[1] L Hines, K Petersen, G Z Lum et al. Soft actuators for small-scale robotics. Adv Mater, 29, 1603483(2017).

[2] A Kotikian, C McMahan, E C Davidson et al. Untethered soft robotic matter with passive control of shape morphing and propulsion. Sci Robot, 4, eaax7044(2019).

[3] I A Anderson, T A Gisby, T G McKay et al. Multi-functional dielectric elastomer artificial muscles for soft and smart machines. J Appl Phys, 112, 041101(2012).

[4] X Cheng, Y Zhang. Micro/nanoscale 3D assembly by rolling, folding, curving, and buckling approaches. Adv Mater, 31, 1901895(2019).

[5] H Zhao, K Li, M Han et al. Buckling and twisting of advanced materials into morphable 3D mesostructures. Proc Natl Academ Sci United States Am, 116, 13239(2019).

[6] G Z Lum, Z Ye, X Dong et al. Shape-programmable magnetic soft matter. Proceedings of the National Academy of Sciences of the United States of America, 113, E6007(2016).

[7] A Lendlein, O E C Gould. Reprogrammable recovery and actuation behaviour of shape-memory polymers. Nat Rev Mater, 4, 116(2019).

[8] Y Liu, J Genzer, M D Dickey. "2D or not 2D": Shape-programming polymer sheets. Prog Polym Sci, 52, 79(2016).

[9] B Xu, B Zhang, L Wang et al. Tubular micro/nanomachines: from the basics to recent advances. Adv Funct Mater, 28, 1705872(2018).

[10] J Li, T Liu, S Xia et al. A versatile approach to achieve quintuple-shape memory effect by semi-interpenetrating polymer networks containing broadened glass transition and crystalline segments. J Mater Chem, 21, 12213(2011).

[11] M D Hager, S Bode, C Weber et al. Shape memory polymers: past, present and future developments. Prog Polym Sci, 49/50, 3(2015).

[12] T Xie. Tunable polymer multi-shape memory effect. Nature, 464, 267(2010).

[13] M Behl, K Kratz, U Noechel et al. Temperature-memory polymer actuators. Proceedings of the National Academy of Sciences of the United States of America, 110, 12555(2013).

[14] Y Wang, A Villada, Y Zhai et al. Tunable surface wrinkling on shape memory polymers with application in smart micromirror. Appl Phys Lett, 114, 193701(2019).

[15] Y Wang, Y Zhai, A Villada et al. Programmable localized wrinkling of thin films on shape memory polymers with application in nonuniform optical gratings. Appl Phys Lett, 112, 251603(2018).

[16] M Noh, S W Kim, S An et al. Flea-inspired catapult mechanism for miniature jumping robots. IEEE Trans Robot, 28, 1007(2012).

[17] Y Q Fu, H J Du, W M Huang et al. TiNi-based thin films in MEMS applications: a review. Sens Actuators A, 112, 395(2004).

[18] Y Q Fu, J K Luo, A J Flewitt et al. Microactuators of free-standing TiNiCu films. Smart Mater Struct, 16, 2651(2007).

[19] K Liu, C Cheng, J Suh et al. Powerful, multifunctional torsional micromuscles activated by phase transition. Adv Mater, 26, 1746(2014).

[20] T Wang, D Torres, F E Fernandez et al. Maximizing the performance of photothermal actuators by combining smart materials with supplementary advantages. Sci Adv, 3, e1602697(2017).

[21] A Rúa, F E Fernández, N Sepúlveda. Bending in VO₂-coated microcantilevers suitable for thermally activated actuators. J Appl Phys, 107, 074506(2010).

[22] T H Ware, M E McConney, J J Wie et al. Voxelated liquid crystal elastomers. Science, 347, 982(2015).

[23] L T de Haan, V Gimenez-Pinto, A Konya et al. Accordion-like actuators of multiple 3D patterned liquid crystal polymer films. Adv Funct Mater, 24, 1251(2014).

[24] Y Yang, Z Pei, Z Li et al. Making and remaking dynamic 3D structures by shining light on flat liquid crystalline vitrimer films without a mold. J Am Chem Soc, 138, 2118(2016).

