Researchers have developed a new technique combining vertical small-angle X-ray scattering and optical microscopy to observe the real-time self-assembly of nanoparticles at liquid interfaces, offering high spatial and temporal resolution.
Image Credit: Mariya Kovalenko/Condensed Matter Physics DOI: 10.5488/CMP.27.23702
With their tunable properties, nanoparticles can form extremely complicated structures like superlattices and supercrystals when organized precisely. These assembled structures often display unique physical characteristics, making them highly valuable in nanoscience and materials engineering.
Conventional analytical techniques such as the Langmuir-Blodgett method and grazing-incidence small-angle X-ray scattering (SAXS) have advanced our understanding of these assemblies. However, they often require highly specialized setups and aren’t well-suited for in situ monitoring under standard lab conditions.
This study, published in Nano Trends, addresses that limitation, introducing an accessible, versatile setup aimed at tracking the dynamic behaviour of nanoparticles during key stages of self-assembly, particularly at liquid interfaces where processes like solvent evaporation, convection, and nucleation play a critical role.
A New Experimental Setup
The researchers designed a custom setup at the P10 beamline of PETRA III, incorporating vertical SAXS geometry. An X-ray beam is directed vertically downward onto a sample of a liquid subphase, such as toluene, with nanoparticles deposited on the surface. This vertical geometry enables scattering data to be collected within a specific volume at the liquid interface, delivering micrometre-scale spatial resolution.
The team used monodisperse gold nanoparticles coated with poly(ethylene glycol) thiol (PSSH) ligands, with an average diameter of around 40 nm. To initiate self-assembly, controlled volumes of nanoparticle solution were added to the liquid surface, and solvent evaporation drove the assembly.
To complement the structural insights from the vertical SAXS, the setup also included optical microscopy, allowing researchers to visualize the assembly process directly. This dual approach offered nanoscale structural data and dynamic morphological imaging in real time.
Capturing the Assembly Process in Real Time
The SAXS data provided a detailed view of how the nanoparticles evolved from a dispersed state into well-ordered superlattices. Early-stage scattering profiles showed isolated, monodisperse particles. As evaporation progressed, distinct Bragg peaks emerged, indicating the formation of hexagonally packed superlattices.
These peaks evolved in intensity and shape, allowing researchers to track the progression of crystallization and densification. From the scattering profiles, parameters such as lattice spacing and domain size were extracted, offering precise insight into the emerging structure.
Optical microscopy supported these findings by revealing heterogeneous nucleation sites and the growth of crystallites. It also captured the influence of convective flows and surface stress, which affected how crystals moved, rearranged, and grew.
Together, the two techniques made it possible to identify distinct stages of assembly, from initial nucleation through to large-scale ordering. The presence of fluid turbulence, in particular, significantly impacted the size and uniformity of the resulting supercrystals.
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Advantages of the Vertical SAXS Approach
The vertical SAXS geometry provided several advantages over traditional grazing-incidence techniques. It allowed researchers to probe not just the surface but a three-dimensional volume at the interface, allowing a more complete picture of the self-assembly process.
The vertical setup enabled real-time, spatially resolved data collection under ambient conditions by eliminating complex alignment steps and sampling limitations associated with grazing geometries.
The study highlighted the potential of this method for examining more complex systems in the future. Potentially even including core-shell nanoparticles and nanostructures with diverse ligand chemistries. The technique offers a flexible platform for exploring different environmental and evaporation conditions.
Implications For Nanoscience
This research demonstrates that combining vertical SAXS with optical microscopy provides a powerful, in situ method for studying nanoparticle self-assembly at liquid interfaces. The approach enables detailed tracking of how nanoparticles transition from dispersed states to dense, crystalline superlattices under conditions that closely resemble real-world environments.
These insights are key for designing controlled assembly processes and could support the fabrication of functional nanomaterials with tailored optical, electronic, or mechanical properties.
The technique’s adaptability also makes it suitable for broader applications in nanoscience, nanoengineering, and soft matter research, particularly where liquid–interface phenomena are central to material behaviour.
Journal Reference
Lehmkühler F., Westermeier F., et al. (2025). Monitoring nanoparticle self-assembly on liquid subphases in situ in a vertical scattering geometry. Nano Trends 11, 100132. DOI: 10.1016/j.nwnano.2025.100132, https://www.sciencedirect.com/science/article/pii/S2666978125000613