[2]LI X Y, WANG J X, CHAI Y J, et al. A novel frog-like meta-structure with linkage mechanism for low-frequency vibration isolation[J].Journal of Physics D: Applied Physics,2024,57: 135304.
|
DARWISH Y, ELGAWADY M A. Numerical and experimental investigation of negative stiffness beams and honeycomb structures[J].Engineering Structures,2024,301: 117163.
|
[3]杨航, 马力. 多材料点阵结构的热可编程力学行为[J]. 应用数学和力学, 2022,43(5): 534-552.(YANG Hang, MA Li. Multimaterial lattice structures with thermally programmable mechanical behaviors[J].Applied Mathematics and Mechanics,2022,43(5): 534-522.(in Chinese))
|
[4]王竞哲, 陈保才, 朱绍伟, 等. 圆锥形负刚度超材料吸能性能研究[J]. 应用数学和力学, 2023,44(10): 1172-1179.(WANG Jingzhe, CHEN Baocai, ZHU Shaowei, et al. Study on energy absorption performances of conical negative stiffness metamaterials[J].Applied Mathematics and Mechanics,2023,44(10): 1172-1179.(in Chinese))
|
[5]VALENCIA C, RESTREPO D, MANKAME N D, et al. Computational characterization of the wave propagation behavior of multi-stable periodic cellular materials[J].Extreme Mechanics Letters,2019,33(C): 100565.
|
[6]GOLDSBERRY B M, HABERMAN M R. Negative stiffness honeycombs as tunable elastic metamaterials[J].Journal of Applied Physics,2018,123(9): 091711.
|
[7]FRAZIER M J. Multi-stable acoustic metamaterials with re-configurable mass distribution[J].Journal of Applied Physics,2022,131(16): 165105.
|
[8]HU N, LI B, BAI R Y, et al. A torsion-bending antagonistic bistable actuator enables untethered crawling and swimming of miniature robots[J].Research,2023,6: 0116.
|
[9]MUNGEKAR M, MA L X, YAN W Z, et al. Design of bistable soft deployable structures via a kirigami-inspired planar fabrication approach[J].Advanced Materials Technologies,2023,8(16): 00088.
|
[10]CHI Y D, HONG Y Y, ZHAO Y, et al. Snapping for high-speed and high-efficient butterfly stroke-like soft swimmer[J].Science Advances,2022,8(46): eadd3788.
|
[11]WANG J, ZHAO T H, FAN Y Y, et al. Leveraging bioinspired structural constraints for tunable and programmable snapping dynamics in high-speed soft actuators[J].Advanced Functional Materials,2022,33(2): 09798.
|
[12]ZHOU S X, CAO J Y, ERTURK A, et al. Enhanced broadband piezoelectric energy harvesting using rotatable magnets[J].Applied Physics Letters,2013,102(17): 173901.
|
[13]ZHOU S X, CAO J Y, INMAN D J, et al. Broadband tristable energy harvester: modeling and experiment verification[J].Applied Energy,2014,133: 33-39.
|
[14]BARTON DAW, BURROW S G, CLARE L R. Energy harvesting from vibrations with a nonlinear oscillator[J].Journal of Vibration and Acoustics,2010,132(2): 427-436.
|
[15]SHAN S C, KANG S H, RANEY J R, et al. Multistable architected materials for trapping elastic strain energy[J].Advanced Materials,2015,27(29): 4296-4301.
|
[16]FRENZEL T, FINDISEN C, KADIC M, et al. Tailoredbuckling microlattices as reusable light-weight shock absorbers[J].Advanced Materials,2016,28(28): 5865-5870.
|
[17]WANG B, TAN X J, ZHU S W, et al. Cushion performance of cylindrical negative stiffness structures: analysis and optimization[J].Composite Structures,2019,227: 111276.
|
[18]ZHANG Y, TICHEM M, VAN KEULEN F. A novel design of multi-stable metastructures for energy dissipation[J].Materials Design,2021,212: 110234.
|
[19]TAN X J, WANG L C, ZHU S W, et al. A general strategy for performance enhancement of negative stiffness mechanical metamaterials[J].European Journal of Mechanics A: Solids,2022,96: 104702.
|
[20]MENG Z Q, OUYANG Z, CHEN C Q. Multi-step metamaterials with two phases of elastic and plastic deformation[J].Composite Structures,2021,271: 114152.
|
[21]SHI J H, MOFATTEH H, MIRABOLGHASEMI A, et al. Programmable multistable perforated shellular[J].Advanced Materials,2021,33(42): 210243.
|
[22]LIU S H, AZAD A, BURGUENO R. Architected materials for tailorable shear behavior with energy dissipation[J].Extreme Mechanics Letters,2019,28: 1-7.
|
[23]CHEN S, WANG B, ZHU S W, et al. A novel composite negative stiffness structure for recoverable trapping energy[J].Composites Part A,2020,129: 105697.
|