Abstract: This disclosure relates to a system and method for creating nano-object arrays. A nano-object array can be created by exposing troughs in a corrugated surface to nano-objects and depositing the nano-objects within or orienting the nano-objects with the troughs.

Abstract: This invention relates to a method of fabricating nano-dimensional structures, comprising: depositing at least one deformable material upon a substrate such that the material includes at least one portion; and creating an oxidizable layer located substantially adjacent to the deposited deformable material such that at least a portion of the oxidized portion of the oxidizable layer interacts with the at least one portion of the deformable material to apply a localized pressure upon the at least one portion of the deformable material.

Abstract: A storage medium for gas molecules has a nanowire core and a number of organic molecules attached to the exterior surface of the nanowire. The organic molecules attached to the exterior of the nanowire are adapted to releasably hold gas molecules. Methods for making and using the invention, including the use of a silicon nanowire, are disclosed.

Abstract: This disclosure relates to a system and method for creating nano-object arrays. A nano-object array can be created by exposing troughs in a corrugated surface to nano-objects and depositing the nano-objects within or orienting the nano-objects with the troughs.

Abstract: This disclosure describes system(s) and/or method(s) enabling contacts for individual nanometer-scale-thickness layers of a multilayer film.

Abstract: A method of using a contact printing stamp, including forming a transfer material on a plurality of stamping surfaces. The plurality of stamping surfaces are disposed on a plurality of stamp protrusions adapted from the forming of a stamp material in a plurality of recessed regions formed in an exposed end-region of a multilayer thin film structure.

Abstract: A periodic layered structure having physical and chemical properties varying periodically at least along a direction perpendicular to its layers is made by providing a substrate, depositing a quantity of non-porous electrochemically oxidizable material over the substrate, at least partially anodizing the non-porous electrochemically oxidizable material, and repeating similar steps until a layered structure having a desired periodicity and a desired total structure thickness is completed.

Abstract: A method of forming a contact printing stamp, including creating a stamp material in a plurality of recessed regions formed in an exposed end-region of a multilayer thin film structure. The stamp material having a printing surface adapted to transfer a transfer material.

Abstract: A memory device including a substrate, and multiple self-aligned nano-rectifying elements disposed over the substrate. Each nano-rectifying element has multiple first electrode lines, and multiple device structures disposed on the multiple first electrode lines forming the multiple self-aligned nano-rectifying elements. Each device structure has at least one lateral dimension less than about 75 nanometers. The memory device also includes multiple switching elements disposed over the device structures and self-aligned in at least one direction with the device structures. In addition, the memory device includes multiple second electrode lines disposed over, electrically coupled to, and self-aligned to the switching elements, whereby a memory device is formed.

Abstract: A memory device including a substrate, and multiple self-alignednano-rectifying elements disposed over the substrate. Each nano-rectifying element has multiple first electrode lines, and multiple device structures disposed on the multiple first electrode lines forming the multiple self-aligned nano-rectifying elements. Each device structure has at least one lateral dimension less than about 75 nanometers. The memory device also includes multiple switching elements disposed over the device structures and self-aligned in at least one direction with the device structures. In addition, the memory device includes multiple second electrode lines disposed over, electrically coupled to, and self-aligned to the switching elements, whereby a memory device is formed.

Abstract: A single molecular species having a low-forward-voltage rectifying property is provided. The molecular species is represented by the formula: CL-IL-A-IR-CR where A is a “conducting” moiety (with a relatively narrow HOMO-LUMO gap), IL and IR are each an “insulating” moiety (with a relatively wide HOMO-LUMO gap), CL is a connecting group for attachment to a first electrode, and CR is a connecting group for attachment to a second electrode. Also, a low-forward-voltage rectifying molecular rectifier is provided, comprising the molecular species attached between the two electrodes. The present teachings provide a set of design rules to build single-molecule rectifying diodes that operate at low forward and large reverse voltages. Such single-molecule rectifying diodes are useful in a variety of nano-scale applications.

Abstract: This disclosure relates to continuous carbon-nanotube filaments of radiation-emitting devices and methods for fabricating them.

Abstract: In one embodiment, a method for fabricating a nano-structure includes forming a feature on a substrate, depositing multiple layers of material over the substrate and feature to form a multi-layer stack, depositing a film over the multi-layer stack, removing a portion of the film and the multi-layer stack to expose edges of the layers of material, and removing portions of the layers of material to form trenches at a surface of the nano-structure.

Abstract: The disclosure relates to a system having a chemical sensor and either a temperature sensor or an ionic-strength sensor in a same fluidic channel. The disclosure also related to a system having a chemical sensor and either a temperature sensor or an ionic-strength sensor over a same substrate. This system can be capable of measuring chemical concentrations of two or more chemicals and a temperature or ionic strength of a fluid.

Abstract: This disclosure relates to a system and method for fabricating and using a superlattice. A superlattice can be fabricated by applying alternating material layers on a ridge and then removing some of the alternating layers to expose edges. These exposed edges can be of nearly arbitrary length and curvature. These edges can be used to fabricate an array of nano-scale-width curved wires.

Abstract: A structure is provided that is formed with a template defining a pattern having nanoscale features. The template may be positioned on a substrate and include a resist layer having openings formed therein, where the template is configured to accommodate the controlled assembly of nanoscale objects.

Abstract: One aspect of this disclosure relates to a method of building a superconductor device on a substrate, comprising depositing an imprint layer on at least a portion of the subdtrate. The imprint layer is imprinted to provide an imprinted portion of the imprint layer and a non-imprinted portion of the imprint layer. A superonductor layer is deposited on at least a portion of the imprint portion of the imprint layer.

Abstract: One aspect of this disclosure relates to a method of building a superconductor device on a substrate, comprising depositing an imprint layer on at least a portion of the substrate. The imprint layer is imprinted to provide an imprinted portion of the imprint layer and a non-imprinted portion of the imprint layer. A superconductor layer is deposited on at least a portion of the imprinted portion of the imprint layer.

Abstract: A memory device including a substrate, and multiple self-alignednano-rectifying elements disposed over the substrate. Each nano-rectifying element has multiple first electrode lines, and multiple device structures disposed on the multiple first electrode lines forming the multiple self-aligned nano-rectifying elements. Each device structure has at least one lateral dimension less than about 75 nanometers. The memory device also includes multiple switching elements disposed over the device structures and self-aligned in at least one direction with the device structures. In addition, the memory device includes multiple second electrode lines disposed over, electrically coupled to, and self-aligned to the switching elements, whereby a memory device is formed.

Abstract: One aspect of this disclosure relates to a method of building a superconductor device on a substrate, comprising depositing an imprint layer on at least a portion of the substrate. The imprint layer is imprinted to provide an imprinted portion of the imprint layer and a non-imprinted portion of the imprint layer. A superconductor layer is deposited on at least a portion of the imprinted portion of the imprint layer.