Abstract
Tactile or electronic skin is needed to provide critical haptic perception to robots and amputees, as well as in wearable electronics for health monitoring and wellness applications. Energy autonomy of skin is a critical feature that would enable better portability and longer operation times. This study shows a novel structure, consisting of a transparent tactile sensitive layer based on single‐layer graphene, and a photovoltaic cell underneath as a building block for energy‐autonomous, flexible, and tactile skin. Transparency of the touch sensitive layer is considered a key feature to allow the photovoltaic cell to effectively harvest light. Moreover, ultralow power consumed by the sensitive layer (20 nW cm−2) further reduces the photovoltaic area required to drive the tactile skin. In addition to its energy autonomy, the fabricated skin is sensitive to touch, mainly because a transparent polymeric protective layer, spin‐coated on the sensor's active area, makes the coplanar capacitor sensitive to touch, detecting minimum pressures of 0.11 kPa with a uniform sensitivity of 4.3 Pa−1 along a broad pressure range. Finally, the tactile skin patches are integrated on a prosthetic hand, and the responses of the sensors for static and dynamic stimuli are evaluated by performing tasks, ranging from simple touching to grabbing of soft objects.
Highlights
Tactile or electronic skin is needed to provide critical haptic perception to robots and amputees, as well as in wearable electronics for health monitoring such as diabetes
We started with the fabrication of a touch-sensitive layer by large-area transfer of graphene on 125-μm-thick, flexible poly vinyl chloride (PVC) substrates
This work presents a promising approach toward the development of an energy-autonomous, flexible, and transparent tactile skin based on single-layer graphene integrated onto a PV cell
Summary
We started with the fabrication of a touch-sensitive layer by large-area transfer of graphene on 125-μm-thick, flexible poly vinyl chloride (PVC) substrates. To analyze the electromechanical properties and cyclic stability of the graphene-on-PVC samples, we applied mechanical stress through a bending test and recorded the resistance change. The active bending test of the flexible graphene-on-PVC sample with an Lc of 33 mm was carried out taking snapshots while measuring RT every 0.2 mm, up to a step size of 4 mm. The resistance change (ΔR/R0) as a function of both the radius of curvature (Rcur) and the strain are shown in Figure 1F,G, respectively. The latter was calculated by[6,35,36]
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