As a class of stimuli-responsive materials, shape memory polymers (SMPs) have received great attention due to their scientific interest and promising applications in advanced technologies in different areas. [1,2] Dual-SMPs can memorize a programmed temporary shape defined by the applied force and fixed by switching the system from one state to the other. Various molecular relaxations and phase transitions, e.g., vitrification, crystallization, or less commonly used liquid crystal (LC) transition, can be employed to fix the temporary shape. It is also demonstrated that multi-SMPs can be fabricated based on multiple transitions or a broad transition. [3] When the reversible transition is triggered by external stimuli, [1,4] the SMP will recover to its permanent shape defined by a network embedded in the system. The network shall be robust enough to resist the plastic deformation when the temporary shape is programmed.The network can be made of chemical or physical crosslink points, leading to SMPs that are thermoset or thermoplastic. [1] While the former gives more stable shape memory performance, the latter is attractive due to the flexibility of processing. However, physical crosslinks based on noncovalent bond interactions, e.g., chain entanglement, hydrogen bond, and ionic interaction, are often less stable. [5] Chain sliding or reorganization occurred during deformation will result in poor shape memory properties. This is a fatal weakness for many thermoplastic SMPs, particularly when a large shape change is demanded, [6] such as in some biomedical devices [2a] and package materials. [6d] To obtain better SMPs combining thermoplastic and stable network, one elegant approach is to follow the strategy of vitrimer. [7a] One can make the network using dynamic covalent bonds, which can allow the SMP to be reshaped at high temperatures with the aid of a catalyst. [7] On the other hand, new thermoplastic SMPs with pure physical crosslink network are still desirable. For example, an excellent multi-SMP of a compositional gradient copolymer is recently reported, [3d] showing a microphase-separated structure similar to the thermoplastic elastomer of styrene-butadiene-styrene (SBS) triblock copolymer. Nevertheless, to make the thermoplastic SMPs with both ideal shape fixity (R f ) and shape recovery (R r ) for high strain (e.g., strain >400%) remains a great challenge. [5,6b] While the commonly applied physical crosslinks show their limitation, we attempt to find a new type of physical crosslink by utilizing a columnar LC structure. Here we report a novel thermoplastic high strain SMP of hemiphasmid sidechain polynorbornene (P1; Figure 1a). P1 exhibits a hexagonal columnar LC (Φ H ) phase and a broad Φ H -isotropic transition. It renders both the R f and R r approaching 100% for dual-shape memory effect (SME), even when a high strain of ≈600% is applied. It is also a multi-SMP. For triple and quadruple-SME, with the total strain higher than 400%, it can still give R f quite high and R r > 95% at each step....
