Mechanical stability enhancement by pore size and connectivity control in colloidal crystals by layer-by-layer growth of oxide

摘要

The present invention provides a method to control the degree of connectivity of the colloidal particles making up a colloidal crystal and, consequently, the pore size, filling fraction, mechanical stability and optical properties of the colloidal lattice, without disrupting its long range order and without the deleterious effects of lattice contraction induced cracking observed in conventional necking methods based on thermal sintering. The colloidal particles are connected to adjacent colloidal particles in the lattice by a homogeneous layer of uniform and controllable thickness of a metal oxide. This metal oxide layer is grown in a layer-by-layer process and is chemically bonded to the colloidal particle surface and serves to enhance the mechanical stability of the colloidal crystal in addition to acting to control the pore size or void volume between the colloidal particles in the lattice.