Time-Resolved Tomographic Quantification of the Microstructural Evolution of Ice Cream

Jingyi Mo; Enyu Guo; D. Mccartney; David Eastwood; Julian Bent; Gerard Van Dalen; Peter Schuetz; Peter Rockett; Peter Lee

doi:10.3390/ma11102031

Time-Resolved Tomographic Quantification of the Microstructural Evolution of Ice Cream

Jingyi Mo, Enyu Guo, D. Mccartney, David Eastwood, Julian Bent, Gerard Van Dalen, Peter Schuetz, Peter Rockett, Peter Lee

Research output: Contribution to journal › Article › peer-review

Abstract

Ice cream is a complex multi-phase colloidal soft-solid and its three-dimensional microstructure plays a critical role in determining the oral sensory experience or mouthfeel. Using in-line phase contrast synchrotron X-ray tomography, we capture the rapid evolution of the ice cream microstructure during heat shock conditions in situ and operando, on a time scale of minutes. The further evolution of the ice cream microstructure during storage and abuse was captured using ex situ tomography on a time scale of days. The morphology of the ice crystals and unfrozen matrix during these thermal cycles was quantified as an indicator for the texture and oral sensory perception. Our results reveal that the coarsening is due to both Ostwald ripening and physical agglomeration, enhancing our understanding of the microstructural evolution of ice cream during both manufacturing and storage. The microstructural evolution of this complex material was quantified, providing new insights into the behavior of soft-solids and semi-solids, including many foodstuffs, and invaluable data to both inform and validate models of their processing.

Original language	English
Pages (from-to)	2031
Journal	Materials
Volume	11
Issue number	10
Early online date	19 Oct 2018
DOIs	https://doi.org/10.3390/ma11102031
Publication status	Published - 2018

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10.3390/ma11102031Licence: CC BY

http://www.mdpi.com/1996-1944/11/10/2031

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1 Active

UoMaH: The University of Manchester at Harwell
Lawrence, J. (PI), Burnett, T. (PI), Baker, M. (Researcher), Eastwood, D. (Researcher), Falkowska, M. (Researcher), Freitas, D. (Researcher), Hunt, S. (Researcher), Khan, A. (Researcher), Lane, H. (Researcher), Lezcano Gonzalez, I. (Researcher), Ma, L. (Researcher), Mirihanage, W. (Researcher), Parlett, C. (Researcher), Xu, S. (Researcher), Yan, K. (Researcher), Reinhard, C. (Support team), Duggins, D. (Technical team), Lewis-Fell, J. (Technical team), Nonni, S. (Technical team), Rollings, B. (Technical team), Sinclair, L. (Technical team) & Batts, S. (Support team)
1/01/18 → …
Project: Other
Structural Evolution across multiple time and length scales
Withers, P. (PI), Cartmell, S. (CoI), Cernik, R. (CoI), Derby, B. (CoI), Eichhorn, S. (CoI), Freemont, A. (CoI), Hollis, C. (CoI), Mummery, P. (CoI), Sherratt, M. (CoI), Thompson, G. (CoI) & Watts, D. (CoI)
1/06/11 → 31/05/16
Project: Research

Cite this

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title = "Time-Resolved Tomographic Quantification of the Microstructural Evolution of Ice Cream",

abstract = "Ice cream is a complex multi-phase colloidal soft-solid and its three-dimensional microstructure plays a critical role in determining the oral sensory experience or mouthfeel. Using in-line phase contrast synchrotron X-ray tomography, we capture the rapid evolution of the ice cream microstructure during heat shock conditions in situ and operando, on a time scale of minutes. The further evolution of the ice cream microstructure during storage and abuse was captured using ex situ tomography on a time scale of days. The morphology of the ice crystals and unfrozen matrix during these thermal cycles was quantified as an indicator for the texture and oral sensory perception. Our results reveal that the coarsening is due to both Ostwald ripening and physical agglomeration, enhancing our understanding of the microstructural evolution of ice cream during both manufacturing and storage. The microstructural evolution of this complex material was quantified, providing new insights into the behavior of soft-solids and semi-solids, including many foodstuffs, and invaluable data to both inform and validate models of their processing. ",

author = "Jingyi Mo and Enyu Guo and D. Mccartney and David Eastwood and Julian Bent and {Van Dalen}, Gerard and Peter Schuetz and Peter Rockett and Peter Lee",

year = "2018",

doi = "10.3390/ma11102031",

language = "English",

volume = "11",

pages = "2031",

journal = "Materials",

issn = "1996-1944",

publisher = "MDPI",

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T1 - Time-Resolved Tomographic Quantification of the Microstructural Evolution of Ice Cream

AU - Mo, Jingyi

AU - Guo, Enyu

AU - Mccartney, D.

AU - Eastwood, David

AU - Bent, Julian

AU - Van Dalen, Gerard

AU - Schuetz, Peter

AU - Rockett, Peter

AU - Lee, Peter

PY - 2018

Y1 - 2018

N2 - Ice cream is a complex multi-phase colloidal soft-solid and its three-dimensional microstructure plays a critical role in determining the oral sensory experience or mouthfeel. Using in-line phase contrast synchrotron X-ray tomography, we capture the rapid evolution of the ice cream microstructure during heat shock conditions in situ and operando, on a time scale of minutes. The further evolution of the ice cream microstructure during storage and abuse was captured using ex situ tomography on a time scale of days. The morphology of the ice crystals and unfrozen matrix during these thermal cycles was quantified as an indicator for the texture and oral sensory perception. Our results reveal that the coarsening is due to both Ostwald ripening and physical agglomeration, enhancing our understanding of the microstructural evolution of ice cream during both manufacturing and storage. The microstructural evolution of this complex material was quantified, providing new insights into the behavior of soft-solids and semi-solids, including many foodstuffs, and invaluable data to both inform and validate models of their processing.

AB - Ice cream is a complex multi-phase colloidal soft-solid and its three-dimensional microstructure plays a critical role in determining the oral sensory experience or mouthfeel. Using in-line phase contrast synchrotron X-ray tomography, we capture the rapid evolution of the ice cream microstructure during heat shock conditions in situ and operando, on a time scale of minutes. The further evolution of the ice cream microstructure during storage and abuse was captured using ex situ tomography on a time scale of days. The morphology of the ice crystals and unfrozen matrix during these thermal cycles was quantified as an indicator for the texture and oral sensory perception. Our results reveal that the coarsening is due to both Ostwald ripening and physical agglomeration, enhancing our understanding of the microstructural evolution of ice cream during both manufacturing and storage. The microstructural evolution of this complex material was quantified, providing new insights into the behavior of soft-solids and semi-solids, including many foodstuffs, and invaluable data to both inform and validate models of their processing.

U2 - 10.3390/ma11102031

DO - 10.3390/ma11102031

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SN - 1996-1944

VL - 11

SP - 2031

JO - Materials

JF - Materials

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Time-Resolved Tomographic Quantification of the Microstructural Evolution of Ice Cream

Abstract

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UoMaH: The University of Manchester at Harwell

Structural Evolution across multiple time and length scales

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