Patent application number | Description | Published |
20090242869 | SUPER LATTICE/QUANTUM WELL NANOWIRES - Segmented semiconductor nanowires are manufactured by removal of material from a layered structure of two or more semiconductor materials in the absence of a template. The removal takes place at some locations on the surface of the layered structure and continues preferentially along the direction of a crystallographic axis, such that nanowires with a segmented structure remain at locations where little or no removal occurs. The interface between different segments can be perpendicular to or at angle with the longitudinal direction of the nanowire. | 10-01-2009 |
20090269286 | SYSTEM AND METHOD FOR AUTHENTICATING PHARMACEUTICALS USING INTERNALLY LOCATED HYDROSCOPIC GELS WITH INDICIA - The invention is an article of manufacture, comprising an identifying marker disposed in a pharmaceutical product. The pharmaceutical product may be selected from the group consisting of a pharmaceutical liquid, a pill, a tablet, a caplet, and a capsule. The identifying marker may be a hydroscopic medium having an indicia imprinted thereon or within, where the marker expands volumetrically when contacted with a liquid. | 10-29-2009 |
20120193231 | DNA SEQUENCING USING MULTIPLE METAL LAYER STRUCTURE WITH ORGANIC COATINGS FORMING TRANSIENT BONDING TO DNA BASES - A nanodevice is provided. A reservoir is filled with an ionic fluid. A membrane separates the reservoir, and the membrane includes electrode layers separated by insulating layers in which the electrode layers have an organic coating. A nanopore is formed through the membrane, and the organic coating on the electrode layers forms transient bonds to a base of a molecule in the nanopore. When a first voltage is applied to the electrode layers a tunneling current is generated by the base in the nanopore, and the tunneling current travels through the transient bonds formed to the base to be measured as a current signature for distinguishing the base. | 08-02-2012 |
20120286236 | SUPER LATTICE/QUANTUM WELL NANOWIRES - Segmented semiconductor nanowires are manufactured by removal of material from a layered structure of two or more semiconductor materials in the absence of a template. The removal takes place at some locations on the surface of the layered structure and continues preferentially along the direction of a crystallographic axis, such that nanowires with a segmented structure remain at locations where little or no removal occurs. The interface between different segments can be perpendicular to or at angle with the longitudinal direction of the nanowire. | 11-15-2012 |
20130001082 | DNA SEQUENCING USING MULTIPLE METAL LAYER STRUCTURE WITH ORGANIC COATINGS FORMING TRANSIENT BONDING TO DNA BASES - A technique for nanodevice is provided. A reservoir is filled with an ionic fluid. A membrane separates the reservoir, and the membrane includes electrode layers separated by insulating layers in which the electrode layers have an organic coating. A nanopore is formed through the membrane, and the organic coating on the electrode layers forms transient bonds to a base of a molecule in the nanopore. When a first voltage is applied to the electrode layers a tunneling current is generated by the base in the nanopore, and the tunneling current travels through the transient bonds formed to the base to be measured as a current signature for distinguishing the base. | 01-03-2013 |
20130068617 | CHARGED ENTITIES AS LOCOMOTIVE TO CONTROL MOTION OF POLYMERS THROUGH A NANOCHANNEL - A technique for controlling the motion of one or more charged entities linked to a polymer through a nanochannel is provided. A first reservoir and a second reservoir are connected by the nanochannel. An array of electrodes is positioned along the nanochannel, where fluid fills the first reservoir, the second reservoir, and the nanochannel. A first electrode is in the first reservoir and a second electrode is in the second reservoir. The first and second electrodes are configured to direct the one or more charged entities linked to the polymer into the nanochannel. An array of electrodes is configured to trap the one or more charged entities in the nanochannel responsive to being controlled for trapping. The array of electrodes is configured to move the one or more charged entities along the nanochannel responsive to being controlled for moving. | 03-21-2013 |
20130068618 | CHARGED ENTITIES AS LOCOMOTIVE TO CONTROL MOTION OF POLYMERS THROUGH A NANOCHANNEL - A technique for controlling the motion of one or more charged entities linked to a polymer through a nanochannel is provided. A first reservoir and a second reservoir are connected by the nanochannel. An array of electrodes is positioned along the nanochannel, where fluid fills the first reservoir, the second reservoir, and the nanochannel. A first electrode is in the first reservoir and a second electrode is in the second reservoir. The first and second electrodes are configured to direct the one or more charged entities linked to the polymer into the nanochannel. An array of electrodes is configured to trap the one or more charged entities in the nanochannel responsive to being controlled for trapping. The array of electrodes is configured to move the one or more charged entities along the nanochannel responsive to being controlled for moving. | 03-21-2013 |
20140299473 | CONTROLLED TRANSLOCATION OF MACROMOLECULES EMPLOYING A FUNNEL NANOPORE STRUCTURE AND A GEL - A system of controlled translocation of macromolecules by gel electrophesis employs a funnel nanopore structure. A graphene portion is attached to a porous material layer including funnel-shaped pores such that the graphene portion blocks the side of the porous material layer having openings for smaller pores. A pair of electrical contacts is formed on the graphene portion. A dielectric material layer may be deposited to hold the graphene portion in place. A nanoscale hole is formed through the dielectric material layer and the graphene portion to provide a smallest opening in a funnel nanopore structure. The funnel nanopore structure is placed within a capsule configured for gel electrophoresis. A linear chain of molecules can pass through a funnel-shaped pore and the nanoscale hole during the gel electrophoresis. A graphene nanopore detector allows measurement of blockage current for sufficient resolution of base pairs in DNA's. | 10-09-2014 |
20140299474 | CONTROLLED TRANSLOCATION OF MACROMOLECULES EMPLOYING A FUNNEL NANOPORE STRUCTURE AND A GEL - A system of controlled translocation of macromolecules by gel electrophesis employs a funnel nanopore structure. A graphene portion is attached to a porous material layer including funnel-shaped pores such that the graphene portion blocks the side of the porous material layer having openings for smaller pores. A pair of electrical contacts is formed on the graphene portion. A dielectric material layer may be deposited to hold the graphene portion in place. A nanoscale hole is formed through the dielectric material layer and the graphene portion to provide a smallest opening in a funnel nanopore structure. The funnel nanopore structure is placed within a capsule configured for gel electrophoresis. A linear chain of molecules can pass through a funnel-shaped pore and the nanoscale hole during the gel electrophoresis. A graphene nanopore detector allows measurement of blockage current for sufficient resolution of base pairs in DNA's. | 10-09-2014 |