The creation of micromotors that can convert stored energy to autonomous movement would be of great value in various applications, ranging from chemical sensing to precision water-quality screening and from cleaning clogged arteries to repairing microscopic cracks. Many of micromotors, based on different propulsion mechanisms (e.g., magnetic fields, ultrasound filed, chemical fuels, light, and bubble propulsion), [1][2][3][4][5][6][7][8][9] have been designed and fabricated over the past decade. Generally, they are built of rigid materials [10] to maintain a good maneuverability, but often with limited body compliance and adaptability in confined spaces. [11][12][13] In contrast to the hard Shape-transformable liquid metal (LM) micromachines have attracted the attention of the scientific community over the past 5 years, but the inconvenience of transfer routes and the use of corrosive fuels have limited their potential applications. In this work, a shape-transformable LM micromotor that is fabricated by a simple, versatile ice-assisted transfer printing method is demonstrated, in which an ice layer is employed as a "sacrificial" substrate that can enable the direct transfer of LM micromotors to arbitrary target substrates conveniently. The resulting LM microswimmers display efficient propulsion of over 60 µm s −1 (≈3 bodylength s −1 ) under elliptically polarized magnetic fields, comparable to that of the common magnetic micro/ nanomotors with rigid bodies. Moreover, these LM micromotors can undergo dramatic morphological transformation in an aqueous environment under the irradiation of an alternating magnetic field. The ability to transform the shape and efficiently propel LM microswimmers holds great promise for chemical sensing, controlled cargo transport, materials science, and even artificial intelligence in ways that are not possible with rigid-bodies microrobots.bodied, nature has created a wide range of biological motors with deformable bodies at small scales. They often have strong ability to actively adapt to their environment, thus can perform various demanding tasks in complex environments. Inspired by nature, researchers have begun to explore the design and control shape-transformable micromotors composed of compliant materials [14,15] (e.g., hydrogels, [16] granular media, [17] lowmelting point alloys, [18,19] and electroactive polymers [14] ) to ensure maneuverability, adaptability and agility in practical applications. Liquid metals (LMs) are typical examples of highly extensible and adaptable compliant materials, [20,21] such as Gallium and gallium-containing alloys (e.g., eutectic gallium-indium (EGaIn): 75% gallium and 25% indium; Galinstan: 68.5% gallium, 21.5% indium, and 10% tin). One of the most striking features of these gallium-based liquid metals is the nearly instant formation of a passivating oxide layer on their surface in the present of oxygen. This oxide layer (mainly composed of Ga 2 O 3 ) mechanically stabilizes the liquid metals into nonequilibrium shapes [22] and can be removed ...