[25] C Ahn, X Liang, S Cai. Inhomogeneous stretch induced patterning of molecular orientation in liquid crystal elastomers. Extrem Mechan Lett, 5, 30(2015).

[26] Z Pei, Y Yang, Q Chen et al. Mouldable liquid-crystalline elastomer actuators with exchangeable covalent bonds. Nat Mater, 13, 36(2014).

[27] E Bormashenko, Y Bormashenko, R Pogreb et al. Janus droplets: liquid marbles coated with dielectric/semiconductor particles. Langmuir, 27, 7(2011).

[28] M Lemanowicz, A Gierczycki, W Kuznik et al. Determination of lower critical solution temperature of thermosensitive flocculants. Miner Eng, 69, 170(2014).

[29] G Stoychev, S Turcaud, J W C Dunlop et al. Hierarchical multi-step folding of polymer bilayers. Adv Funct Mater, 23, 2295(2013).

[30] V Stroganov, M Al-Hussein, J U Sommer et al. Reversible thermosensitive biodegradable polymeric actuators based on confined crystallization. Nano Lett, 15, 1786(2015).

[31] E Wang, M S Desai, S W Lee. Light-controlled graphene-elastin composite hydrogel actuators. Nano Lett, 13, 2826(2013).

[32] B Jin, H Song, R Jiang et al. Programming a crystalline shape memory polymer network with thermo- and photo-reversible bonds toward a single-component soft robot. Sci Adv, 4, eaao3865(2018).

[33] S Wall, D Wegkamp, L Foglia et al. Ultrafast changes in lattice symmetry probed by coherent phonons. Nat Commun, 3, 721(2012).

[34] J Cao, E Ertekin, V Srinivasan et al. Strain engineering and one-dimensional organization of metal-insulator domains in single-crystal vanadium dioxide beams. Nat Nanotechnol, 4, 732(2009).

[35] S Fusco, M S Sakar, S Kennedy et al. An integrated microrobotic platform for on-demand, targeted therapeutic interventions. Adv Mater, 26, 952(2014).

[36] S Miyashita, L Meeker, M T Tolley et al. Self-folding miniature elastic electric devices. Smart Mater Struct, 23, 094005(2014).

[37] G Stoychev, N Puretskiy, L Ionov. Self-folding all-polymer thermoresponsive microcapsules. Soft Matter, 7, 3277(2011).

[38] C Yoon, R Xiao, J Park et al. Functional stimuli responsive hydrogel devices by self-folding. Smart Mater Struct, 23, 094008(2014).

[39] R Verduzco. Shape-shifting liquid crystals. Science, 347, 949(2015).

[40] S Palagi, A G Mark, S Y Reigh et al. Structured light enables biomimetic swimming and versatile locomotion of photoresponsive soft microrobots. Nat Mater, 15, 647(2016).

[41] Y Cui, C Wang, K Sim et al. A simple analytical thermo-mechanical model for liquid crystal elastomer bilayer structures. AIP Adv, 8, 025215(2018).

[42] C Wang, K Sim, J Chen et al. Soft ultrathin electronics innervated adaptive fully soft robots. Adv Mater, 30, 1706695(2018).

[43] Q He, Z Wang, Y Wang et al. Electrically controlled liquid crystal elastomer-based soft tubular actuator with multimodal actuation. Sci Adv, 5, eaax5746(2019).

[44] S Kim, E Hawkes, K Cho et al. Micro artificial muscle fiber using NiTi spring for soft robotics. 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems, 2228(2009).

[45] M S M Ali, K Takahata. Frequency-controlled wireless shape-memory-alloy microactuators integrated using an electroplating bonding process. Sens Actuators A, 163, 363(2010).

[46] J Colorado, A Barrientos, C Rossi et al. Biomechanics of smart wings in a bat robot: morphing wings using SMA actuators. Bioinspir Biomimet, 7, 036006(2012).

[47] S J Furst, G Bunget, S Seelecke. Design and fabrication of a bat-inspired flapping-flight platform using shape memory alloy muscles and joints. Smart Mater Struct, 22, 014011(2012).

[48] K Liu, C Cheng, Z Cheng et al. Giant-amplitude, high-work density microactuators with phase transition activated nanolayer bimorphs. Nano Lett, 12, 6302(2012).

