06/02/2026 La Fusion des nanoparticules

La fusion des nanoparticules est un domaine d’expertise qui a récemment été exploré pour sa capacité à créer des architectures nanométriques complexes. Des chercheurs ont démontré que des populations distinctes de nanoparticules polymères peuvent fusionner entre elles selon un contrôle purement cinétique, ouvrant la voie pour la manipulation nano-structurale des polymères. Cette approche illustre comment des mécanismes purement physiques peuvent suffire à orchestrer des architectures nanométriques complexes, sans recourir à une chimie sophistiquée de surface. 

Groupe Français d’Etudes et d’Applications des Polymères

A New Probe of Nanoparticle Melting

January 27, 2026• Physics 19, s18

The melting point of alkali-metal nanoparticles was determined with high accuracy by measuring the energy required to eject electrons from the particles.

V. Kresin/University of Southern California

Understanding nanoparticles is important in astrophysics and atmospheric physics and for applications like catalysts. These particles are tough to characterize, but now Vitaly Kresin of the University of Southern California and his colleagues have determined one elusive property with high accuracy. They inferred the melting point of sodium and potassium nanoparticles 7–9 nm in diameter with an accuracy of 1% [1]. They found that the melting point is about 100 K lower than in bulk samples, in agreement with less-precise data on other types of nanoparticles of this size and with theoretical predictions. The technique could potentially provide a new way to probe other properties of nanoparticles having a wide range of sizes.

Metal nanoparticles are known to melt at lower temperatures than bulk samples, but the theory needed to predict the melting point has significant uncertainties. Experiments also face various challenges, such as the tendency of electron microscopes to melt nanoparticles. Kresin and his colleagues suspected that the work function—the energy required to remove an electron from a surface or a nanoparticle—might show some notable changes when a nanoparticle melts, given the major structural rearrangements involved.

Their recently developed setup [2] uses a beam of temperature-controlled nanoparticles targeted by an adjustable-wavelength, monochromatic light source. When the photons eject electrons, the team detects the charged particles. For both sodium and potassium, the work function-versus-temperature data show a clear discontinuity and change in slope at the melting point.

The nanoparticles move so rapidly through the vacuum that they have no time to acquire impurities. Kresin says that this feature makes the technique ideal for studying the melting process in reactive metals, which are especially prone to contamination.

Correction (27 January 2026): Additional words have been added in the first paragraph to clarify that previous experiments did not include alkali-metal nanoparticles (like sodium or potassium) of this size. “Precision” has been changed to “accuracy” in the teaser.

–David Ehrenstein

David Ehrenstein is a Senior Editor for Physics Magazine.

References

1. A. O. Haridy et al., “Temperature-dependent photoionization thresholds of alkali-metal nanoparticles reveal thermal expansion and the melting transition,” Phys. Rev. B 113, L041404 (2026).
2. A. A. Sheekhoon et al., “Photoionization of temperature-controlled nanoparticles in a beam: Accurate and efficient determination of ionization energies and work functions,” Rev. Sci. Instrum. 96, 123705 (2025).