Tunable Nanoparticle Stripe Patterns at Inclined Surfaces

TL;DR

This study demonstrates how evaporation-driven nanoparticle patterning on inclined surfaces can be controlled by adjusting nanoparticle concentration and inclination, enabling tunable, periodic stripe formations for advanced surface patterning applications.

Contribution

First experimental demonstration of nanoparticle stripe patterns formed via stick-slip dynamics during evaporation on inclined surfaces, with tunable parameters for pattern control.

Findings

Stripe density varies sinusoidally with inclination angle.

Inter-stripe spacing remains nearly constant despite parameter changes.

Independent control over stripe spacing through nanoparticle or surfactant concentration.

Abstract

Periodic assemblies of nanoparticles are central to surface patterning, with applications in biosensing, energy conversion, and nanofabrication. Evaporation of colloidal droplets on substrates provides a simple yet effective route to achieve such assemblies. This work reports the first experimental demonstration of patterns formed through stick-slip dynamics of the three-phase contact line during evaporation of gold nanoparticle suspensions on inclined substrates. Variation in nanoparticle concentration and substrate inclination alter the balance of interfacial and gravitational forces, producing multiple stick-slip events that generate periodic stripes. Stripe density exhibits a sinusoidal dependence on inclination angle, while inter-stripe spacing remains nearly invariant. Independent control over inter-stripe spacing is achieved through adjustment of nanoparticle or surfactant concentration. These results highlight the complex interplay of gravitational and interfacial forces in directing periodic nanoparticle assembly and establish a versatile, programmable framework for surface patterning with tunable nano/microscale dimensions.