Materials Research Express (Jan 2024)
Multifunctional tri-electrode sensors for the measurement of displacement, force, and infrared irradiation
Abstract
Here we described the effect of displacement, force and infrared irradiation on the resistance and impedance of tri-electrode multifunctional sensors. These sensors are based on the gel type composite of carbon nanotubes (CNT), nickel phthalocyanine (NiPc) and edible oil. The channel of this tri-electrodes (field effect transistors) structure is made of CNT-NiPc-oil gel composite using rubbing-in technology. The tri-electrode sensors’ response depends upon the direction of force/displacement and shows an anisotropy. Application of force or displacement from the top causes to decrease resistance and the impedance and vice versa in case of applying force or displacement from the side. The displacement and force sensitivities were up to −273.3 Ω μm ^−1 and −46.5 Ω gf ^−1 from the top and 480.0 Ω μm ^−1 and 3.1 × 10 ^2 Ω gf ^−1 from the side, respectively, for the sensing ranges 0–150 μm and 0–215 gf. Under the effect of the infrared irradiation from any direction the impedance and the resistance of the sensor reduces. On changing infrared irradiation intensity from 0 to 2500 W m ^−2 the sensitivities from top and side of the sensor were −37.4 Ωm ^2 W ^−1 and −16.5 Ωm ^2 W ^−1 , respectively. The investigated sensors may potentially be used as prototypes to develop gel-electronic-based shockproof sensors. The technological achievement in fabricating these devices is the consumption of environmentally friendly materials, particularly edible oil (organic). The edible oil allows to formulate uniform composite gel-films, that may not be comprehended only by ingredients mixing. The fabricated sensors are highly attractive for commercialization.
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