Temperature dependency of the interaction between xanthan gum and sage seed gum: An interpretation of dynamic rheology and thixotropy based on creep test

The viscoelastic (transient and dynamic) and time‐dependent rheological behaviors of XG (xanthan gum), SSG (sage seed gum) and their blends at various ratios (1‐3, 1‐1, and 3‐1 SSG‐XG) and temperatures (10, 30, and 50C) were investigated using creep and recovery analyses. The creep compliance was converted to stress relaxation data; then, the structural kinetic model satisfactorily fitted the time‐dependent relaxation modulus. Furthermore, dynamic rheology of mixtures was investigated using creep analyses. The most important contribution of the Maxwell spring to deformation (53.51%), was that corresponding to the SSG at 50C and the most important contribution of the Maxwell dashpot to the maximum deformation, were those corresponding to the XG (61.44%) and 1‐3 SSG‐XG (58.91%) samples both at 50C. The breakdown rate constant ( α ) of the crosslinked gum structure in SSG and 3‐1 SSG‐XG under the application of external shear stress increases with temperature from 10 to 50C in the range of 0.14–0.32 (1/s) and 0.14–0.24 (1/s), respectively, whereas other dispersions showed the reverse trend. Among all dispersions, only XG and 1‐3 SSG‐XG demonstrated crossover frequency at 9.95 and 31.47 rad/s, respectively, at 50C, indicative of the lowest entanglement density for 1‐3 SSG‐XG. The greatest interaction between SSG and XG occurred for 3‐1 ratio at 50C, which was confirmed by the Han curves. Practical applications Hydrocolloid blends, particularly those consisting of xanthan gum and a galactomannan from new source can provide a range of attractive textural properties. Rheological studies contribute to the description of the molecular structure and prediction of the structural changes during their manufacturing processes. Sage seed gum (SSG), as a polyelectrolyte galactomannan, has a great potential to exert stabilizing, thickening, gelling and binding properties in food, cosmetics, and pharmaceutical systems. Therefore, we elaborate the interactions between SSG and xanthan gum and also the effect of temperature using transient measurements. In this way, we show that the viscoelastic (transient and dynamic) and time‐dependent rheological behaviors may be investigated using single creep/recovery tests. This new insight into transient measurements is useful to characterize the interaction behavior of similar biopolymers blends.