Liquids in narrow spaces

Effect of hard-sphere fluid confinementon pair correlations represented byexperimental (top) and theoretical (bottom) anisotropic structure factors. Channel widths increase from left to right.
Effect of hard-sphere fluid confinementon pair correlations represented byexperimental (top) and theoretical (bottom) anisotropic structure factors. Channel widths increase from left to right.

How does spatial confinement affect the microscopic structure of liquids?

This is a question which is receiving increasing attention from condensed matter physicists. Liquids are characterized by a short-ranged, so-called local structure, and it has been predicted theoretically about 25 years ago that confinement induces anisotropy in the local structure, and hence many properties, of liquids. However, this prediction had not been experimentally verified previously. Here, we have combined x-ray scattering experiments from colloid-filled nanofluidic channel arrays, a technique developed at PSI, with a state-of-the-art inhomogeneous liquid-state theory, to provide the first experimental verification of the theoretically predicted anisotropic local structure of confined liquids. The simultaneous experimental and theoretical description of confined liquids at this level allows accurate studies of the interaction mechanisms in liquids under spatial confinement.

Facility: SLS
Reference
Anisotropic Pair Correlations and Structure Factors of Confined Hard-Sphere Fluids: An Experimental and Theoretical Study
K. Nygard et al.
Phys Rev. Lett. 108, 037802 (2012) / DOI: 10.1103/PhysRevLett.108.037802
Contact
Dr. Kim Nygard
University of Gothenburg, Sweden
Email: kim.nygard@chem.gu.se

Prof. Dr. Friso van der Veen
Swiss Light Source at Paul Scherrer Institut
Phone: +41 56 310 5118
Email: friso.vanderveen@psi.ch