Unravelling the multiscale surface mechanics of soft solids

The softer a material is, the more its mechanics are sensitive to interfaces. In soft gels, an elastic polymeric network is filled with free-flowing molecules. In theory, either of these components could dominate the material interfacial properties. In practice, current measurements cannot distinguish between the two, nor can they rule out material inhomogeneities, which could modulate the apparent properties of the interfaces. Here, we introduce an experimental approach that elucidates the interfacial mechanics of soft solids. Coupling quantum dots, controlled deformations, and precise confocal measurements, we fully separate the material inhomogeneities of a silicone gel from its true interfacial properties. We quantify a gradient in bulk elastic properties near the surface, with a characteristic length scale of about 20 {\mu}m. In addition, we observe a surface excess elasticity, whose associated gradient is unresolvable with light microscopy. The composition of the external medium has a strong affect on the observed value of the surface elasticity. Thus, we conclude that the surface elasticity of this silicone network is an interfacial property.