for applications in aerospace, smart devices, and biomedical materials. [1][2][3] Among these materials, shape-morphing polymers (SMPs) are particularly attractive because their forms can be programmed to perform transformations or motions in response to external stimuli (e.g., temperature, light, solvent, and electric fields). [3][4][5][6][7][8][9][10][11] Currently, two general approaches are used to obtain unparalleled shape-programming flexibility. The first involves geometric assistances to produce complex SMP shapes, such as kirigami and origami art, as well as 3D printing. [12][13][14][15][16][17] Alternatively, another approach is through the use of an innovational polymer network design, which employs functional components to expand the programmability of SMPs. [18][19][20][21][22][23] For example, SMPs with dynamic covalent polymer networks and reversible crosslinking netpoints exhibit unique shape reconfiguration and programmability. [18][19][20][21] However, despite these exciting prospects, most SMPs with the single control routes only allow complex temporary shapes to recover a former permanent state, ultimately limiting the versatility of these materials and our ability to control them for complex applications. Owing to the intrinsic restriction of the permanently crosslinked polymer network, such single programming inevitably lacks a mechanism Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape morphing performance that far exceeds conventional shape-morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
Gel MaterialsProgrammable materials are capable of changing their inherent shapes or exquisite properties to adapt to complex environments a...
