Modelling of nanoparticle sintering under electrical boundary conditions

A. T. Alastalo; H. Seppä; J. H. Leppäniemi; M. J. Aronniemi; M. L. Allen; T. Mattila

doi:10.1088/0022-3727/43/48/485501

Modelling of nanoparticle sintering under electrical boundary conditions

A. T. Alastalo, H. Seppä, J. H. Leppäniemi, M. J. Aronniemi, M. L. Allen, T. Mattila

Tutkimustuotos: Lehtiartikkeli › Article › Scientific › vertaisarvioitu

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A statistical model for sintering of solution-processed electrically conducting nanoparticle structures is developed. The model considers thermal expansion of the particles under Joule heating as the driving force of the process. The results are used to explain the fast resistance transition observed for the recently reported rapid electrical sintering process. A comparison with experimental results shows good agreement for the kinetics of the process. A heat-equation solution is also derived for a generic geometry of a printed conductor. This provides a basis for further refinements of the model to take other driving mechanisms, such as diffusion and inter-particle forces, into account. The results of this paper help in developing quantitative understanding of the physical processes that are relevant in nanoparticle sintering.

Alkuperäiskieli	Englanti
Artikkeli	485501
Julkaisu	Journal of Physics D: Applied Physics
Vuosikerta	43
Numero	48
DOI - pysyväislinkit	https://doi.org/10.1088/0022-3727/43/48/485501
Tila	Julkaistu - 8 jouluk. 2010
OKM-julkaisutyyppi	A1 Julkaistu artikkeli, soviteltu

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10.1088/0022-3727/43/48/485501

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title = "Modelling of nanoparticle sintering under electrical boundary conditions",

abstract = "A statistical model for sintering of solution-processed electrically conducting nanoparticle structures is developed. The model considers thermal expansion of the particles under Joule heating as the driving force of the process. The results are used to explain the fast resistance transition observed for the recently reported rapid electrical sintering process. A comparison with experimental results shows good agreement for the kinetics of the process. A heat-equation solution is also derived for a generic geometry of a printed conductor. This provides a basis for further refinements of the model to take other driving mechanisms, such as diffusion and inter-particle forces, into account. The results of this paper help in developing quantitative understanding of the physical processes that are relevant in nanoparticle sintering.",

author = "Alastalo, {A. T.} and H. Sepp{\"a} and Lepp{\"a}niemi, {J. H.} and Aronniemi, {M. J.} and Allen, {M. L.} and T. Mattila",

year = "2010",

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doi = "10.1088/0022-3727/43/48/485501",

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T1 - Modelling of nanoparticle sintering under electrical boundary conditions

AU - Alastalo, A. T.

AU - Seppä, H.

AU - Leppäniemi, J. H.

AU - Aronniemi, M. J.

AU - Allen, M. L.

AU - Mattila, T.

PY - 2010/12/8

Y1 - 2010/12/8

N2 - A statistical model for sintering of solution-processed electrically conducting nanoparticle structures is developed. The model considers thermal expansion of the particles under Joule heating as the driving force of the process. The results are used to explain the fast resistance transition observed for the recently reported rapid electrical sintering process. A comparison with experimental results shows good agreement for the kinetics of the process. A heat-equation solution is also derived for a generic geometry of a printed conductor. This provides a basis for further refinements of the model to take other driving mechanisms, such as diffusion and inter-particle forces, into account. The results of this paper help in developing quantitative understanding of the physical processes that are relevant in nanoparticle sintering.

AB - A statistical model for sintering of solution-processed electrically conducting nanoparticle structures is developed. The model considers thermal expansion of the particles under Joule heating as the driving force of the process. The results are used to explain the fast resistance transition observed for the recently reported rapid electrical sintering process. A comparison with experimental results shows good agreement for the kinetics of the process. A heat-equation solution is also derived for a generic geometry of a printed conductor. This provides a basis for further refinements of the model to take other driving mechanisms, such as diffusion and inter-particle forces, into account. The results of this paper help in developing quantitative understanding of the physical processes that are relevant in nanoparticle sintering.

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U2 - 10.1088/0022-3727/43/48/485501

DO - 10.1088/0022-3727/43/48/485501

M3 - Article

AN - SCOPUS:78650100612

VL - 43

JO - Journal of Physics D - Applied Physics

JF - Journal of Physics D - Applied Physics

SN - 0022-3727

IS - 48

M1 - 485501

ER -

Modelling of nanoparticle sintering under electrical boundary conditions

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