Textile‐based triboelectric nanogenerators integrated with 2D materials
Textile‐based triboelectric nanogenerators integrated with 2D materials
The human body continuously generates ambient mechanical energy through diverse movements, such as walking and cycling, which can be harvested via various renewable energy harvesting mechanisms. Triboelectric Nanogenerator (TENG) stands out as one of the most promising emerging renewable energy harvesting technologies for wearable applications due to its ability to harness various forms of mechanical energies, including vibrations, pressure, and rotations, and convert them into electricity. However, their application is limited due to challenges in achieving performance, flexibility, low power consumption, and durability. Here, we present a robust and high-performance self-powered system integrated into cotton fabric by incorporating a textile-based triboelectric nanogenerator (T-TENG) based on 2D materials, addressing both energy harvesting and storage. The proposed system extracts significant ambient mechanical energy from human body movements and stores it in a textile supercapacitor (T-Supercap). The integration of 2D materials (graphene and MoS 2) in fabrication enhances the performance of T-TENG significantly, as demonstrated by a record-high open-circuit voltage of 1068 V and a power density of 14.64 W/m 2 under a force of 22 N. The developed T-TENG in this study effectively powers 200+ LEDs and a miniature watch while also charging the T-Supercap with 4-5 N force for efficient miniature electronics operation. Integrated as a step counter within a sock, the T-TENG serves as a self-powered step counter sensor. This work establishes a promising platform for wearable electronic textiles, contributing significantly to the advancement of sustainable and autonomous self-powered wearable technologies. (Figure presented.).
2D materials, e-textiles, energy harvesting, smart materials, textile, wearable technology
Ali, Iftikhar
edcc154b-691f-44be-9ee4-0ba30cd43094
Karim, Nazmul
31555bd6-2dc7-4359-b717-3b2fe223df36
Afroj, Shaila
9b4a7a26-01db-40c7-a933-f07a7ed58a73
21 July 2024
Ali, Iftikhar
edcc154b-691f-44be-9ee4-0ba30cd43094
Karim, Nazmul
31555bd6-2dc7-4359-b717-3b2fe223df36
Afroj, Shaila
9b4a7a26-01db-40c7-a933-f07a7ed58a73
Ali, Iftikhar, Karim, Nazmul and Afroj, Shaila
(2024)
Textile‐based triboelectric nanogenerators integrated with 2D materials.
EcoMat, 6 (7), [e12471].
(doi:10.1002/eom2.12471).
Abstract
The human body continuously generates ambient mechanical energy through diverse movements, such as walking and cycling, which can be harvested via various renewable energy harvesting mechanisms. Triboelectric Nanogenerator (TENG) stands out as one of the most promising emerging renewable energy harvesting technologies for wearable applications due to its ability to harness various forms of mechanical energies, including vibrations, pressure, and rotations, and convert them into electricity. However, their application is limited due to challenges in achieving performance, flexibility, low power consumption, and durability. Here, we present a robust and high-performance self-powered system integrated into cotton fabric by incorporating a textile-based triboelectric nanogenerator (T-TENG) based on 2D materials, addressing both energy harvesting and storage. The proposed system extracts significant ambient mechanical energy from human body movements and stores it in a textile supercapacitor (T-Supercap). The integration of 2D materials (graphene and MoS 2) in fabrication enhances the performance of T-TENG significantly, as demonstrated by a record-high open-circuit voltage of 1068 V and a power density of 14.64 W/m 2 under a force of 22 N. The developed T-TENG in this study effectively powers 200+ LEDs and a miniature watch while also charging the T-Supercap with 4-5 N force for efficient miniature electronics operation. Integrated as a step counter within a sock, the T-TENG serves as a self-powered step counter sensor. This work establishes a promising platform for wearable electronic textiles, contributing significantly to the advancement of sustainable and autonomous self-powered wearable technologies. (Figure presented.).
Text
EcoMat - 2024 - Ali - Textile‐based triboelectric nanogenerators integrated with 2D materials
- Version of Record
More information
Accepted/In Press date: 22 May 2024
e-pub ahead of print date: 18 June 2024
Published date: 21 July 2024
Keywords:
2D materials, e-textiles, energy harvesting, smart materials, textile, wearable technology
Identifiers
Local EPrints ID: 496202
URI: http://eprints.soton.ac.uk/id/eprint/496202
PURE UUID: dc0e6d36-f236-4bff-b1cf-5bf5624ccef1
Catalogue record
Date deposited: 06 Dec 2024 17:47
Last modified: 21 Aug 2025 02:52
Export record
Altmetrics
Contributors
Author:
Iftikhar Ali
Author:
Nazmul Karim
Author:
Shaila Afroj
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics