Effects of different ultrahigh molecular weight polyethylene contents on the formation and evolution of hierarchical crystal structure of high‐density polyethylene/ultrahigh molecular weight polyethylene blend fibers

In this paper, the blend fibers of ultrahigh molecular weight polyethylene (UHMWPE) and high‐density polyethylene (HDPE) were prepared by solution blending and gel spinning process. The uniformity of the blend fibers has been confirmed by rheological data and thermodynamic unimodal curve. They were further characterized by single fiber strength test, scanning electron microscopy, wide‐angle X‐ray diffraction, small‐angle X‐ray scattering, and so forth, to explore the structural evolution mechanism with the change of UHMWPE content. The results showed that when the molar content of UHMWPE was only 2.9 mol%, entanglement appeared in the structure of shish‐kebab, and when the proportion reached 20 mol%, an interlocking structure could be observed. With the increase of UHMWPE content, kebab began to be networked, and when the content reached 33 mol%, kebab's orientation reached its peak. After that, the interlocking network structure gradually improved. When the content reached 50 mol%, the shish's orientation reached saturation, and the shish‐kebab network became perfect. In addition, with the increase of UHMWPE content, stress‐induced recrystallization occurred on the wafer, some kebab would be converted into shish crystals, and when the content exceeded 50 mol%, the microfibers began to merge, and the wafer became denser, but still had entanglements. Our work has proposed a quantitative explanation for the evolution of hierarchical crystal structure of HDPE/UHMWPE blend fibers. The formation and evolution of hierarchical crystal structure of high‐density polyethylene/ultrahigh molecular weight polyethylene (UHMWPE) blend fibers prepared by solution blending and gel spinning‐overstretching process with a range of UHMWPE proportions are studied here. The shish‐kebab structure is the typical oriented structure of the blend fibers. As the UHMWPE content increases, an interlocking network structure is formed, and then the microfibers begin to emerge.