Soft actuators have received great research attention
because of the recent rise of soft robotics. However, these actuators
could perform only relatively simple deformations (such as bending,
twisting, etc.) for manipulation, limiting their functionality. Here,
we develop highly responsive and shape adaptive soft robotic heaters
which not only can achieve large degree of deformation but also can
grab and heat objects of three-dimensional (3D) curvilinear surfaces.
With intentionally synthesized and selected materials for device fabrication,
a U-shaped soft robotic heater exhibits a deformation angle of more
than 860° and a curvature of 4.0 cm–1 at a
very low voltage of 2 V, and its curvature can quickly reach 1.31
cm–1 within 6 s. Moreover, the device can also function
as a stable heat source with temperature of 203 °C upon actuation,
demonstrating a maximum energy efficiency of 7.44% as a heater. Importantly,
the soft robotic heaters can deform to enclose 3D curvilinear surfaces
with pressure to enable intimate contact for more effective heat transfer.
The unique utility of the soft robotic heaters is illustrated through
the heating of objects of various 3D shapes, showcasing their potential
applications in soft robotics, advanced thermal therapy, food handling
and processing, etc.