Provided are plasmon resonance imaging devices having metal-insulator-metal nanocups and methods of use thereof.

A method of forming a semiconductor structure includes forming two or more catalyst nanoparticles from a metal layer disposed over a substrate in two or more openings of a hard mask patterned over the metal layer. The method also includes growing two or more carbon nanotubes using the catalyst nanoparticles, and removing the carbon nanotubes to form two or more nanoscale pores. The two or more nanoscale pores may be circular nanoscale pores having a substantially uniform diameter. The two or more openings in the hard mask may have non-uniform size, and the substantially uniform diameter of the two or more nanopores may be controlled by a size of the carbon nanotubes.

A method for surface writing is disclosed. The method includes fabricating a plurality of nanomotors, forming a secondary solution by adding the plurality of nanomotors to a primary solution placed on a substrate, guiding the plurality of nanomotors along a path in the secondary solution, and forming a sol-gel film along the path on a surface of the substrate. Wherein, the primary solution includes a monomer and hydrogen peroxide (H.sub.2O.sub.2). Fabricating the plurality of nanomotors includes preparing a mesoporous silica template, forming the plurality of nanomotors within the mesoporous silica template, and separating the plurality of nanomotors from the mesoporous silica template. The mesoporous silica template includes a plurality of channels, wherein each channel of the plurality of channels has a diameter less than about 50 nm and a length of less than about 100 nm, and each nanomotor of the plurality of nanomotors is formed within a channel of the plurality of channels.

Embodiments relate to an apparatus for forming nano-structures with tailored properties on objects while fabricating the objects. The apparatus includes a reservoir that holds compositions therein. Each of the compositions includes a nano-structural material, a plurality of grain growth inhibitor nano-particles, and at least one of a tailoring solute and a plurality of tailoring nano-particles. A nozzle is operatively coupled to the reservoir and a translatable stage is positioned proximate to the nozzle. The stage includes a substrate holder adapted to hold a substrate. A surface profile determination device is positioned proximate to the stage to obtain profile data of the substrate. A control unit is operatively coupled to the device and the stage and regulates manufacture of a pinned nano-structure. The control unit forms deposition layers positioned proximal to the substrate with the compositions through electrospray techniques.

A wearable electronic device may alert a wearer as to a presence of either a range of allergens or to specific pollen to which the individual is allergic. As such, the device may warn the user of bioparticles likely to affect them allergenically. The device may include an airflow path. A deterministic lateral displacement (DLD) array may be positioned within the airflow path to capture bioparticles of a particular size. An imaging device may capture images of captured bioparticles. The system may include a database of bioparticles in a range of sizes. The system may be configured to compare the captured bioparticles to the information in the database. A wearer may be alerted if bioparticles potentially allergenically problematic to the person have been found in the captured bioparticles.

A wearable electronic device may alert a wearer as to a presence of either a range of allergens or to specific pollen to which the individual is allergic. As such, the device may warn the user of bioparticles likely to affect them allergenically. The device may include an airflow path. A deterministic lateral displacement (DLD) array may be positioned within the airflow path to capture bioparticles of a particular size. An imaging device may capture images of captured bioparticles. The system may include a database of bioparticles in a range of sizes. The system may be configured to compare the captured bioparticles to the information in the database. A wearer may be alerted if bioparticles potentially allergenically problematic to the person have been found in the captured bioparticles.

Techniques regarding nanofluidic chips with a plurality of inlets and/or outlets in fluid communication with one or more nanoDLD arrays are provided. For example, one or more embodiments described herein can comprise a nanoscale deterministic lateral displacement array between and in fluid communication with a global inlet and a global outlet. The nanoscale deterministic lateral displacement array can further be between and in fluid communication with a local inlet and a local outlet. Also, the nanoscale deterministic lateral displacement array can laterally displace a particle comprised within a sample fluid supplied from the global inlet to a collection region that directs the particle to the local outlet. An advantage of such an apparatus can be the expanded versatility of the nanoscale deterministic lateral displacement array for sample preparation applications involving nanoparticles not accessible to other higher throughput microscale microfluidic technologies.

A method for separating a carbon nanotube array grown on a growth substrate from the growth substrate includes providing a carbon nanotube array grown on the growth substrate. The carbon nanotube array includes a plurality of carbon nanotube, each of the plurality of carbon nanotubes includes a top end and a bottom end, and the bottom end is bonded to the growth substrate. The bottom end is oxidized to form an oxidized carbon nanotube array. And then the oxidized carbon nanotube array or the growth substrate is applied to a force.

The present invention is a method for fabricating clean technology products. It discloses composition comprising: a network of one or more nanostructures having a lattice structure formed by (ASU)n, ASU is asymmetric unit, n>0, the one or more nanostructures of the present invention comprise a selection from the group consisting of 0D, 1D, 2D, carbon, inorganic, and any combinations thereof, the lattice structure of the present invention is selected from a cubic system, a rhombohedral system, an orthorhombic system, monoclinic system, and triclinic system, where ASU is selected from (HwTxLyMz) H is hydrogen, T is an alkaline metal, L is a chalcogen, O is oxygen, w>=0, x>=1, y>=1, z>=0.

A method of preparing an optical element made of a transparent plastic with embedded or firmly bound nanoparticles, the method comprising: a) exposing the optical element to nanoparticles and to a liquid that causes the nanoparticles to diffuse into or become firmly bound to the optical element; and b) maintaining the optical element and the liquid at a range of pressures greater than one atmosphere, and at a range of diffusion temperatures greater than the boiling point of the liquid at one atmosphere, while the liquid remains in a liquid state, for a time interval, while the nanoparticles diffuse into or firmly bind to the optical element.