▎ 摘　　要

NOVELTY - Atomic-level laminated composite electric driving deformable material comprises at least one laminated layer structure comprising an upper graphene layer, a lower epoxy resin-based shape memory polymer layer and two electrodes. The two electrodes are respectively covered and arranged on both ends of the upper surface of the graphene layer. The number of layers of the graphene layer is 2-10 layers. The epoxy resin-based shape memory polymer is obtained by mixing epoxy resin E51, polysulfide rubber, aminoethyl piperazine and n-butyl glycidyl ether in a mass ratio of 100:16-35:24:20. USE - The deformation material is useful for electric driving intelligent material with shape-memory polymer/atomic layer composite graphene used as electric heating body. ADVANTAGE - The material: has simple structure, controllable electrical conductivity, thermal conductivity, fast response and recycling speed; and is easy to be used for electrically driving recycling deformation components. DETAILED DESCRIPTION - INDEPENDENT CLAIMS are also included for: a multilayer atomic-level laminated composite electric driving deformable material based on atomic-level laminated composite electric driving deformable material, comprising at least two laminated structure, where the two-layer laminated structure is bonded and connected by epoxy resin-based shape memory polymer, the two ends of the multilayer atomic-level laminated composite electric driving deformable material are provided with conductive materials, and are integrally connected to the electrodes of the laminated structure; preparing the atomic-level laminated composite electric driving deformable material, comprising (i) using chemical vapor deposition method to grow graphene on nickel foil surface, and obtaining at least one atomic layer graphene/nickel foil material, (ii) mixing epoxy resin E51, polysulfide rubber, aminoethyl piperazine and n-butyl glycidyl ether according to the mass ratio of 100:16-35:24:20, and obtaining a liquid shape memory polymer precursor, (iii) pouring a liquid shape memory polymer precursor into a mold pre-coated with a release agent, flatly covering the few atomic layer graphene/nickel foil material obtained in the step (i) on the surface of the shape memory polymer precursor, curing at 60-85°C for 2-6 hours, demolding, removing the nickel foil by etching to obtain a shape memory polymer/less atomic layer graphene composite material, and (iv) making electrodes at both ends of the upper surface of the graphene layer of the shape memory polymer/less atomic layer graphene composite material obtained in the step (iii) to obtain a laminated structure, and obtaining the finished product; and preparing the multilayer atomic-level laminated composite electric driving deformable material based on atomic-level laminated, comprising placing the laminated structure in the mold, uniformly brushing the liquid shape memory polymer precursor between the laminated structures as adhesive, curing at 60-85℃ for 2-6 hours and demolding, coating the two ends of the stacked structure with conductive material, and integrally connecting with the electrodes of a single stacked structure to obtain the finished product.