Lee ChowFarmington, MI

6582673, Jun 24, 2003

Mar 17, 2000

09/528259

Lee Chow - Orlando FL
Dan Zhou - Orlando FL
Stephen Kleckley - Orlando FL

University of Central Florida - Orlando FL

C01B 3104

423445R, 423445 B, 423448, 423460, 428403

A method for manufacturing carbon nanotubes with an integrally attached outer graphitic layer is disclosed. The graphitic layer improves the ability to handle and manipulate the nanometer size nanotube device in various applications, such as a probe tip in scanning probe microscopes and optical microscopes, or as an electron emitting device. A thermal chemical vapor deposition reactor is the preferred reaction vessel in which a transition metal catalyst with an inert gas, hydrogen gas and a carbon-containing gas mixture are heated at various temperatures in a range between 500Â C. and 1000Â C. with gases and temperatures being adjusted periodically during the reaction times required to grow the nanotube core and subsequently grow the desired outer graphitic layer.

6758957, Jul 6, 2004

Apr 9, 2002

10/119414

Dan Zhou - Orlando FL
Lee Chow - Orlando FL

University of Central Florida - Orlando FL

C25D 1500

205109, 205157, 205234, 205235, 205316, 205317, 205413

Carbon nanoparticles including both nanofilaments and nanotubes produced by an electrochemical deposition method from organic solutions at room temperature, in which the formation and growth of carbon nanoparticles are stimulated by the catalyst, such as iron and nickel. It has been found that the electrochemical deposition conditions have a strong influence on the growth phenomenon of the carbon nanotubes. Scanning electron microscope (SEM) and transmitting electron microscope (TEM) characterizations show that the diameter of nanotubes is of the order of approximately 100 nm, and the length of filaments can be up to approximately 50 m, depending on the size of catalyst particles.

6905736, Jun 14, 2005

Feb 27, 2002

10/084688

Lee Chow - Orlando FL, US
Dan Zhou - Orlando FL, US
Fred Stevie - Raleigh NC, US

University of Central Florida - Orlando FL

B05D005/12
C23C014/14
C23C014/16

427564, 427531, 427595, 427 96, 427123, 427125

The method for the fabrication of nano scale temperature sensors and nano scale heaters using focused ion beam (FIB) techniques. The process used to deposit metal nano strips to form a sensor is ion beam assisted chemical vapor deposition (CVD). The FIB Ga ion beam can be used to decompose W(CO)molecules to deposit a tungsten nano-strip on a suitable substrate. The same substrate can also be used for Pt nano-strip deposition. The precursors for the Pt can be trimethyl platinum (CH)Pt in the present case. Because of the Ga beam used in the deposition, both Pt and W nano-strips can contain a certain percentage of Ga impurities, which we denoted as Pt(Ga) and W(Ga) respectively. Our characterization of the response of this Pt(Ga)/W(Ga) nano scale junction indicates it has a temperature coefficient of approximately 5. 4 mV/ C. This is a factor of approximately 130 larger than the conventional K-type thermocouples.

7009487, Mar 7, 2006

Jan 23, 2004

10/764242

Lee Chow - Orlando FL, US
Dan Zhou - Orlando FL, US
Fred Stevie - Raleigh NC, US

University of Central Florida Research Foundation, Inc. - Orlando FL

H01C 3/04

338 25, 338333

The method for the fabrication of nano scale temperature sensors and nano scale heaters using focused ion beam (FIB) techniques. The process used to deposit metal nano strips to form a sensor is ion beam assisted chemical vapor deposition (CVD). The FIB Ga ion beam can be used to decompose W(CO)molecules to deposit a tungsten nano-strip on a suitable substrate. The same substrate can also be used for Pt nano-strip deposition. The precursors for the Pt can be trimethyl platinum (CH)Pt in the present case. Because of the Ga beam used in the deposition, both Pt and W nano-strips can contain a certain percentage of Ga impurities, which we denoted as Pt(Ga) and W(Ga) respectively. Our characterization of the response of this Pt(Ga)/W(Ga) nano scale junction indicates it has a temperature coefficient of approximately 5. 4 mV/ C. This is a factor of approximately 130 larger than the conventional K-type thermocouples.

