In this study, mechanically strong hydrogels are synthesized by photopolymerization of 2‐vinyl‐4,6‐diamino‐1,3,5‐triazine, poly(ethylene glycol) methacrylate, and disulfide‐containing cross‐linker, N′N‐bis(acryloyl)cystamine. The bilayer hydrogel with distinct cross‐linking density is shown to self‐roll into a 3D tube, which could still be well reinforced by hydrogen bondings, upon exposing reductants such as 1,4‐dithio‐DL‐threitol (DTT) or L‐glutathione (GSH), because the redox‐induced cleavage of disulfide bonds results in the imbalanced internal shrinking stress between two layers. At an intracellular level of GSH, model L929 cells‐seeded bilayer gel sheet could curl up into a 3D tubular scaffold where the cells maintained good viability.
Microwave absorbing structures (MASs) reinforced by two dimensional (2D) composite lattice elements have been designed and fabricated. The density of these MASs is lower than 0.5?g/cm3. Experimental measurements show that the sandwich structure with glass fiber reinforced composite (GFRC) lattice core can serve as a broadband MAS with its reflectivity below ?10?dB over the frequency range of 4?C18?GHz. The low permittivity GFRC is indicated to be the proper material for both the structural element of the core and the transparent face sheet. Calculations by the periodic moment method (PMM) demonstrate that the 2D Kagome lattice performs better for microwave absorbing than the square one at relatively low frequencies. The volume fraction and cell size of the structural element are also revealed to be key factors for microwave absorbing performance. 相似文献
