Abstract
For the first time, the novel experimental technique Temperature Modulated Optical Refractometry (TMOR) was employed for cocoa butter thermal transitions characterization. The average refractive index (NMEAN), the volume (v) change, and the volumetric expansion coefficient () as well as the dynamic quantities and (real and imaginary volumetric expansion coefficient, respectively) were monitored during cooling and heating and compared to the heat flow curves obtained via the standard technique dynamic scanning calorimetry (DSC). The investigation of these quantities showed that TMOR analysis can yield not only thermal transitions temperatures that are comparable to DSC results, but also some new thermal events that are not detected by DSC. This outcome suggests that TMOR might provide some additional insights on cocoa butter melting and crystallization by means of frequency-dependent measurements due to temperature modulation. This new information that can be accessed during temperature ramps might provide a deeper insight into thermal behavior of fat-based foods, evidencing TMOR value as a tool for thermal transitions investigation.
Highlights
Chocolate is a dense suspension of solid particles arranged in a complex microstructure.Commercial chocolates are usually composed by approximately 70% of fine particles such as sugar, cocoa powder, and milk solids, which are dispersed in a fat continuous phase, mostly of cocoa butter (CB) [1,2]
We investigated for the first time the Temperature Modulated Optical Refractometry (TMOR) capacity to identify the melting transitions of CB
The melting and crystallization behavior of this industrially relevant lipid was investigated by TMOR and compared against the conventional dynamic scanning calorimetry (DSC) analysis
Summary
Chocolate is a dense suspension of solid particles arranged in a complex microstructure. The possibility to impose a sinusoidal modulation in temperature represents a significative gain with respect to conventional DSC analysis because it allows to study dynamic effects as well. We investigated for the first time the TMOR capacity to identify the melting transitions of CB To this end, the melting and crystallization behavior of this industrially relevant lipid was investigated by TMOR and compared against the conventional DSC analysis. Results showed that in addition to the thermal transition temperatures that agreed well with DSC, TMOR is able to probe some other thermal events that are not visible on DSC curves This outcome highlighted TMOR as an accurate and practical tool to investigate thermal transitions of some edible fats and open a large range of applications for this novel technique
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