Moreover, we have observed that when the conductivity of the solution is much increased, the layer deposited consisted of predominantly scattered nanospheres, which is consistent with dominant repulsive forces between them Selleck Tariquidar as a result of particle dipole interaction [31] and the dielectrophoretic force from the main field created by the needle tip and the bottom electrode. The detailed explanation on how the dielectrophoretic force on the particles stimulates the orderly deposition of the spheres requires

further work as particle alignment and enhancement of net electrostatic adhesion force have been described for xerographic applications [31]. Our work opens the way to investigate other electrode geometries and spatial and temporal dependence of the electric field to further improve deposition. To complete

the study on ordering quality, we have measured the optical reflectance of the crystals by infrared spectroscopy (see Figure 9). Spheres pack on an ordered combination of face-centered cube (FCC) and hexagonal close-packed (HCP) lattice, as observed from SEM images (Figure 6). The PI3K inhibitor photonic band structure of an FCC lattice of dielectric nanospheres does not allow the opening of a full optical bandgap, neither HCP arrangement, but only of a pseudo optical bandgap along the L direction of the Brillouin zone [32]. As expected, there is a reflectivity increase in the spectral region 929 to 980 nm peaking close to 950 nm, with a maximum value of 75.1%. This result is consistent with theoretical calculations

carried out using the plane Selleck BIBW2992 wave expansion method, which predicts Anacetrapib a relative stop band in the normal direction of the crystal. Figure 9 Reflectance measurements of a 360-nm-diameter nanosphere layer. The optical measurements were made with a Shimadzu (Kyoto, Japan) UV3600 UV–VIS-NIR spectrophotometer and an ISR-3100 integrating sphere attachment of 3 mm × 12 mm beam area. All the reflectance measurements were made in the range of 700 to 1,200 nm. The measured sample consists of an approximately 1-cm2 colloidal crystal of 360-nm-diameter polystyrene nanospheres electrosprayed onto a glass substrate covered by a 100-nm-thick ITO layer. Conclusions We can conclude that a simple electrospray method is able to produce thick layers of tridimensional order from off-the-shelf colloidal solutions of nanospheres. Polystyrene nanospheres 360 and 780 nm in diameter were electrosprayed onto 1-cm2 metalized areas. Experimental work was made to achieve 3D ordered nanostructures up to 20-μm thick in a few minutes, totally avoiding cracks. With the dimensions used in this work, it is shown that the deposited layers behave as a photonic crystal exhibiting a stop band in the NIR, according to theoretical predictions, thereby demonstrating good quality of the deposited layers.