Abstract
AbstractElectric nanogenerators that directly convert the energy of moving drops into electrical signals require hydrophobic substrates with a high density of static electric charge that is stable in “harsh environments” created by continued exposure to potentially saline water. The recently proposed charge‐trapping electric generators (CTEGs) that rely on stacked inorganic oxide–fluoropolymer (FP) composite electrets charged by homogeneous electrowetting‐assisted charge injection (h‐EWCI) seem to solve both problems, yet the reasons for this success have remained elusive. Here, systematic measurements at variable oxide and FP thickness, charging voltage, and charging time and thermal annealing up to 230 °C are reported, leading to a consistent model of the charging process. It is found to be controlled by an energy barrier at the water‐FP interface, followed by trapping at the FP‐oxide interface. Protection by the FP layer prevents charge densities up to −1.7 mC m−2 from degrading and the dielectric strength of SiO2 enables charge decay times up to 48 h at 230 °C, suggesting lifetimes against thermally activated discharging of thousands of years at room temperature. Combining high dielectric strength oxides and weaker FP top coatings with electrically controlled charging provides a new paradigm for developing ultrastable electrets for applications in energy harvesting and beyond.
Highlights
Combining high dielectric strength oxides and weaker FP top coatings with electrically controlled charging insulation properties,[20] and should be hydrophobic to avoid discharging due to ambient humidity.[23,24,25,26]
The same conditions apply to dielectric materials in electrowetting-on-dielectric provides a new paradigm for developing ultrastable electrets for applications (EWOD) applications.[27,28]
Following, we focus on the regime |UC| > |Umin|, where the excess surface potential beyond U0 is obviously caused by charge carriers that are injected into the sample during the charging phase
Summary
Electric nanogenerators that directly convert the energy of moving drops into attention.[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16] The efficiency of triboelectric nanogenerators is, limelectrical signals require hydrophobic substrates with a high density of static ited by the relatively small[1,6,7,8,9,11,12,13,14] and electric charge that is stable in “harsh environments” created by continued exposure to potentially saline water. Combining high dielectric strength oxides and weaker FP top coatings with electrically controlled charging insulation properties,[20] and should be hydrophobic to avoid discharging due to ambient humidity.[23,24,25,26]. The same conditions apply to dielectric materials in electrowetting-on-dielectric provides a new paradigm for developing ultrastable electrets for applications (EWOD) applications.[27,28] In EWOD, in energy harvesting and beyond. These conditions are often satisfied by using composite dielectrics that consist of an insulating, high dielectric strength. (tribo)electric nanogenerators that convert mechanical energy Recently, it was demonstrated that this effect, which into electrical energy have recently attracted substantial is preferentially localized near the three-phase contact line due to local field enhancement[34,41] can be transformed into
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