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Micropatterning of flexible and free standing polyvinylidene difluoride (PVDF) films for enhanced pyroelectric energy transformation

Micropatterning of flexible and free standing polyvinylidene difluoride (PVDF) films for enhanced pyroelectric energy transformation
Micropatterning of flexible and free standing polyvinylidene difluoride (PVDF) films for enhanced pyroelectric energy transformation
In an effort to harvest thermal energy and exploit abundantly available waste heat the pyroelectric effect offers the opportunity to convert temperature fluctuations into useable electrical energy. Here, the micropatterning of the surface of a pyroelectric in order to enhance heat transfer and achieve faster and larger temperature fluctuations, which improve pyroelectric energy transformation, is reported. Methods for the fabrication of partially covered electrodes on polyvinylidene difluoride (PVDF) films are developed to investigate and quantify the benefits of such an electrode structure for pyroelectric energy harvesting. The micropattern consists of an array of holes that are etched into the upper aluminum electrodes of free standing ferroelectric PVDF films using a low cost photolithography and wet etching process. Under the application of infrared radiation heating, it is demonstrated that such microfeatures are able to significantly improve the open circuit voltage by 380% and the closed circuit current by 420% for an electrode area coverage of 45% when compared to a fully covered electrode design. Capacitance measurements show constant electric fields with microfeatures for electrode area coverages as low as 28%. A specific generator performance of 66.9 μJ cm−3 cycle−1 is presented at oscillation temperatures of 2.8 °C.
1614-6832
Zabek, Daniel
7281d29f-829d-4f54-89a2-ee4f48a357af
Taylor, John
f3a9f1ba-4735-4aa4-9767-20c0ce90f9ca
Le Boulbar, Emmanuel
27bec2b7-4be5-4ec5-ac95-4cbe24c19052
Bowen, Chris R.
532014b1-a887-44a1-a5a6-c860d80ed362
Zabek, Daniel
7281d29f-829d-4f54-89a2-ee4f48a357af
Taylor, John
f3a9f1ba-4735-4aa4-9767-20c0ce90f9ca
Le Boulbar, Emmanuel
27bec2b7-4be5-4ec5-ac95-4cbe24c19052
Bowen, Chris R.
532014b1-a887-44a1-a5a6-c860d80ed362

Zabek, Daniel, Taylor, John, Le Boulbar, Emmanuel and Bowen, Chris R. (2015) Micropatterning of flexible and free standing polyvinylidene difluoride (PVDF) films for enhanced pyroelectric energy transformation. Advanced Energy Materials, 5 (8), [1401891]. (doi:10.1002/aenm.201401891).

Record type: Article

Abstract

In an effort to harvest thermal energy and exploit abundantly available waste heat the pyroelectric effect offers the opportunity to convert temperature fluctuations into useable electrical energy. Here, the micropatterning of the surface of a pyroelectric in order to enhance heat transfer and achieve faster and larger temperature fluctuations, which improve pyroelectric energy transformation, is reported. Methods for the fabrication of partially covered electrodes on polyvinylidene difluoride (PVDF) films are developed to investigate and quantify the benefits of such an electrode structure for pyroelectric energy harvesting. The micropattern consists of an array of holes that are etched into the upper aluminum electrodes of free standing ferroelectric PVDF films using a low cost photolithography and wet etching process. Under the application of infrared radiation heating, it is demonstrated that such microfeatures are able to significantly improve the open circuit voltage by 380% and the closed circuit current by 420% for an electrode area coverage of 45% when compared to a fully covered electrode design. Capacitance measurements show constant electric fields with microfeatures for electrode area coverages as low as 28%. A specific generator performance of 66.9 μJ cm−3 cycle−1 is presented at oscillation temperatures of 2.8 °C.

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Published date: 21 January 2015
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Identifiers

Local EPrints ID: 496752
URI: http://eprints.soton.ac.uk/id/eprint/496752
DOI: doi:10.1002/aenm.201401891
ISSN: 1614-6832
PURE UUID: 2acfbe86-c25a-436b-b135-f37433a31013
ORCID for Daniel Zabek: ORCID iD orcid.org/0000-0001-5856-5301

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Date deposited: 07 Jan 2025 23:14
Last modified: 10 Jan 2025 03:21

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Author: Daniel Zabek ORCID iD
Author: John Taylor
Author: Emmanuel Le Boulbar
Author: Chris R. Bowen

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