Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces

Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces

Adhesion has significant impacts in life sciences, such as, cell adhesion, bacterial aggregation and drug delivery vesicles in micro-scale, and contact lens adhesion in macro-scale. In order to quantify adhesion, several classical models for solid adhesion were constructed and widely adopted by the...

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Online Access:http://hdl.handle.net/2047/D20406222
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spelling ndltd-NEU--neu-16102021-05-25T05:10:02ZAdhesion-detachment mechanics of thin shells in the presence of intrinsic surface forcesAdhesion has significant impacts in life sciences, such as, cell adhesion, bacterial aggregation and drug delivery vesicles in micro-scale, and contact lens adhesion in macro-scale. In order to quantify adhesion, several classical models for solid adhesion were constructed and widely adopted by the scientific community over the past decades, such as the celebrated Johnson-Kendall-Roberts (JKR), Derjaguin-Muller-Toporov (DMT), and the Tabor-Muller-Maugisfs JKR-DMT transition models. However, nano-shells / particles, vesicles and biological cells are shells instead of solid spheres, rendering the classical models invalid. A new mechanics model is necessary for shell adhesion.http://hdl.handle.net/2047/D20406222
collection NDLTD
sources NDLTD
description Adhesion has significant impacts in life sciences, such as, cell adhesion, bacterial aggregation and drug delivery vesicles in micro-scale, and contact lens adhesion in macro-scale. In order to quantify adhesion, several classical models for solid adhesion were constructed and widely adopted by the scientific community over the past decades, such as the celebrated Johnson-Kendall-Roberts (JKR), Derjaguin-Muller-Toporov (DMT), and the Tabor-Muller-Maugisfs JKR-DMT transition models. However, nano-shells / particles, vesicles and biological cells are shells instead of solid spheres, rendering the classical models invalid. A new mechanics model is necessary for shell adhesion.
title Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
spellingShingle Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
title_short Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
title_full Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
title_fullStr Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
title_full_unstemmed Adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
title_sort adhesion-detachment mechanics of thin shells in the presence of intrinsic surface forces
publishDate
url http://hdl.handle.net/2047/D20406222
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