Air bubbles in calcium caseinate fibrous material enhances anisotropy

Air bubbles in calcium caseinate fibrous material enhances anisotropy

Dense calcium caseinate dispersions can be transformed into hierarchically fibrous structures by shear deformation. This transformation can be attributed to the intrinsic properties of calcium caseinate. Depending on the dispersion preparation method, a certain amount of air gets entrapped in the sheared protein matrix. Although anisotropy is obtained in the absence of entrapped air, the fibrous appearance and mechanical anisotropy of the calcium caseinate materials are more pronounced with dispersed air present. The presence of air induces the protein fibers to be arranged in microscale bundles, and the fracture strain and stress in the parallel direction are larger compared with the material without air. The effects can be understood from the alignment of the fibers in the parallel direction, providing strain energy dissipation. This study shows that creation of anisotropy is the result of interactions between multiple phases.

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Main Authors: Wang, Zhaojun, Tian, Bei, Boom, Remko, van der Goot, Atze Jan
Format: Article/Letter to editor biblioteca
Language:English
Subjects:Air bubble, Anisotropy, Fibrous material, Mechanical property, Microstructure,
Online Access:https://research.wur.nl/en/publications/air-bubbles-in-calcium-caseinate-fibrous-material-enhances-anisot
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spelling dig-wur-nl-wurpubs-5409422024-12-04 Wang, Zhaojun Tian, Bei Boom, Remko van der Goot, Atze Jan Article/Letter to editor Food Hydrocolloids 87 (2019) ISSN: 0268-005X Air bubbles in calcium caseinate fibrous material enhances anisotropy 2019 Dense calcium caseinate dispersions can be transformed into hierarchically fibrous structures by shear deformation. This transformation can be attributed to the intrinsic properties of calcium caseinate. Depending on the dispersion preparation method, a certain amount of air gets entrapped in the sheared protein matrix. Although anisotropy is obtained in the absence of entrapped air, the fibrous appearance and mechanical anisotropy of the calcium caseinate materials are more pronounced with dispersed air present. The presence of air induces the protein fibers to be arranged in microscale bundles, and the fracture strain and stress in the parallel direction are larger compared with the material without air. The effects can be understood from the alignment of the fibers in the parallel direction, providing strain energy dissipation. This study shows that creation of anisotropy is the result of interactions between multiple phases. en application/pdf https://research.wur.nl/en/publications/air-bubbles-in-calcium-caseinate-fibrous-material-enhances-anisot 10.1016/j.foodhyd.2018.08.037 https://edepot.wur.nl/459135 Air bubble Anisotropy Fibrous material Mechanical property Microstructure https://creativecommons.org/licenses/by-nc-nd/4.0/ Wageningen University & Research
institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic Air bubble
Anisotropy
Fibrous material
Mechanical property
Microstructure
Air bubble
Anisotropy
Fibrous material
Mechanical property
Microstructure
spellingShingle Air bubble
Anisotropy
Fibrous material
Mechanical property
Microstructure
Air bubble
Anisotropy
Fibrous material
Mechanical property
Microstructure
Wang, Zhaojun
Tian, Bei
Boom, Remko
van der Goot, Atze Jan
Air bubbles in calcium caseinate fibrous material enhances anisotropy
description Dense calcium caseinate dispersions can be transformed into hierarchically fibrous structures by shear deformation. This transformation can be attributed to the intrinsic properties of calcium caseinate. Depending on the dispersion preparation method, a certain amount of air gets entrapped in the sheared protein matrix. Although anisotropy is obtained in the absence of entrapped air, the fibrous appearance and mechanical anisotropy of the calcium caseinate materials are more pronounced with dispersed air present. The presence of air induces the protein fibers to be arranged in microscale bundles, and the fracture strain and stress in the parallel direction are larger compared with the material without air. The effects can be understood from the alignment of the fibers in the parallel direction, providing strain energy dissipation. This study shows that creation of anisotropy is the result of interactions between multiple phases.
format Article/Letter to editor
topic_facet Air bubble
Anisotropy
Fibrous material
Mechanical property
Microstructure
author Wang, Zhaojun
Tian, Bei
Boom, Remko
van der Goot, Atze Jan
author_facet Wang, Zhaojun
Tian, Bei
Boom, Remko
van der Goot, Atze Jan
author_sort Wang, Zhaojun
title Air bubbles in calcium caseinate fibrous material enhances anisotropy
title_short Air bubbles in calcium caseinate fibrous material enhances anisotropy
title_full Air bubbles in calcium caseinate fibrous material enhances anisotropy
title_fullStr Air bubbles in calcium caseinate fibrous material enhances anisotropy
title_full_unstemmed Air bubbles in calcium caseinate fibrous material enhances anisotropy
title_sort air bubbles in calcium caseinate fibrous material enhances anisotropy
url https://research.wur.nl/en/publications/air-bubbles-in-calcium-caseinate-fibrous-material-enhances-anisot
work_keys_str_mv AT wangzhaojun airbubblesincalciumcaseinatefibrousmaterialenhancesanisotropy
AT tianbei airbubblesincalciumcaseinatefibrousmaterialenhancesanisotropy
AT boomremko airbubblesincalciumcaseinatefibrousmaterialenhancesanisotropy
AT vandergootatzejan airbubblesincalciumcaseinatefibrousmaterialenhancesanisotropy
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