Thermal finite difference analysis of threshold heating for nanoscale machining

Chris A. Trinkle; Phil Smith; R. Ryan Vallance; Basil T. Wong; M. Pinar Mengüç

doi:10.1115/IMECE2002-39377

Thermal finite difference analysis of threshold heating for nanoscale machining

Chris A. Trinkle, Phil Smith, R. Ryan Vallance, Basil T. Wong, M. Pinar Mengüç

Mechanical and Aerospace Engineering

Research output: Contribution to conference › Paper › peer-review

Abstract

We are investigating a new manufacturing process utilizing Threshold Heating and Emission from Nanotubes (THEN) to remove clusters of atoms from workpiece surfaces. A pulsed laser will locally heat a workpiece to the threshold temperature, and then electrons emitted from nanotube tips will create nanoscale features within the heated zone. This paper concentrates on modeling the temperature distribution in the workpiece caused by radiation and conduction transfer. Our finite difference model considers a Gaussian laser beam radiating through a transparent substrate onto a metallic workpiece layer. The finite difference model will eventually be integrated with thermal models of electron emission and absorption to achieve a complete model of the THEN process.

Original language	English
Pages	507-513
Number of pages	7
DOIs	https://doi.org/10.1115/IMECE2002-39377
State	Published - 2002
Event	2002 ASME International Mechanical Engineering Congress and Exposition - New Orleans, LA, United States Duration: Nov 17 2002 → Nov 22 2002

Conference

Conference	2002 ASME International Mechanical Engineering Congress and Exposition
Country/Territory	United States
City	New Orleans, LA
Period	11/17/02 → 11/22/02

ASJC Scopus subject areas

Mechanical Engineering
Electrical and Electronic Engineering

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10.1115/IMECE2002-39377

Cite this

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title = "Thermal finite difference analysis of threshold heating for nanoscale machining",

abstract = "We are investigating a new manufacturing process utilizing Threshold Heating and Emission from Nanotubes (THEN) to remove clusters of atoms from workpiece surfaces. A pulsed laser will locally heat a workpiece to the threshold temperature, and then electrons emitted from nanotube tips will create nanoscale features within the heated zone. This paper concentrates on modeling the temperature distribution in the workpiece caused by radiation and conduction transfer. Our finite difference model considers a Gaussian laser beam radiating through a transparent substrate onto a metallic workpiece layer. The finite difference model will eventually be integrated with thermal models of electron emission and absorption to achieve a complete model of the THEN process.",

author = "Trinkle, {Chris A.} and Phil Smith and Vallance, {R. Ryan} and Wong, {Basil T.} and Meng{\"u}{\c c}, {M. Pinar}",

year = "2002",

doi = "10.1115/IMECE2002-39377",

language = "English",

pages = "507--513",

note = "2002 ASME International Mechanical Engineering Congress and Exposition ; Conference date: 17-11-2002 Through 22-11-2002",

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AU - Trinkle, Chris A.

AU - Smith, Phil

AU - Vallance, R. Ryan

AU - Wong, Basil T.

AU - Mengüç, M. Pinar

PY - 2002

Y1 - 2002

N2 - We are investigating a new manufacturing process utilizing Threshold Heating and Emission from Nanotubes (THEN) to remove clusters of atoms from workpiece surfaces. A pulsed laser will locally heat a workpiece to the threshold temperature, and then electrons emitted from nanotube tips will create nanoscale features within the heated zone. This paper concentrates on modeling the temperature distribution in the workpiece caused by radiation and conduction transfer. Our finite difference model considers a Gaussian laser beam radiating through a transparent substrate onto a metallic workpiece layer. The finite difference model will eventually be integrated with thermal models of electron emission and absorption to achieve a complete model of the THEN process.

AB - We are investigating a new manufacturing process utilizing Threshold Heating and Emission from Nanotubes (THEN) to remove clusters of atoms from workpiece surfaces. A pulsed laser will locally heat a workpiece to the threshold temperature, and then electrons emitted from nanotube tips will create nanoscale features within the heated zone. This paper concentrates on modeling the temperature distribution in the workpiece caused by radiation and conduction transfer. Our finite difference model considers a Gaussian laser beam radiating through a transparent substrate onto a metallic workpiece layer. The finite difference model will eventually be integrated with thermal models of electron emission and absorption to achieve a complete model of the THEN process.

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T2 - 2002 ASME International Mechanical Engineering Congress and Exposition

Y2 - 17 November 2002 through 22 November 2002

ER -

Thermal finite difference analysis of threshold heating for nanoscale machining

Abstract

Conference

ASJC Scopus subject areas

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