[49] K Wang, C Cheng, E Cardona et al. Performance limits of microactuation with vanadium dioxide as a solid engine. ACS Nano, 7, 2266(2013).

[50] Z Tian, W Huang, B Xu et al. Anisotropic rolling and controlled chirality of nanocrystalline diamond nanomembranes toward biomimetic helical frameworks. Nano Lett, 18, 3688(2018).

[51] Q Zhao, J W C Dunlop, X Qiu et al. An instant multi-responsive porous polymer actuator driven by solvent molecule sorption. Nat Commun, 5, 4293(2014).

[52] R Xiao, J Guo, D L Safranski et al. Solvent-driven temperature memory and multiple shape memory effects. Soft Matter, 11, 3977(2015).

[53] W M Huang, B Yang, L An et al. Water-driven programmable polyurethane shape memory polymer: Demonstration and mechanism. Appl Phys Lett, 86, 114105(2005).

[54] M Ma, L Guo, D G Anderson et al. Bio-inspired polymer composite actuator and generator driven by water gradients. Science, 339, 186(2013).

[55] X Chen, D Goodnight, Z Gao et al. Scaling up nanoscale water-driven energy conversion into evaporation-driven engines and generators. Nat Commun, 6, 7346(2015).

[56] B P Lee, S Konst. Novel hydrogel actuator inspired by reversible mussel adhesive protein chemistry. Adv Mater, 26, 3415(2014).

[57] M Jamal, A M Zarafshar, D H Gracias. Differentially photo-crosslinked polymers enable self-assembling microfluidics. Nat Commun, 2, 527(2011).

[58] J Kim, J A Hanna, M Byun et al. Designing responsive buckled surfaces by halftone gel lithography. Science, 335, 1201(2012).

[59] A S Gladman, E A Matsumoto, R G Nuzzo et al. Biomimetic 4D printing. Nat Mater, 15, 413(2016).

[60] E Palleau, D Morales, M D Dickey et al. Reversible patterning and actuation of hydrogels by electrically assisted ionoprinting. Nat Commun, 4, 2257(2013).

[61] H Lee, C Xia, N X Fang. First jump of microgel; actuation speed enhancement by elastic instability. Soft Matter, 6, 4342(2010).

[62] H Zhang, X Guo, J Wu et al. Soft mechanical metamaterials with unusual swelling behavior and tunable stress-strain curves. Sci Adv, 4, eaar8535(2018).

[63] A Ollagnier, A Fabre, T Thundat et al. Activation process of reversible Pd thin film hydrogen sensors. Sens Actuators B, 186, 258(2013).

[64] B Xu, X Zhang, Z Tian et al. Microdroplet-guided intercalation and deterministic delamination towards intelligent rolling origami. Nat Commun, 10, 5019(2019).

[65] B Xu, Z Tian, J Wang et al. Stimuli-responsive and on-chip nanomembrane micro-rolls for enhanced macroscopic visual hydrogen detection. Sci Adv, 4, eaap8203(2018).

[66] A Gestos, P G Whitten, G G Wallace et al. Actuating individual electrospun hydrogel nanofibres. Soft Matter, 8, 8082(2012).

[67] P Techawanitchai, M Ebara, N Idota et al. Photo-switchable control of pH-responsive actuators via pH jump reaction. Soft Matter, 8, 2844(2012).

[68] C Ma, T Li, Q Zhao et al. Supramolecular Lego assembly towards three-dimensional multi-responsive hydrogels. Adv Mater, 26, 5665(2014).

[69] L Dong, A K Agarwal, D J Beebe et al. Adaptive liquid microlenses activated by stimuli-responsive hydrogels. Nature, 442, 551(2006).

[70] Y Yu, T Ikeda. Soft actuators based on liquid-crystalline elastomers. Angew Chem Int Ed, 45, 5416(2006).

[71] M F Yu, B S Files, S Arepalli et al. Tensile loading of ropes of single wall carbon nanotubes and their mechanical properties. Phys Rev Lett, 84, 5552(2000).

[72] J Wei, Y Yu. Photodeformable polymer gels and crosslinked liquid-crystalline polymers. Soft Matter, 8, 8050(2012).