7011884, Mar 14, 2006

Apr 25, 2003

10/424336

Lee Chow - Orlando FL, US
Dan Zhou - Orlando FL, US
Stephen Kleckley - Orlando FL, US

University of Central Florida Research Foundation, Inc. - Orlando FL

D01F 9/12

428367, 4234471, 4234472, 977DIG 1

A method for manufacturing carbon nanotubes with an integrally attached outer graphitic layer is disclosed. The graphitic layer improves the ability to handle and manipulate the nanometer size nanotube device in various applications, such as a probe tip in scanning probe microscopes and optical microscopes, or as an electron emitting device. A thermal chemical vapor deposition reactor is the preferred reaction vessel in which a transition metal catalyst with an inert gas, hydrogen gas and a carbon-containing gas mixture are heated at various temperatures in a range between 500 C. and 1000 C. with gases and temperatures being adjusted periodically during the reaction times required to grow the nanotube core and subsequently grow the desired outer graphitic layer.

7422667, Sep 9, 2008

Oct 18, 2004

10/699488

Dan Zhou - St. Peter MO, US
Lee Chow - Orlando FL, US
Elvira Vladimirovna Anoshkina - Winter Springs FL, US

University of Central Florida Research Foundation, Inc. - Orlando FL

C25B 9/06
C25B 3/00
B82B 3/00

2042301, 2042298, 204242, 977742, 977842, 977899

Carbon nanoparticles including both nanofilaments and nanotubes produced by an electrochemical deposition method from organic solutions at room temperature, in which the formation and growth of carbon nanoparticles are stimulated by the catalyst, such as iron and nickel. It has been found that the electrochemical deposition conditions have a strong influence on the growth phenomenon of the carbon nanotubes. Scanning electron microscope (SEM) and transmitting electron microscope (TEM) characterizations show that the diameter of nanotubes is of the order of approximately 100 nm, and the length of filaments can be up to approximately 50 μm, depending on the size of catalyst particles.

7750297, Jul 6, 2010

Mar 9, 2007

11/716258

Lee Chow - Orlando FL, US
Guangyu Chai - Orlando FL, US
Thomas Schenkel - San Francisco CA, US

University of Central Florida Research Foundation, Inc. - Orlando FL
The Regents of the University of California - Oakland CA

H01J 37/26
G21K 5/04

250311, 250306, 250307, 2504923, 977734, 977742, 977840, 977842, 977849

Apparatus, methods, systems and devices for fabricating individual CNT collimators. Micron size fiber coated CNT samples are synthesized with chemical vapor deposition method and then the individual CNT collimators are fabricated with focused ion beam technique. Unfocused electron beams are successfully propagated through the CNT collimators. The CNT nano-collimators are used for applications including single ion implantation and in high-energy physics, and allow rapid, reliable testing of the transmission of CNT arrays for transport of molecules.

7847207, Dec 7, 2010

Oct 8, 2004

10/961929

Lee Chow - Orlando FL, US
Guang-Yu Chai - Orlando FL, US

University of Central Florida Research Foundation, Inc. - Orlando FL

B23K 11/22
C23C 8/00

219 68, 4234471, 4234473, 423585, 427564, 228101

An easy and controllable method and system to attach a carbon nanotube to a scanning probe tip such as a scanning probe microscopy (SPM) tip using a focus ion beam (FIB) technique. The method and system includes selecting a carbon fiber by a Focus Ion Beam micromanipulator, picking up the carbon fiber with the nanotube tip, forming a slot on an SPM tip, and inserting the carbon fiber with the nanotube tip into the slot.