Nanocrystals, 20 to 100 in diameter, exhibit unique size dependent electronic, optical, and magnetic properties. [1,2] Assembly with spatial control on various length scales presents a critical challenge in nanocrystal processing. Although translational order on the nanometer-and submicrometer-scale is readily achieved in self-organized superlattices, [3] some applications such as photonics, separations, catalysis, and sensors require organization into more spatially complex macroporous structures where the lattice parameter is on the order of a micrometer or more. Herein, we show the formation of ordered macroporous thin films of nanocrystals by dispersion evaporation of a volatile solvent in a relatively humid environment. Water droplets condense on the evaporating dispersion and self-organize into an ordered array that templates the deposition of the hydrophobic nanocrystals. Upon complete evaporation, an ordered macroporous thin film made of close-packed nanocrystals remains. Interfacially active nanocrystals that adsorb at the solvent±water interface prevent water droplet coalescence and preserve the structure of the macroporous film during drying. The ligands and the nanocrystal cores may be chosen independently to form a wide variety of novel porous films. Macroporous materials are typically fabricated in a threestep process of template formation, matrix infusion, and template disintegration. Prefabricated templates of colloidal crystals, [4] emulsions, [5] or microemulsions [6] are infused with a material of choice, such as metals, [7] semiconductors, [8] inorganics, [4] and polymers, [9] and then subsequently removed to reveal arrays of holes. In some cases, nanocrystals have been infused into colloidal crystal templates. [7,8] Often the collapse, or loss of shape, of the templated media occurs during thermally or chemically harsh template removal steps. The evaporative self-assembly of macroporous nanocrystal films demonstrated here represents a single-step method to achieve films with ordered micrometer-size holes. The nanocrystals in the films remain as distinct individual particles with the potential to retain their size-dependent properties. Figure 1 shows scanning electron microscopy (SEM) images of macroporous gold nanocrystal thin films consisting of a continuous network of perfluoropolyether thiol-coated (PFPE-SH, (F(CF(CF 3 )CF 2 O) 3 CF(CF 3 )CONH(CH 2 ) 2 SH)) 5 nm diameter gold nanocrystals. The self-organized porous array of submicrometer-size holes extends over thousands of square micrometers of substrate. The films in Figure 1 were formed by drop casting the PFPE-capped Au nanocrystals in 1,1,2-trichlorotrifluoroethane (Freon) under ambient conditions at 60 % relative humidity. The Freon evaporates quickly due to its high vapor pressure, leading to a significant temperature drop and water condensation at the air±liquid interface. The water droplets grow by molecular condensation until they reach a self-limiting narrow size distribution [10] and ultimately organize at high surface coverage...
