Maximum Thermal Insulation by Nanoporous, Particulate Materials

Efficient thermal insulation is of high importance to decrease the overall power consumption for heating and cooling applications. Good thermal insulation materials possess a high degree of porosity typically, like foams or aerogels. The low density of such materials mainly drives this.
In this contribution, we use structurally well-defined hollow silica nanoparticles to elaborate the minimum thermal conductivity achievable with this sort of particulate material. The use of monodisperse hollow silica nanoparticles offers several benefits: precise adjustment of open and closed pore volume, the independent variation of the density, and control over particle contact points.
By adjusting the structural properties, we find a minimum thermal conductivity to be reached at ~ 35 mWm^-1K^-1 in air, whereas 7 mWm^-1K^-1 can be achieved in vacuum. Thus, tailor-made particle ensembles based on hollow silica nanoparticles represent a dispersion processable, breathable, and non-flammable alternative to common polymer foams.