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Thai Minh Le

from Allen, TX
Age ~58
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Also known as:
Thai M Le, Thai Giao Le, Thoi M Le, Thai Mle, Mike Le, Minh Le Thai, Manh Lethai, Thai Minhle
Phone and address:
724 Cottonwood Bend Dr, Allen, TX 75002
Related to:
Tam H Truong, 87Ngan Le Kim, 36Manh LeLe Dung NDung L Nguyen, 62Khue V Nguyen, 61Andrew D Vinh, 64Romeo Le, 36Dung N Le, 62T LexuanXuan L Vinh, 61Thy H Troung, 53Dinh Q Truong, 50Kim LeGiao H Truong, 58Vincent N Le, 30Brandon Q Truong, 50V LedungPhuong T Nguyen, 55Ronald Le, 33
Connected to:
Ai Le, 52Alphonse A Le, 51Amie Le, 46Angela M Le, 48Angeline H Le, 45Anhvu X Le, 56Annette M Le, 88Anson H Le, 39Antoine Le, 43Ar Le, 37

Thai Le Phones & Addresses

  • 724 Cottonwood Bend Dr, Allen, TX 75002
  • Plano, TX
  • Lafayette, IN
  • Alviso, CA
  • Richardson, TX
  • Dallas, TX

Resumes

Resumes

Thai Le Photo 1

Thai Le

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Thai Le Photo 2

Thai Le

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Thai Le Photo 3

Thai Le

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Thai Le Photo 4

Thai Le

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Thai Le Photo 5

Thai Le

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Thai Le Photo 6

Thai Le

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Thai Le Photo 7

Thai Le Los Angeles, CA

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Work:
TAKEDA PHARMACEUTICALS

2004 to Present
Territory Manager
CREST STEEL CORPORATION
Carson, CA
2003 to 2004
Business Development Associate
ADVANCED MICRO DEVICES
Sunnyvale, CA
2001 to 2002
Channel Sales Associate, Technical Sales Engineer Program
Education:
UCLA ANDERSON SCHOOL OF MANAGEMENT
Los Angeles, CA
2009
M.B.A. in Entrepreneurship
UNIVERSITY OF CALIFORNIA
Los Angeles, CA
2001
B.A. in Economics
Skills:
MS Office
Thai Le Photo 8

Thai An Le

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Work:
Oxfam
Sucre
Jul 2012 to Dec 2012
Business Advisor for Women - 6 month internship
Limited Brands Canada
Montral, QC
2011 to 2012
Financial Analyst - Inventory
Imperial Tobacco Canada Limited
Montral, QC
2009 to 2011
Credit Analyst/Billing Adjustments/Accounts Payable
Scotiabank
Montral, QC
2007 to 2009
Customer Service Representative
Education:
McGill University
Montral, QC
2006 to 2009
Bachelor of Commerce in Finance
Collge Jean-de-Brebeuf
Montral, QC
2004 to 2006
International Baccalaureate in Economics
CFA Institute
Montral, QC
CFA level III Candidate in Finance
CAIA Association
CAIA in Finance
Skills:
MS Word, MS Excel, MS PowerPoint, MS Outlook, SAP, Peoplesoft, nVision, Lotus Notes, BI, Connected Retailer/Smartlook

Publications

Us Patents

Exchange-Coupled Magnetoresistive Sensor With A Coercive Ferrite Layer And An Oxide Underlayer Having A Spinal Lattice Structure

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US Patent:
6992866, Jan 31, 2006
Filed:
Aug 31, 2004
Appl. No.:
10/931315
Inventors:
Matthew Joseph Carey - San Jose CA, US
Eric Edward Fullerton - Morgan Hill CA, US
Bruce Alvin Gurney - San Rafael CA, US
Thai Le - San Jose CA, US
Stefan Maat - San Jose CA, US
Philip Milton Rice - San Jose CA, US
Assignee:
Hitachi Global Storage Technologies Netherlands B.V. - Amsterdam
International Classification:
G11B 5/39
US Classification:
36032411
Abstract:
An exchange-coupled magnetic structure includes a ferromagnetic layer, a coercive ferrite layer, such as cobalt-ferrite, for biasing the magnetization of the ferromagnetic layer, and an oxide underlayer, such as cobalt-oxide, in proximity to the coercive ferrite layer. The oxide underlayer has a lattice structure of either rock salt or a spinel and exhibits no magnetic moment at room temperature. The underlayer affects the structure of the coercive ferrite layer and therefore its magnetic properties, providing increased coercivity and enhanced thermal stability. As a result, the coercive ferrite layer is thermally stable at much smaller thicknesses than without the underlayer. The exchange-coupled structure is used in spin valve and magnetic tunnel junction magnetoresistive sensors in read heads of magnetic disk drive systems. Because the coercive ferrite layer can be made as thin as 1 nm while remaining thermally stable, the sensor satisfies the narrow gap requirements of high recording density systems.