[73] T J White, N V Tabiryan, S V Serak et al. A high frequency photodriven polymer oscillator. Soft Matter, 4, 1796(2008).

[74] H Zeng, P Wasylczyk, C Parmeggiani et al. Light-fueled microscopic walkers. Adv Mater, 27, 3883(2015).

[75] X Tang, S Y Tang, V Sivan et al. Photochemically induced motion of liquid metal marbles. Appl Phys Lett, 103, 174104(2013).

[76] A Lendlein, H Y Jiang, O Junger et al. Light-induced shape-memory polymers. Nature, 434, 879(2005).

[77] H Y Jiang, S Kelch, A Lendlein. Polymers move in response to light. Adv Mater, 18, 1471(2006).

[78] Y L Yu, M Nakano, T Ikeda. Directed bending of a polymer film by light. Nature, 425, 145(2003).

[79] A Natansohn, P Rochon. Photoinduced motions in azo-containing polymers. Chem Rev, 102, 4139(2002).

[80] K M Lee, H Koerner, R A Vaia et al. Light-activated shape memory of glassy, azobenzene liquid crystalline polymer networks. Soft Matter, 7, 4318(2011).

[81] C Huang, J A Lv, X Tian et al. Miniaturized swimming soft robot with complex movement actuated and controlled by remote light signals. Sci Rep, 5, 17414(2015).

[82] M Yamada, M Kondo, J Mamiya et al. Photomobile polymer materials: towards light-driven plastic motors. Angew Chem, 47, 4986(2008).

[83] M Boncheva, S A Andreev, L Mahadevan et al. Magnetic self-assembly of three-dimensional surfaces from planar sheets. Proc Natl Academ Sci United States of Am, 102, 3924(2005).

[84] A A Solovev, S Sanchez, M Pumera et al. Nanomotors: magnetic control of tubular catalytic microbots for the transport, assembly, and delivery of micro-objects. Adv Funct Mater, 20, 2430(2010).

[85] S Fusco, H W Huang, K E Peyer et al. Shape-switching microrobots for medical applications: the influence of shape in drug delivery and locomotion. Acs Appl Mater Interfaces, 7, 6803(2015).

[86] S Tasoglu, E Diller, S Guven et al. Untethered micro-robotic coding of three-dimensional material composition. Nat Commun, 5, 3124(2014).

[87] E Diller, J Giltinan, G Z Lum et al. Six-degree-of-freedom magnetic actuation for wireless microrobotics. Int J Robot Res, 35, 114(2016).

[88] E Diller, J Zhuang, G Z Lum et al. Continuously distributed magnetization profile for millimeter-scale elastomeric undulatory swimming. Appl Phys Lett, 104, 174101(2014).

[89] B Jang, E Gutman, N Stucki et al. Undulatory locomotion of magnetic multilink nanoswimmers. Nano Lett, 15, 4829(2015).

[90] J V I Timonen, M Latikka, L Leibler et al. Switchable static and dynamic self-assembly of magnetic droplets on superhydrophobic surfaces. Science, 341, 253(2013).

[91] T Jamin, C Py, E Falcon. Instability of the origami of a ferrofluid drop in a magnetic field. Phys Rev Lett, 107, 204503(2011).

[92] W Hu, G Z Lum, M Mastrangeli et al. Small-scale soft-bodied robot with multimodal locomotion. Nature, 554, 81(2018).

[93] P Garstecki, P Tierno, D B Weibel et al. Propulsion of flexible polymer structures in a rotating magnetic field. J Phys Conden Matter, 21, 204110(2009).

[94] J Kim, S E Chung, S E Choi et al. Programming magnetic anisotropy in polymeric microactuators. Nat Mater, 10, 747(2011).

[95] Y Kim, H Yuk, R Zhao et al. Printing ferromagnetic domains for untethered fast-transforming soft materials. Nature, 558, 274(2018).

[96] Y Kim, G A Parada, S Liu et al. Ferromagnetic soft continuum robots. Sci Robot, 4, eaax7329(2019).

[97] T Qiu, T C Lee, A G Mark et al. Swimming by reciprocal motion at low Reynolds number. Nat Commun, 5, 5119(2014).

