Abstract: A physical structure and a method for forming a electronic devices on a substrate comprising: providing a substrate; forming a plurality of layers on the substrate, the layers comprising at least two layers of conducting material and a layer of insulating material therebetween; depositing photoresist material onto predetermined regions of the plurality of layers, the photoresist material varying in thickness; utilizing gray scale illumination on the photoresist material; removing a portion of the layers using physical etching to expose predetermined portions of the conducting layers. Optionally, the photoresist may be utilized on a plurality of discrete electronic devices concurrently, such that the gray scale illumination is conducted on a plurality of discrete electronic devices concurrently. Similarly, the physical etching may be conducted on the discrete electronic devices concurrently; removing different thicknesses of material concurrently. Also claimed is a product made by the claimed method.

Abstract: A physical structure and a method for forming a electronic devices on a substrate comprising: providing a substrate; forming a plurality of layers on the substrate, the layers comprising at least two layers of conducting material and a layer of insulating material therebetween; depositing photoresist material onto predetermined regions of the plurality of layers, the photoresist material varying in thickness; utilizing gray scale illumination on the photoresist material; removing a portion of the layers using physical etching to expose predetermined portions of the conducting layers. Optionally, the photoresist may be utilized on a plurality of discrete electronic devices concurrently, such that the gray scale illumination is conducted on a plurality of discrete electronic devices concurrently. Similarly, the physical etching may be conducted on the discrete electronic devices concurrently; removing different thicknesses of material concurrently. Also claimed is a product made by the claimed method.

Abstract: A method of forming a device on a substrate comprising creating a depository and at least one attached capillary; the depository being of millimeter scale; providing a liquid containing particles in the range 1 nanometer to 1 millimeter; depositing into the depository the liquid containing particles which flows into at least one capillary by capillary action; evaporating the liquid such that the particles form an agglomerate beginning at the end of the at least one capillary with a substantially uniform distribution of the particles within the agglomerate; which is used to form a device. A microelectronic integrated circuit device comprising a substrate; a depository coupled to said substrate, the depository being formed by at least one wall adjacent to the substrate; at least one capillary channel coupled to at least one depository that is formed by walls adapted to be filled with a liquid (by capillary action) comprising nanoparticles.

Abstract: Methods of forming a nano-scale electronic and optoelectronic devices include forming a substrate having a semiconductor layer therein and a substrate insulating layer on the semiconductor layer. An etching template having a first array of non-photolithographically defined nano-channels extending therethrough, is formed on the substrate insulating layer. This etching template may comprise an anodized metal oxide, such as an anodized aluminum oxide (AAO) thin film. The substrate insulating layer is then selectively etched to define a second array of nano-channels therein. This selective etching step preferably uses the etching template as an etching mask to transfer the first array of nano-channels to the underlying substrate insulating layer, which may be thinner than the etching template. An array of semiconductor nano-pillars is then formed in the second array of nano-channels. The semiconductor nano-pillars in the array may have an average diameter in a range between about 8 nm and about 50 nm.