Stability-Enhancing Underlayer For Exchange-Coupled Magnetic Structures, Magnetoresistive Sensors, And Magnetic Disk Drive Systems

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US Patent:
7116532, Oct 3, 2006
Filed:
Nov 9, 2004
Appl. No.:
10/985195
Inventors:
Matthew Joseph Carey - San Jose CA, US
Eric Edward Fullerton - Morgan Hill CA, US
Bruce Alvin Gurney - San Rafael CA, US
Thai Le - San Jose CA, US
Stefan Maat - San Jose CA, US
Philip Milton Rice - San Jose CA, US
Assignee:
Hitachi Global Storage Technologies Netherlands B.V. - Amsterdam
International Classification:
G11B 5/39
US Classification:
36032411
Abstract:
An exchange-coupled magnetic structure includes a ferromagnetic layer, a coercive ferrite layer, such as cobalt-ferrite, for biasing the magnetization of the ferromagnetic layer, and an oxide underlayer, such as cobalt-oxide, in proximity to the coercive ferrite layer. The oxide underlayer has a lattice structure of either rock salt or a spinel and exhibits no magnetic moment at room temperature. The underlayer affects the structure of the coercive ferrite layer and therefore its magnetic properties, providing increased coercivity and enhanced thermal stability. As a result, the coercive ferrite layer is thermally stable at much smaller thicknesses than without the underlayer. The exchange-coupled structure is used in spin valve and magnetic tunnel junction magnetoresistive sensors in read heads of magnetic disk drive systems. Because the coercive ferrite layer can be made as thin as 1 nm while remaining thermally stable, the sensor satisfies the narrow gap requirements of high recording density systems.

Stability-Enhancing Underlayer For Exchange-Coupled Magnetic Structures, Magnetoresistive Sensors, And Magnetic Disk Drive Systems

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US Patent:
20020154456, Oct 24, 2002
Filed:
Apr 24, 2001
Appl. No.:
09/841942
Inventors:
Matthew Carey - San Jose CA, US
Eric Fullerton - Morgan Hill CA, US
Bruce Gurney - San Rafael CA, US
Thai Le - San Jose CA, US
Stefan Maat - San Jose CA, US
Philip Rice - San Jose CA, US
International Classification:
G11B005/39
US Classification:
360/324110, 360/324120, 360/324200
Abstract:
An exchange-coupled magnetic structure includes a ferromagnetic layer, a coercive ferrite layer, such as cobalt-ferrite, for biasing the magnetization of the ferromagnetic layer, and an oxide underlayer, such as cobalt-oxide, in proximity to the coercive ferrite layer. The oxide underlayer has a lattice structure of either rock salt or a spinel and exhibits no magnetic moment at room temperature. The underlayer affects the structure of the coercive ferrite layer and therefore its magnetic properties, providing increased coercivity and enhanced thermal stability. As a result, the coercive ferrite layer is thermally stable at much smaller thicknesses than without the underlayer. The exchange-coupled structure is used in spin valve and magnetic tunnel junction magnetoresistive sensors in read heads of magnetic disk drive systems. Because the coercive ferrite layer can be made as thin as 1 nm while remaining thermally stable, the sensor satisfies the narrow gap requirements of high recording density systems.

Stability-Enhancing Underlayer For Exchange-Coupled Magnetic Structures, Magnetoresistive Sensors, And Magnetic Disk Drive Systems

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US Patent:
20050036244, Feb 17, 2005
Filed:
Sep 27, 2004
Appl. No.:
10/951397
Inventors:
Matthew Carey - San Jose CA, US
Eric Fullerton - Morgan Hill CA, US
Bruce Gurney - San Rafael CA, US
Thai Le - San Jose CA, US
Stefan Maat - San Jose CA, US
Philip Rice - San Jose CA, US
International Classification:
G11B005/127
G11B005/33
US Classification:
360324120
Abstract:
An exchange-coupled magnetic structure includes a ferromagnetic layer, a coercive ferrite layer, such as cobalt-ferrite, for biasing the magnetization of the ferromagnetic layer, and an oxide underlayer, such as cobalt-oxide, in proximity to the coercive ferrite layer. The oxide underlayer has a lattice structure of either rock salt or a spinel and exhibits no magnetic moment at room temperature. The underlayer affects the structure of the coercive ferrite layer and therefore its magnetic properties, providing increased coercivity and enhanced thermal stability. As a result, the coercive ferrite layer is thermally stable at much smaller thicknesses than without the underlayer. The exchange-coupled structure is used in spin valve and magnetic tunnel junction magnetoresistive sensors in read heads of magnetic disk drive systems. Because the coercive ferrite layer can be made as thin as 1 nm while remaining thermally stable, the sensor satisfies the narrow gap requirements of high recording density systems.
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Thai Minh Le from Allen, TX, age ~58 Get Report