Jingming Xu

Bio: Jingming Xu is an academic researcher from California Institute of Technology. The author has contributed to research in topics: Molecular sieve & Signal. The author has an hindex of 2, co-authored 2 publications receiving 175 citations.

Carbon nanotube array rf filter

Abstract: A tunable nanomechanical filter system (10) comprising an array of nanofeatures (18), such as nanotubes, where the nanofeatures (18) are in signal communication with means for inducing a difference in charge density in the nanofeature (18) such that the mechanical resonant frequency of the nanofeature (18) can be tuned, and where the nanofeature (18) is in signal communication with a waveguide (14) or other RF bias conduit such that an RF signal having a frequency corresponding to the mechanical resonant frequency of the array will couple to the array thereby inducing resonant motion in the array of nanofeatures (18), and subsequently coupling to an output waveguide (16), forming a nanoscale RF filter (10) is provided. A method of producing a nanoscale RF filter (10) structure controllably positioned and oriented with a waveguide (14/16) and integrated electrodes (20) is also provided.

Development of a gel-free molecular sieve based on self-assembled nano-arrays

Abstract: A device for utilizing a non-gel self-assembled nano-feature array molecular sieve for analyzing molecules is provided. The molecular sieve device comprises an ordered array of self-assembled nano-features which function as a molecular sieve to separate molecules based on a suitable characteristic. A system for integrating the non-gel ordered self-assembled nano-feature array molecular sieve of this invention into a device for separating molecules based on a characteristic and a method for separating a wide range of molecules using the non-gel ordered self-assembled nano-feature array molecular sieve of the invention are also provided.

Integrated circuit device and method of producing the same

Abstract: An integrated circuit device having vias having good resistance to migration causing the breaking of a wiring line, or an integrated circuit device having a wiring structure that is fined by breaking the limit of lithography technique is provided. The former device comprises a plurality of elements fabricated on a semiconductor substrate, wiring lines for making the elements and the integrated circuit device function, and vias for interconnecting wiring lines in separate layers, the via being formed of one or more cylindrical structures made up of carbon atoms. The latter device comprises a plurality of elements fabricated on a semiconductor substrate and wiring members for making the elements and the integrated circuit device function, at least part of the wiring members being formed of one or more cylindrical structures made up of carbon atoms. The latter device is preferably manufactured by a method comprising using a CVD process for the formation of the cylindrical structures, while applying a direct current electric field so as to grow the cylindrical structures in one direction, or applying an alternating current electric field so as to grow the cylindrical structures in two directions. A semiconductor device using a carbon nanotube and a method of forming a pattern using a carbon nanotube as a mask are also disclosed.

Method of producing regular arrays of nano-scale objects using nano-structured block-copolymeric materials

Abstract: A method of forming a periodic array of nano-scale objects using a block copolymer, and nano-scale object arrays formed from the method are provided. The method for forming the arrays generally includes the steps of depositing a block copolymer of at least two blocks on a substrate to form an ordered meso-scale structured array of the polymer materials, forming catalytic metal dots based on the meso-scale structure, and growing nano-scale objects on the catalytic dots to form an ordered array of nano-scale objects.

Nanocomposites and methods thereto

Abstract: Electrical, thermal and mechanical applications are provided for nanocomposite materials having low percolation thresholds for electrical conductivity, low percolation thresholds for thermal conductivity, or improved mechanical properties.

Method of fabricating a composite carbon nanotube thermal interface device

Abstract: Embodiments of a composite carbon nanotube structure comprising a number of carbon nanotubes disposed in a matrix comprised of a metal or a metal oxide. The composite carbon nanotube structures may be used as a thermal interface device in a packaged integrated circuit device.

Sensor for detecting biomolecule using carbon nanotubes

Abstract: Provided is a sensor for detecting a biomolecule, and particularly, a sensor for detecting a biomolecule, including (a) a substrate; and (b) a plurality of carbon nanotubes which are arranged on the substrate and provide a binding site for a receptor for a target biomolecule. With the biomolecular sensor, a various kinds of disease-associated biomolecules can be detected simultaneously, accurately and quickly.