Plucknett K. P., Pomfret S. J., Normand V., Ferdinando D., Veerman C., Frith W. J., Norton I. T.
Unilever Research Laboratory, Colworth House, Sharnbrook, Bedfordshire, MK44 1LQ, U.K.; Wageningen Agricultural University, Wageningen, The Netherlands.
J Microsc. 2001 Feb;201(2):279-290.
Confocal laser scanning microscopy (CLSM) is used to follow the dynamic structural evolution of several phase-separated mixed biopolymer gel composites. Two protein/polysaccharide mixed gel systems were examined: gelatin/maltodextrin and gelatin/agarose. These materials exhibit 'emulsion-like' structures, with included spherical particles of one phase (i.e. polymer A) within a continuous matrix of the second (i.e. polymer B). Compositional control of these materials allows the phase order to be inverted (i.e. polymer B included and polymer A continuous), giving four basic variants for the present composites. Tension and compression mechanical tests were conducted dynamically on the CLSM, with crack/microstructure interactions investigated using a notched compact tension geometry. Gelatin/maltodextrin composites exhibit a 'pseudo-yielding' stress/strain response in both tension and compression, when the gelatin-rich phase is continuous, which was attributed to debonding of the particle/matrix interface. This behaviour is significantly less apparent for both the gelatin/agarose composites, and the maltodextrin continuous gelatin/maltodextrin composites, with these materials responding in a nominally linear elastic manner. Values of the interfacial fracture energy for selected compositions of the two biopolymer systems were determined by 90 degrees peel testing, where a gelatin layer was peeled from either a maltodextrin or agarose substrate. For biopolymer layers 'cast' together, a value of 0.2 +/- 0.2 J m-2 was obtained for the fracture energy of a gelatin/maltodextrin interface, while a significantly higher value of 6.5 +/- 0.2 J m-2 was determined for a gelatin/agarose interface. The interfacial fracture energy of the two mixed systems was also determined following an indirect elastomer composite debonding model. An interfacial fracture energy of approximately 0.25 J m-2 was determined using this approach for the gelatin continuous gelatin/maltodextrin composite, which compares favourably with the value calculated directly by peel testing (i.e. approximately 0.2 J m-2). A somewhat higher value was estimated for the gelatin continuous gelatin/agarose system (1.0-2.0 J m-2), using this model, although there are severe limitations to this approach for this mixed gel system. In the present case, it is believed that the differing mechanical response of the two mixed biopolymer systems, when the gelatin phase is continuous, arises from the order of magnitude difference in interfacial fracture energy. It is postulated that polymer interdiffusion may occur across the interface for the gelatin/agarose system, to a significantly greater extent than for interfaces between gelatin and maltodextrin, resulting in a higher interfacial fracture energy.
共聚焦激光扫描显微镜(CLSM)用于追踪几种相分离混合生物聚合物凝胶复合材料的动态结构演变。研究了两种蛋白质/多糖混合凝胶体系:明胶/麦芽糊精和明胶/琼脂糖。这些材料呈现出“乳液状”结构,在第二种聚合物(即聚合物B)的连续基质中包含一种相(即聚合物A)的球形颗粒。对这些材料进行成分控制可使相序反转(即包含聚合物B且聚合物A连续),从而为当前复合材料提供四种基本变体。在CLSM上动态进行拉伸和压缩力学测试,使用带缺口紧凑拉伸几何形状研究裂纹/微观结构相互作用。当富含明胶的相连续时,明胶/麦芽糊精复合材料在拉伸和压缩时均表现出“假屈服”应力/应变响应,这归因于颗粒/基质界面的脱粘。对于明胶/琼脂糖复合材料以及麦芽糊精连续的明胶/麦芽糊精复合材料,这种行为明显不那么明显,这些材料以名义上的线性弹性方式响应。通过90度剥离测试确定了两种生物聚合物体系选定组成的界面断裂能,其中将明胶层从麦芽糊精或琼脂糖基材上剥离。对于“浇铸”在一起的生物聚合物层,明胶/麦芽糊精界面的断裂能为0.2±0.2 J m-2,而明胶/琼脂糖界面的断裂能则明显更高,为6.5±0.2 J m-2。还根据间接弹性体复合材料脱粘模型确定了两种混合体系的界面断裂能。使用这种方法,对于明胶连续的明胶/麦芽糊精复合材料,确定的界面断裂能约为0.25 J m-2,与通过剥离测试直接计算的值(即约0.2 J m-2)相比具有优势。使用该模型对明胶连续的明胶/琼脂糖体系估计的值略高(1.0 - 2.0 J m-2),尽管该方法对这种混合凝胶体系存在严重局限性。在当前情况下,据信当明胶相连续时,两种混合生物聚合物体系的不同力学响应源于界面断裂能的数量级差异。据推测,与明胶和麦芽糊精之间的界面相比,明胶/琼脂糖体系中聚合物可能在界面上发生更大程度的相互扩散,从而导致更高的界面断裂能。
