard to capture because they take place within attoseconds: the realm of quintillionths of a second. Since advanced lasers now operate at these timescales, they can offer scientists glimpses of these ultrafast processes via a range of techniques.

An international team of researchers has now demonstrated that it is possible to probe electron dynamics in liquids using intense laser fields and to retrieve the electron’s mean free path — the average distance an electron can travel before colliding with another particle.

“We found that the mechanism by which liquids emit a particular light spectrum, known as the high-harmonic spectrum, is markedly different from the ones in other phases of matter like gases and solids,” said Zhong Yin from Tohoku University’s International Center for Synchrotron Radiation Innovation Smart (SRIS) and co-first author of the paper. “Our findings open the door to a deeper understanding of ultrafast dynamics in liquids.”

Details of the group’s research were published on September 28, 2023, in the journal Nature PhysicsAs the name implies, Nature Physics is a peer-reviewed, scientific journal covering physics and is published by Nature Research. It was first published in October 2005 and its monthly coverage includes articles, letters, reviews, research highlights, news and views, commentaries, book reviews, and correspondence.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Nature Physics.

The High-Harmonic Generation Technique

Using intense laser fields to generate high-energy photons, a phenomenon known as high-harmonic generation (HHG), is a widespread technique used in many different areas of science, for instance for probing electronic motion in materials, or tracking chemical reactions in time. HHG has been studied extensively in gases and more recently in crystals, but much less is known about liquids.

The team of researchers, which also included scientists from the Max Planck Institute for the Structure and Dynamics of Matter (MPSD) in Hamburg and ETH Zurich, reported on the unique behavior of liquids when irradiated by intense lasers. Until now, almost nothing is known about these light-induced processes in liquids, which surround us everywhere and are present in every chemical reaction. In contrast, scientists have made significant strides in recent years in exploring the behavior of solids under irradiation.

Therefore, the experimental team at ETH Zurich developed a unique apparatus to specifically study the interaction of liquids with intense lasers. The researchers discovered a distinctive behavior where the maximum photon energy obtained through HHG in liquids was independent of the laser’s wavelength. What, then, was the responsible factor?

Uncovering the Photon Energy Ceiling

Setting out to answer this question, the scientists identified a connection that had not been uncovered so far.

“The distance an electron can travel in the liquid before colliding with another particle is the crucial factor that imposes a ceiling on the photon energy,” said MPSD researcher Nicolas Tancogne-Dejean, a co-author of the study. “We were able to retrieve this quantity — known as the effective electron mean free path — from the experimental data thanks to a specifically developed analytical model which accounts for the scattering of the electrons.”

By combining experimental and theoretical results in their study of HHG in liquids, the scientists not only pinpointed the key factor that determines the maximum photo energy but also provide an intuitive model to elucidate the fundamental mechanism.

“Measuring the effective mean free path of the electrons is very challenging in the low kinetic energy region, as was done in this study, added Yin. “Ultimately, our collaborative effort establishes HHG as a new spectroscopical tool to study liquids and is therefore an important stepping stone in the quest to understand the dynamics of electrons in liquids.”

The research was a continuation of Yin’s previous work.

Reference: “High-harmonic spectroscopy of low-energy electron-scattering dynamics in liquids” by Angana Mondal, Ofer Neufeld, Zhong Yin, Zahra Nourbakhsh, Vít Svoboda, Angel Rubio, Nicolas Tancogne-Dejean and Hans Jakob Wörner, 28 September 2023, Nature Physics.
DOI: 10.1038/s41567-023-02214-0

Source: SciTechDaily