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Cain, M.
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Publications (11/11 displayed)
- 2024Ultrasound Stimulation of Piezoelectric Nanocomposite Hydrogels Boosts Chondrogenic Differentiation <i>in Vitro</i>, in Both a Normal and Inflammatory Milieu.citations
- 2016Dielectric constants of bulk ferroelectric PZTmeasured by terahertz time-domain spectroscopycitations
- 2013ZnO nanogenerators - Energy generation through scavenging vibration, advantages of using a diodecitations
- 2013ZnO nanostructured diodes - Enhancing energy generation through scavenging vibrationcitations
- 2013Measurement techniques for piezoelectric nanogeneratorscitations
- 2013Passivation of zinc oxide nanowires for improved piezoelectric energy harvesting devicescitations
- 2012Charge redistribution in piezoelectric energy harvesterscitations
- 2012Nanostructured p-n junctions for kinetic-to-electrical energy conversioncitations
- 2012Nanostructured zinc oxide piezoelectric energy generators based on semiconductor P-N junctionscitations
- 2010Pyroelectric contributions to piezoelectric hydrostatic Berlincourt methodcitations
- 2000Testing for statistical and market efficiency when forecast errors are non-normal: the NFL betting market revisted
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article
Nanostructured p-n junctions for kinetic-to-electrical energy conversion
Abstract
Piezoelectric ZnO nanorods grown on a flexible substrate are combined with the p-type semiconducting polymer PEDOT:PSS to produce a p-n junction device that successfully demonstrates kinetic-to-electrical energy conversion. Both the voltage and current output of the devices are measured to be in the range of 10 mV and 10 μA cm−2. Combining these figures for the best device gives a maximum possible power density of 0.4 mW cm−3. Systematic testing of the devices is performed showing that the voltage output increases linearly with applied stress, and is reduced significantly by illumination with super-band gap light. This provides strong evidence that the voltage output results from piezoelectric effects in the ZnO. The behavior of the devices is explained by considering the time-dependent changes in band structure resulting from the straining of a piezoelectric material within a p-n junction. It is shown that the rate of screening of the depolarisation field determines the power output of a piezoelectric energy harvesting device. This model is consistent with the behavior of a number of previous devices utilising the piezoelectric effect in ZnO.