[98] S Yim, M Sitti. Design and rolling locomotion of a magnetically actuated soft capsule endoscope. IEEE Trans Robot, 28, 183(2012).

[99] S Yim, M Sitti. Shape-programmable soft capsule robots for semi-implantable drug delivery. IEEE Trans Robot, 28, 1198(2012).

[100] P Brochu, Q Pei. Advances in dielectric elastomers for actuators and artificial muscles. Macromolecul Rapid Commun, 31, 10(2010).

[101] I S Park, K Jung, D Kim et al. Physical principles of ionic polymer-metal composites as electroactive actuators and sensors. MRS Bull, 33, 190(2008).

[102] C Miehe, D Rosato. A rate-dependent incremental variational formulation of ferroelectricity. Int J Eng Sci, 49, 466(2011).

[103] T Mirfakhrai, J Oh, M Kozlov et al. Electrochemical actuation of carbon nanotube yarns. Smart Mater Struct, 16, S243(2007).

[104] J Foroughi, G M Spinks, G G Wallace et al. Torsional carbon nanotube artificial muscles. Science, 334, 494(2011).

[105] I Must, F Kaasik, I Põldsalu et al. Ionic and capacitive artificial muscle for biomimetic soft robotics. Adv Eng Mater, 17, 84(2015).

[106] V Palmre, D Pugal, K J Kim et al. Nanothorn electrodes for ionic polymer-metal composite artificial muscles. Sci Rep, 4, 6176(2014).

[107] S Shian, D R Clarke. Electrically-tunable surface deformation of a soft elastomer. Soft Matter, 12, 3137(2016).

[108] J Shintake, S Rosset, B Schubert et al. Versatile soft grippers with intrinsic electroadhesion based on multifunctional polymer actuators. Adv Mater, 28, 231(2016).

[109] G Kofod, W Wirges, M Paajanen et al. Energy minimization for self-organized structure formation and actuation. Appl Phys Lett, 90, 081916(2007).

[110] T Li, G Li, Y Liang et al. Fast-moving soft electronic fish. Sci Adv, 3, e1602045(2017).

[111] W S Chu, K T Lee, S H Song et al. Review of biomimetic underwater robots using smart actuators. Int J Prec Eng Manufact, 13, 1281(2012).

[112] M Aureli, V Kopman, M Porfiri. Free-locomotion of underwater vehicles actuated by ionic polymer metal composites. IEEE/ASME Trans Mechatron, 15, 603(2010).

[113] J Barramba, J Silva, P J C Branco. Evaluation of dielectric gel coating for encapsulation of ionic polymer-metal composite (IPMC) actuators. Sens Actuators A, 140, 232(2007).

[114] I Must, T Kaasik, I Baranova et al. A power-autonomous self-rolling wheel using ionic and capacitive actuators. Proc SPIE, 9430, 94300Q(2015).

[115] B Mohammadi, A A Yousefi, S M Bellah. Effect of tensile strain rate and elongation on crystalline structure and piezoelectric properties of PVDF thin films. Polymer Testing, 26, 42(2007).

[116] G L Smith, J S Pulskamp, L M Sanchez et al. PZT-based piezoelectric MEMS technology. J Am Ceram Soc, 95, 1777(2012).

[117] S B Fuller, M Karpelson, A Censi et al. Controlling free flight of a robotic fly using an onboard vision sensor inspired by insect ocelli. J Royal Soc Interface, 11, 20140281(2014).

[118] Y Wu, J K Yim, J Liang et al. Insect-scale fast moving and ultrarobust soft robot. Sci Robot, 4, eaax1594(2019).

[119] K Y Ma, P Chirarattananon, S B Fuller et al. Controlled flight of a biologically inspired, insect-scale robot. Science, 340, 603(2013).

[120] Y Chen, N Doshi, B Goldberg et al. Controllable water surface to underwater transition through electrowetting in a hybrid terrestrial-aquatic microrobot. Nat Commun, 9, 2495(2018).

[121] N T Jafferis, E F Helbling, M Karpelson et al. Untethered flight of an insect-sized flapping-wing microscale aerial vehicle. Nature, 570, 491(2019).

