A direct quantitative measure of surface mobility in a glassy polymer

Y. Chai; T. Salez; J. D. McGraw; M. Benzaquen; K. Dalnoki-Veress; E. Raphaël; J. A. Forrest

doi:10.1126/science.1244845

A direct quantitative measure of surface mobility in a glassy polymer

Y. Chai
, T. Salez
, J. D. McGraw
, M. Benzaquen
, K. Dalnoki-Veress
, E. Raphaël
, J. A. Forrest

University of Waterloo
PSL Research University
McMaster University
Universität des Saarlandes
Perimeter Institute for Theoretical Physics

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Thin polymer films have striking dynamical properties that differ from their bulk counterparts. With the simple geometry of a stepped polymer film on a substrate, we probe mobility above and below the glass transition temperature T_g. Above T_g the entire film flows, whereas below T _g only the near-surface region responds to the excess interfacial energy. An analytical thin-film model for flow limited to the free surface region shows excellent agreement with sub-T_g data. The system transitions from whole-film flow to surface localized flow over a narrow temperature region near the bulk T_g. The experiments and model provide a measure of surface mobility in a simple geometry where confinement and substrate effects are negligible. This fine control of the glassy rheology is of key interest to nanolithography among numerous other applications.

langue originale	Anglais
Pages (de - à)	994-999
Nombre de pages	6
journal	Science
Volume	343
Numéro de publication	6174
Les DOIs	https://doi.org/10.1126/science.1244845
état	Publié - 1 janv. 2014
Modification externe	Oui

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10.1126/science.1244845

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abstract = "Thin polymer films have striking dynamical properties that differ from their bulk counterparts. With the simple geometry of a stepped polymer film on a substrate, we probe mobility above and below the glass transition temperature Tg. Above Tg the entire film flows, whereas below T g only the near-surface region responds to the excess interfacial energy. An analytical thin-film model for flow limited to the free surface region shows excellent agreement with sub-Tg data. The system transitions from whole-film flow to surface localized flow over a narrow temperature region near the bulk Tg. The experiments and model provide a measure of surface mobility in a simple geometry where confinement and substrate effects are negligible. This fine control of the glassy rheology is of key interest to nanolithography among numerous other applications.",

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AU - Chai, Y.

AU - Salez, T.

AU - McGraw, J. D.

AU - Benzaquen, M.

AU - Dalnoki-Veress, K.

AU - Raphaël, E.

AU - Forrest, J. A.

PY - 2014/1/1

Y1 - 2014/1/1

N2 - Thin polymer films have striking dynamical properties that differ from their bulk counterparts. With the simple geometry of a stepped polymer film on a substrate, we probe mobility above and below the glass transition temperature Tg. Above Tg the entire film flows, whereas below T g only the near-surface region responds to the excess interfacial energy. An analytical thin-film model for flow limited to the free surface region shows excellent agreement with sub-Tg data. The system transitions from whole-film flow to surface localized flow over a narrow temperature region near the bulk Tg. The experiments and model provide a measure of surface mobility in a simple geometry where confinement and substrate effects are negligible. This fine control of the glassy rheology is of key interest to nanolithography among numerous other applications.

AB - Thin polymer films have striking dynamical properties that differ from their bulk counterparts. With the simple geometry of a stepped polymer film on a substrate, we probe mobility above and below the glass transition temperature Tg. Above Tg the entire film flows, whereas below T g only the near-surface region responds to the excess interfacial energy. An analytical thin-film model for flow limited to the free surface region shows excellent agreement with sub-Tg data. The system transitions from whole-film flow to surface localized flow over a narrow temperature region near the bulk Tg. The experiments and model provide a measure of surface mobility in a simple geometry where confinement and substrate effects are negligible. This fine control of the glassy rheology is of key interest to nanolithography among numerous other applications.

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VL - 343

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JO - Science

JF - Science

IS - 6174

ER -

A direct quantitative measure of surface mobility in a glassy polymer

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