Effects of tensile stress on the resonant response of Al thin-film and Al-CNT nanolaminate nanomechanical beam resonators

We report on the dependence of resonant response to applied tensile stress in Al and Al-CNT (carbon nanotube) nanolaminate thin-film nanomechanical beam resonators. We optically measure the dynamic flexural response, while a chip-bending method is utilized to apply a static tension along its axis. F...

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Published inCurrent applied physics Vol. 11; no. 3; pp. 746 - 749
Main Authors Yi, Yun Jeong, Kim, Young Duck, Bak, Jung Hoon, Lee, Seung Ran, Heo, Kwang, Hong, Seunghun, Char, Kookrin, Park, Yun Daniel
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.05.2011
한국물리학회
Subjects
Aluminum
Beams (radiation)
Carbon nanotube composites
carbon nanotubes
Elastic modulus
Nanocomposites
Nanomaterials
Nanomechanical resonators
Nanostructure
NEMS
physics
Resonant frequencies
Resonant response
Resonators
Tensile stress
Thin films
물리학
Carbon nanotube composites
Elastic modulus
NEMS
Nanomechanical resonators
Resonant response
Online AccessGet full text
ISSN1567-1739
1878-1675
DOI10.1016/j.cap.2010.11.054

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Abstract We report on the dependence of resonant response to applied tensile stress in Al and Al-CNT (carbon nanotube) nanolaminate thin-film nanomechanical beam resonators. We optically measure the dynamic flexural response, while a chip-bending method is utilized to apply a static tension along its axis. For Al thin-film resonators, large and reversible increases in the resonant frequencies are observed along with near doubling of the resonator quality factor; while, for Al-CNT, largely unaffected with a slight decrease in resonant frequencies. Such behavior gives an insight on the role of CNT as a structural reinforcement in the Al thin-film based nanolaminate. ► Realized Al and Al-CNT nanolaminate nanomechanical beam resonators. ► Optically measured resonant frequency and Q-factor of Al and Al-CNT beam resonators. ► Chip-bending method is utilized to apply a tensile stress along beam axis.► Al shows large reversible increase in resonant frequency and Q-factor increase. ► Al-CNT shows slight decreasing in resonant frequencies and Q-factor.
AbstractList We report on the dependence of resonant response to applied tensile stress in Al and Al-CNT (carbon nanotube) nanolaminate thin-film nanomechanical beam resonators. We optically measure the dynamic flexural response, while a chip-bending method is utilized to apply a static tension along its axis. For Al thin-film resonators, large and reversible increases in the resonant frequencies are observed along with near doubling of the resonator quality factor; while, for Al-CNT, largely unaffected with a slight decrease in resonant frequencies. Such behavior gives an insight on the role of CNT as a structural reinforcement in the Al thin-film based nanolaminate. KCI Citation Count: 3
We report on the dependence of resonant response to applied tensile stress in Al and Al-CNT (carbon nanotube) nanolaminate thin-film nanomechanical beam resonators. We optically measure the dynamic flexural response, while a chip-bending method is utilized to apply a static tension along its axis. For Al thin-film resonators, large and reversible increases in the resonant frequencies are observed along with near doubling of the resonator quality factor; while, for Al-CNT, largely unaffected with a slight decrease in resonant frequencies. Such behavior gives an insight on the role of CNT as a structural reinforcement in the Al thin-film based nanolaminate. ► Realized Al and Al-CNT nanolaminate nanomechanical beam resonators. ► Optically measured resonant frequency and Q-factor of Al and Al-CNT beam resonators. ► Chip-bending method is utilized to apply a tensile stress along beam axis.► Al shows large reversible increase in resonant frequency and Q-factor increase. ► Al-CNT shows slight decreasing in resonant frequencies and Q-factor.
We report on the dependence of resonant response to applied tensile stress in Al and Al-CNT (carbon nanotube) nanolaminate thin-film nanomechanical beam resonators. We optically measure the dynamic flexural response, while a chip-bending method is utilized to apply a static tension along its axis. For Al thin-film resonators, large and reversible increases in the resonant frequencies are observed along with near doubling of the resonator quality factor; while, for Al-CNT, largely unaffected with a slight decrease in resonant frequencies. Such behavior gives an insight on the role of CNT as a structural reinforcement in the Al thin-film based nanolaminate.
Author Park, Yun Daniel
Bak, Jung Hoon
Lee, Seung Ran
Heo, Kwang
Hong, Seunghun
Char, Kookrin
Yi, Yun Jeong
Kim, Young Duck
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Elastic modulus
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Snippet We report on the dependence of resonant response to applied tensile stress in Al and Al-CNT (carbon nanotube) nanolaminate thin-film nanomechanical beam...
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SubjectTerms Aluminum
Beams (radiation)
Carbon nanotube composites
carbon nanotubes
Elastic modulus
Nanocomposites
Nanomaterials
Nanomechanical resonators
Nanostructure
NEMS
physics
Resonant frequencies
Resonant response
Resonators
Tensile stress
Thin films
물리학
Title Effects of tensile stress on the resonant response of Al thin-film and Al-CNT nanolaminate nanomechanical beam resonators
URI https://dx.doi.org/10.1016/j.cap.2010.11.054
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