| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 205114000 | Uniting two separate solid materials | 7 |
| 20090194424 | CONTACT METALLIZATION OF CARBON NANOTUBES - In one embodiment, SWNTs are synthesized from an embedded catalyst in a modified porous anodic alumina (PAA) template. Pd is electrodeposited into the template to form nanowires that grow from an underlying conductive layer beneath the PAA and extend to the initiation sites of the SWNTs within each pore. Individual vertical channels of SWNTs are created, each with a vertical Pd nanowire back contact. Further Pd deposition results in annular Pd nanoparticles that form on portions of SWNTs extending onto the PAA surface. Two-terminal electrical characteristics produce linear I-V relationships, indicating ohmic contact in the devices. | 08-06-2009 |
| 20120234687 | SOLDERING PROCESS USING ELECTRODEPOSITED INDIUM AND/OR GALLIUM, AND ARTICLE COMPRISING AN INTERMEDIATE LAYER WITH INDIUM AND/OR GALLIUM - The present invention relates to a low temperature process for producing and joining metal substrates using an intermediate layer comprising indium or gallium, wherein the indium or gallium layer is formed by electrodeposition from an ionic liquid comprising an indium or gallium salt. | 09-20-2012 |
| 20130062212 | EMBEDDING A NANOTUBE INSIDE A NANOPORE FOR DNA TRANSLOCATION - A technique for embedding a nanotube in a nanopore is provided. A membrane separates a reservoir into a first reservoir part and a second reservoir part, and the nanopore is formed through the membrane for connecting the first and second reservoir parts. An ionic fluid fills the nanopore, the first reservoir part, and the second reservoir part. A first electrode is dipped in the first reservoir part, and a second electrode is dipped in the second reservoir part. Driving the nanotube into the nanopore causes an inner surface of the nanopore to form a covalent bond to an outer surface of the nanotube via an organic coating so that the inner surface of the nanotube will be the new nanopore with a super smooth surface for studying bio-molecules while they translocate through the nanotube. | 03-14-2013 |
| 20130213815 | Method of Fabricating a Nanochannel System for DNA Sequencing and Nanoparticle Characterization - A process for fabricating a nanochannel system using a combination of microelectromechanical system (MEMS) microfabrication techniques and atomic force microscopy (AFM) nanolithography. The nanochannel system, fabricated on either a glass or silicon substrate, has channel heights and widths on the order of single to tens of nanometers. The channel length is in the micrometer range. The nanochannel system is equipped with embedded micro or nanoscale electrodes, positioned along the length of the nanochannel for electron tunneling based characterization of nanoscale particles in the channel. Anodic bonding is used to cap off the nanochannel with a cover chip. | 08-22-2013 |
| 20140166494 | METHOD FOR FABRICATING FIELD EMISSION CATHODE STRUCTURE - A method for fabricating the field emission cathode structure includes following steps. A first carbon nanotube structure is provided. The first carbon nanotube structure is suspended. A voltage is applied to heat the first carbon nanotube structure to form a temperature gradient. A number of second carbon nanotubes are grown on a surface of the first carbon nanotube structure to form a second carbon nanotube structure. | 06-19-2014 |
| 20140332395 | MANUFACTURING METHOD OF ELECTRONIC COMPONENT - A manufacturing method of an electronic component allows an intermediate inspection during a manufacturing process and includes forming element electrodes and feed lines such that pad portions of the element electrodes and the corresponding one of the feed lines faces each other via a gap in a plan view, and such that the feed lines are located below the pad portions 11 | 11-13-2014 |
| 20160073746 | INVISIBLE SET DECORATIVE PART - The invention relates to a decorative part ( | 03-17-2016 |
