Observations on the strong photochromic effect of crystalline TiO 2 quantum dots (mean size ≈ 4 nm) are presented. The synthesized quantum dots consist of irregularly shaped anatase TiO 2 nanoparticles (NPs) and are dispersed in butanol (8% by mass). Obtained NPs exhibit a dramatic photoresponse to UV light, enabling effective transmittance modulation in a broad wavelength range extending from the visible to near-infrared region, and even the thermal black body radiation regime beyond 10 μm. The exceptional photoresponse is attributed to hole-scavenging by butanol, TiO 2 self-reduction, injection of electrons to the conduction band, and consequent localized surface plasmon resonances in NPs. The observed optical effect is reversible, and the initial high transmittance state can be restored simply by exposing the NPs to air. The applied NP synthesis route is economic and can be easily scaled for applications such as smart window technologies.
The present study reports the origin of surface charge on the polymer surface upon triboelectrification and is a step forward towards the development of next generation of mechanical energy harvesting systems.
Contact
electrification and the triboelectric effect are complex
processes for mechanical-to-electrical energy conversion, particularly
for highly deformable polymers. While generating relatively low power
density, contact electrification can occur at the contact–separation
interface between nearly any two polymer surfaces. This ubiquitousness
of surfaces enables contact electrification to be an important phenomenon
to understand energy conversion and harvesting applications. The mechanism
of charge generation between polymeric materials remains ambiguous,
with electron transfer, material (also known as mass) transfer, and
adsorbed chemical species transfer (including induced ionization of
water and other molecules) all being proposed as the primary source
of the measured charge. Often, all sources of charge, except electron
transfer, are dismissed in the case of triboelectric energy harvesters,
leading to the generation of the “triboelectric series”,
governed by the ability of a polymer to lose, or accept, an electron.
Here, this sole focus on electron transfer is challenged through rigorous
experiments, measuring charge density in polymer–polymer (196
polymer combinations), polymer–glass (14 polymers), and polymer–liquid
metal (14 polymers) systems. Through the investigation of these interfaces,
clear evidence of material transfer via heterolytic bond cleavage
is provided. Based on these results, a generalized model considering
the cohesive energy density of polymers as the critical parameter
for polymer contact electrification is discussed. This discussion
clearly shows that material transfer must be accounted for when discussing
the source of charge generated by polymeric mechanical energy harvesters.
Thus, a correlated physical property to understand the triboelectric
series is provided.
Piezoelectric polymers are emerging as exceptionally promising materials for energy harvesting.While the theoretical figures of merit for piezoelectric polymers are comparable to ceramics, the measurement techniques need to be retrofitted to account for the different mechanical properties of the softer polymeric materials. Here, how contact electrification is often mistaken for piezoelectric charge is discussed, through friction and contact separation, and a perspective for how to separate these effects is provided. The state of the literature is assessed, and recommendations are made for This article is protected by copyright. All rights reserved.clear and simple guidelines in reporting, for both sample geometry and testing methods, to enable accurate determination of piezoelectric figures of merit in polymers. Such improvements will allow an understanding of what types of material manipulation are required in order to enhance the piezoelectric output from polymers and enable the next generation of polymer energy harvester design.
It was recently reported that more efficient triboelectric nanogenerator (TENG)-like devices can be prepared using inversely polarized ferroelectric films made of same material as the contacting layers. In the present work, a clear correlation between the piezoelectric response of inversely polarized ferroelectric PVDF/ BaTiO 3 nanocomposite films and the performance of the TENG-like device based on these films is demonstrated. This observation is explained by magnified electrostatic induction that is driven by piezoelectric charges and ferroelectric properties of these films. A double capacitor model is proposed that effectively portrays the interactions between ferroelectric layers during contact−separation and subsequent charge redistributions in the external circuit. The new understanding has allowed the result of 3-fold higher open circuit voltages (2.7 kV from 5 cm 2) as compared to that of a state of the art TENG. Furthermore, findings uncover the potential for vast improvement in the field of nanogenerators for mechanical energy harvesting as a significantly better piezoelectric performance of flexible nanogenerators has been reported elsewhere.
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