TENG and PENG are extensively studied and potential devices to harness abundantly
available mechanical energy in the environment. These can power electronics without an
external power source under continuous mechanical input in integration with capacitors.
Recent advancements in nanotechnology promoted the advancement and miniaturization
of nanogenerators. These devices can be integrated into wearable electronics for energy
generation and sensing applications (Figure 14.1).
TENG works on the dual principles of triboelectric charging and electric induction. When
two dissimilar materials come into contact, static charges will be produced at their interface
that makes one material positively charged and the other one negatively charged based on
their tendency to gain or lose electrons and generates a potential difference between the
materials. When they are separated, electrons flow from negatively charged material to
positively charged material through the external circuit producing electricity. Based on the
position of material in the triboelectric series, it can be used as either positive material or
negative material. Materials that are far away from each other in the series generate
stronger charges when they come to contact. The common working modes of TENG are
metal-on-dielectric and dielectric-on-dielectric pairs. These can be assembled in various
configurations such as (i) contact sliding mode, (ii) linear sliding mode, (iii) single electrode
mode, and (iv) free-standing mode, as shown in Figure 14.2(i) [25].
Many materials such as wool, rabbit fur, hair, mustard seeds, poly(vinylidene fluoride)
(PVDF), Kapton, lead, etc. show triboelectric effect. Singh et al. developed TENG using
mustard seeds as a positive layer and PVDF as a negative layer which delivered an open
circuit voltage of 84 V and power density of 334 mW/m2 at a force of 40 N at 25 Hz
frequency [26]. The major advantages of TENG are cost-effectiveness, easy design, large
output power, and high conversion efficiency. It was established that the performance
and application of TENG greatly depend on the material used for fabrication.
The use of nanomaterials in these nanogenerators has been reported extensively for a
wide variety of sensing applications [27]. Recently Hao et al. used a flexible self-rebound
FIGURE 14.1
Metal organic framework ecosystem based on nanogenerators for powering wearable biosensors. Adapted with
permission [ 21], Copyright (2011) Elsevier, [ 22], Copyright (2012) Springer Nature, [ 23]. Copyright (2020)
Elsevier and [ 24], Copyright (2019) Elsevier.
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