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From: Heat Conduction in Nanofluid Suspensions

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1 From: Heat Conduction in Nanofluid Suspensions
Date of download: 10/30/2017 Copyright © ASME. All rights reserved. From: Heat Conduction in Nanofluid Suspensions J. Heat Transfer. 2005;128(5): doi: / Figure Legend: The dimensionless wire temperature corresponding to the Fourier as well as the DuPhlag solutions as a function of time, on a logarithmic time scale, for a Fourier number of Foq=10−6 and for copper nanoparticles suspended in ethylene glycol. Detail of the transient solution for the time range 0.5s<t*<5s.

2 From: Heat Conduction in Nanofluid Suspensions
Date of download: 10/30/2017 Copyright © ASME. All rights reserved. From: Heat Conduction in Nanofluid Suspensions J. Heat Transfer. 2005;128(5): doi: / Figure Legend: The dimensionless wire temperature corresponding to the Fourier as well as the DuPhlag solutions as a function of time, on a logarithmic time scale, for a Fourier number of Foq=10−5 and for carbon nanotubes suspended in oil. Detail within the time range 0.5s<t*<5s.

3 From: Heat Conduction in Nanofluid Suspensions
Date of download: 10/30/2017 Copyright © ASME. All rights reserved. From: Heat Conduction in Nanofluid Suspensions J. Heat Transfer. 2005;128(5): doi: / Figure Legend: The dimensionless wire temperature corresponding to the Fourier as well as the DuPhlag solutions as a function of time, on a logarithmic time scale, for a Fourier number of Foq=10−6 and for for carbon nanotubes suspended in oil. Detail within the time range 0.5s<t*<5s.

4 From: Heat Conduction in Nanofluid Suspensions
Date of download: 10/30/2017 Copyright © ASME. All rights reserved. From: Heat Conduction in Nanofluid Suspensions J. Heat Transfer. 2005;128(5): doi: / Figure Legend: The ratio between the “apparent” and “actual” effective thermal conductivities following Eq. and corresponding to copper nanoparticles suspended in ethylene glycol compared with carbon nanotubes suspended in oil for a Fourier number of Foq=10−4

5 From: Heat Conduction in Nanofluid Suspensions
Date of download: 10/30/2017 Copyright © ASME. All rights reserved. From: Heat Conduction in Nanofluid Suspensions J. Heat Transfer. 2005;128(5): doi: / Figure Legend: The ratio between the “apparent” and “actual” effective thermal conductivities following Eq. and corresponding to copper nanoparticles suspended in ethylene glycol compared to carbon nanotubes suspended in oil for a Fourier number of Foq=10−5

6 From: Heat Conduction in Nanofluid Suspensions
Date of download: 10/30/2017 Copyright © ASME. All rights reserved. From: Heat Conduction in Nanofluid Suspensions J. Heat Transfer. 2005;128(5): doi: / Figure Legend: The ratio between the “apparent” and “actual” effective thermal conductivities following Eq. and corresponding to copper nanoparticles suspended in ethylene glycol compared with carbon nanotubes suspended in oil for a Fourier number of Foq=10−6

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