Triboelectric Characterization of Colloidal TiO2 for Energy Harvesting Applications

Garofalo, Erik; Cecchini, Luca; Bevione, Matteo; Chiolerio, Alessandro

doi:10.3390/nano10061181

Cited by 13 publications

(10 citation statements)

References 35 publications

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“…Thus, the idea to combine solid and liquid properties to achieve better results in harvesting efficiency for applications where flexibility is fundamental, exploiting the properties of nanomaterials, comes straightforward. The use of colloids, defined as solid nanoparticles dispersed in a carrier fluid, is our natural framework, in a study that starts from a toroidal dynamo (TORODYNA) exploiting thermomagnetic advection, 15 encompasses triboelectric colloids, 16 and finally aims at creating colloidal energy systems. 17 Here, an experimental apparatus for monitoring the shortcircuit current and open-circuit voltage production brought by the PyE colloid under different heating conditions is presented.…”

Section: Discussion Pointsmentioning

confidence: 99%

“…The functional colloid is heated up in a reservoir by means of a heating plate and then forced using a peristaltic pump into a Fluorinated Ethylene Propylene (FEP) pipe. 16 Along the loop the fluid is subject to forced convection cooling. In order to collect the electrostatic charges developed thanks to the PyE and carried by the BT NPs, two titanium electrodes are placed along the pipe going in direct contact with the colloid.…”

Section: Discussion Pointsmentioning

confidence: 99%

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Liquid-state pyroelectric energy harvesting

Bevione

Garofalo

Cecchini

et al. 2020

MRS Energy & Sustainability

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Section: Discussion Pointsmentioning

confidence: 99%

Section: Discussion Pointsmentioning

confidence: 99%

Liquid-state pyroelectric energy harvesting

Bevione

Garofalo

Cecchini

et al. 2020

MRS Energy & Sustainability

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“…The idea is to combine solid and liquid properties, realizing a stable suspension of nanoparticles in a carrier fluid, and move this mixture by means of the combination of thermal and magnetic flux gradient. This thermomagnetic motion will allow the nanoparticles to crawl on the walls of the container, provoking charge accumulation by means of a triboelectric process, [ 81 ] and experience a temperature variation in time, provoking pyroelectrification. [ 82 ] The device has been tested only in the laboratory and still needs some improvements to be reproduced in a large scale.…”

Section: Industrial Applicationsmentioning

confidence: 99%

Waste Heat to Power: Technologies, Current Applications, and Future Potential

et al. 2020

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Energy consumption, environmental impact, and sustainability have risen fast through the ranks, achieving the first places in driving investments, policies, and concerns of all countries at any developmental stage. Energy transformation, though, must cope with nonunitary efficiency of devices and processes, which results in a distributed production of waste heat. A reduction of emissions, implying a conversion of waste heat to more noble forms of energy and a concurrent increase in efficiency of the same devices and processes, is of paramount importance. In view of the enthalpy content and distribution of the different sources of waste heat, low‐grade/low‐enthalpy sources below 200 °C are considered the most fertile field for research and development, with an impressive industrial growth rate. Thermodynamic cycles and thermal conversion devices based on the most relevant physical effects are herein introduced and briefly described, including both solutions that already achieved industrial maturity and less developed systems and devices whose study is still in progress. A specific focus on three application domains, selected due to their economic relevance, is done: industrial processes for the vast energy and capital availability, automotive sector for its permeation, and wearable devices for the market size. Limits and opportunities are critically discussed.

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“…Titanium dioxide, also known as titania, belongs to the class of transitions metal oxides [26]. TiO 2 has attracted a wide range of interests in the research community owing to its proven ability for many applications in the medical field [27,28], environmental protection [29][30][31], renewable energy [32], etc. TiO 2 is widely employed in solar energy devices, typically used as electron transporting material in nanostructured TiO 2 perovskite-sensitized solar cells and semiconductor in dye sensitized solar cell architecture [18,19,33,34].…”

Section: Introductionmentioning

confidence: 99%

Density Functional Theory Study of Optical and Electronic Properties of (TiO2)n=5,8,68 Clusters for Application in Solar Cells

2021

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A range of solution-processed organic and hybrid organic−inorganic solar cells, such as dye-sensitized and bulk heterojunction organic solar cells have been intensely developed recently. TiO2 is widely employed as electron transporting material in nanostructured TiO2 perovskite-sensitized solar cells and semiconductor in dye-sensitized solar cells. Understanding the optical and electronic mechanisms that govern charge separation, transport and recombination in these devices will enhance their current conversion efficiencies under illumination to sunlight. In this work, density functional theory with Perdew-Burke Ernzerhof (PBE) functional approach was used to explore the optical and electronic properties of three modeled TiO2 brookite clusters, (TiO2)n=5,8,68. The simulated optical absorption spectra for (TiO2)5 and (TiO2)8 clusters show excitation around 200–400 nm, with (TiO2)8 cluster showing higher absorbance than the corresponding (TiO2)5 cluster. The density of states and the projected density of states of the clusters were computed using Grid-base Projector Augmented Wave (GPAW) and PBE exchange correlation functional in a bid to further understand their electronic structure. The density of states spectra reveal surface valence and conduction bands separated by a band gap of 1.10, 2.31, and 1.37 eV for (TiO2)5, (TiO2)8, and (TiO2)68 clusters, respectively. Adsorption of croconate dyes onto the cluster shifted the absorption peaks to higher wavelengths.

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Triboelectric Characterization of Colloidal TiO2 for Energy Harvesting Applications

Cited by 13 publications

References 35 publications

Liquid-state pyroelectric energy harvesting

Liquid-state pyroelectric energy harvesting

Waste Heat to Power: Technologies, Current Applications, and Future Potential

Density Functional Theory Study of Optical and Electronic Properties of (TiO2)n=5,8,68 Clusters for Application in Solar Cells

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