Describing the firmness, springiness and rubberiness of food gels using fractional calculus. Part II: Measurements on semi-hard cheese

Author(s)

Faber, T.J.; Jaishankar, Aditya; McKinley, Gareth H

Abstract

We use the framework of fractional calculus to quantify the linear viscoelastic properties of full-fat, low-fat, and zero-fat, semi-hard cheeses over a range of temperatures and water/protein ratios. These fractional constitutive models correctly predict the time-dependence and interrelation of the firmness, springiness, and rubberiness of these emulsion-filled hydrocolloidal gels. Our equations for the firmness F, springiness S, and rubberiness R, also correctly predict the effect of changing the magnitude or time-scale of the stress loading on the material even in the case of irreversible flow events, when cheese progressively transitions from a solid to a liquid. Finally we show how our FSR-equations can be used in a texture engineering context; they provide rational guidance to product reformulation studies and allow for extrapolation of a firmness measurement to practical situations in which the gel is subjected to prolonged creep loading. Keywords Rational reformulation Food gels Structure-texture engineering Constitutive model Fractional calculus Scott Blair

Date issued

2016-07

URI

http://hdl.handle.net/1721.1/113213

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Food Hydrocolloids

Publisher

Elsevier

Citation

Faber, T.J. et al. “Describing the Firmness, Springiness and Rubberiness of Food Gels Using Fractional Calculus. Part II: Measurements on Semi-Hard Cheese.” Food Hydrocolloids 62 (January 2017): 325–339 © 2016 Elsevier Ltd

Version: Author's final manuscript

ISSN

0268-005X