[122] S Xu, Z Yan, K I Jang et al. Assembly of micro/nanomaterials into complex, three-dimensional architectures by compressive buckling. Science, 347, 154(2015).

[123] Y Zhang, Z Yan, K Nan et al. A mechanically driven form of Kirigami as a route to 3D mesostructures in micro/nanomembranes. Proceedings of the National Academy of Sciences of the United States of America, 112, 11757(2015).

[124] Y Liu, Z Yan, Q Lin et al. Guided formation of 3D helical mesostructures by mechanical buckling: analytical modeling and experimental validation. Adv Funct Mater, 26, 2909(2016).

[125] Z Yan, F Zhang, F Liu et al. Mechanical assembly of complex, 3D mesostructures from releasable multilayers of advanced materials. Sci Adv, 2, e1601014(2016).

[126] Z Fan, K C Hwang, J A Rogers et al. A double perturbation method of postbuckling analysis in 2D curved beams for assembly of 3D ribbon-shaped structures. J Mechan Phys Solids, 111, 215(2018).

[127] J Song. Mechanics of stretchable electronics. Curr Opin Solid State Mater Sci, 19, 160(2015).

[128] Y Zhang, F Zhang, Z Yan et al. Printing, folding and assembly methods for forming 3D mesostructures in advanced materials. Nat Rev Mater, 2, 17019(2017).

[129] X Guo, Z Xu, F Zhang et al. Reprogrammable 3D mesostructures through compressive buckling of thin films with prestrained shape memory polymer. Acta Mechan Solida Sinica, 31, 589(2018).

[130] K I Jang, K Li, H U Chung et al. Self-assembled three dimensional network designs for soft electronics. Nat Commun, 8, 15894(2017).

[131] B H Kim, F Liu, Y Yu et al. Mechanically guided post-assembly of 3D electronic systems. Adv Funct Mater, 28, 1803149(2018).

[132] F Liu, Y Chen, H Song et al. High performance, tunable electrically small antennas through mechanically guided 3D assembly. Small, 15, 1804055(2019).

[133] Z Yan, F Zhang, J Wang et al. Controlled mechanical buckling for origami-inspired construction of 3D microstructures in advanced materials. Adv Funct Mater, 26, 2629(2016).

[134] X Ning, H Wang, X Yu et al. 3D tunable, multiscale, and multistable vibrational micro-platforms assembled by compressive buckling. Adv Funct Mater, 27, 1605914(2017).

[135] Y Shi, F Zhang, K Nan et al. Plasticity-induced origami for assembly of three dimensional metallic structures guided by compressive buckling. Extrem Mechan Lett, 11, 105(2017).

[136] Z Yan, M Han, Y Yang et al. Deterministic assembly of 3D mesostructures in Adv Mater via compressive buckling: A short review of recent progress. Extrem Mechan Lett, 11, 96(2017).

[137] H Fu, K Nan, W Bai et al. Morphable 3D mesostructures and microelectronic devices by multistable buckling mechanics. Nat Mater, 17, 268(2018).

[138] G Luo, H Fu, X Cheng et al. Mechanics of bistable cross-shaped structures through loading-path controlled 3D assembly. J Mechan Phys Solids, 129, 261(2019).

[139] Y Liu, X Wang, Y Xu et al. Harnessing the interface mechanics of hard films and soft substrates for 3D assembly by controlled buckling. Proc Natl Academ Sci, 116, 15368(2019).

[140] J M Jani, M Leary, A Subic et al. A review of shape memory alloy research, applications and opportunities. Mater Des, 56, 1078(2014).

[141] H Ma, J Hou, X Wang et al. Flexible, all-inorganic actuators based on vanadium dioxide and carbon nanotube bimorphs. Nano Lett, 17, 421(2017).

[142] H Yu, T Ikeda. Photocontrollable liquid-crystalline actuators. Adv Mater, 23, 2149(2011).

[143] S W Kwok, S A Morin, B Mosadegh et al. Magnetic assembly of soft robots with hard components. Adv Funct Mater, 24, 2180(2014).

[144] R Pelrine, R Kornbluh, Q Pei et al. High-speed electrically actuated elastomers with strain greater than 100%. Science, 287, 836(2000).