“Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor

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Standard

“Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor. / Li, Xueting; He, Rongtong; Liu, Xingxun; Blennow, Andreas; Ye, Qichao; Hong, Bingbing; Li, Xiaonan; Lu, Lu; Cui, Bo.

I: Sustainable Materials and Technologies, Bind 41, e01049, 2024.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Li, X, He, R, Liu, X, Blennow, A, Ye, Q, Hong, B, Li, X, Lu, L & Cui, B 2024, '“Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor', Sustainable Materials and Technologies, bind 41, e01049. https://doi.org/10.1016/j.susmat.2024.e01049

APA

Li, X., He, R., Liu, X., Blennow, A., Ye, Q., Hong, B., Li, X., Lu, L., & Cui, B. (2024). “Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor. Sustainable Materials and Technologies, 41, [e01049]. https://doi.org/10.1016/j.susmat.2024.e01049

Vancouver

Li X, He R, Liu X, Blennow A, Ye Q, Hong B o.a. “Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor. Sustainable Materials and Technologies. 2024;41. e01049. https://doi.org/10.1016/j.susmat.2024.e01049

Author

Li, Xueting ; He, Rongtong ; Liu, Xingxun ; Blennow, Andreas ; Ye, Qichao ; Hong, Bingbing ; Li, Xiaonan ; Lu, Lu ; Cui, Bo. / “Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor. I: Sustainable Materials and Technologies. 2024 ; Bind 41.

Bibtex

@article{a2c97d89f93e41c6b450bc7c9477a22e,

title = "“Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor",

abstract = "Underwater wearable sensors utilizing conductive hydrogels have garnered significant attention in recent years. However, the response sensitivity to the mechanical strain, quantified by the gauge factor (GF), of most hydrogels is noticeably diminished when submerged in water, and little consideration has been given to the GF value of sensors operating both in air and underwater. Consequently, the development of underwater sensors with high sensitivity in aquatic environments remains a challenge. In this study, we propose a “soaking-in-water” strategy to enhance the sensitivity of the wearable sensor based on starch/poly(vinyl alcohol)/graphene oxide/ionic liquid hydrogel. Through this approach, the maximum GF of the hydrogel underwater was improved to 9.71, representing an 86.7% increase compared to the unsoaked hydrogel (GF of 5.20). Furthermore, the hydrogel demonstrated adjustable conductivity (from 0.26 to 1.82 S·m−1) and tensile properties (from 0.05 MPa at 244% to 0.21 MPa at 527%). The hydrogel underwent the processes of water-absorbing swelling, exudation of ionic liquid and water-repelling shrinkage. The enhancement in sensitivity and swelling mechanism of the hydrogel were closely linked to the movement of ions and water between the hydrogel and soaking water. Leveraging these properties, we further developed an underwater strain sensor capable of monitoring human motions underwater, offering quick, effective, and stable signal transmission. The proposed soaking method represents a promising avenue for improving the sensitivity of hydrogel sensors, providing a facile strategy for achieving accurate and efficient underwater monitoring applications.",

keywords = "Ions/water movement, Sensitivity, Starch-based hydrogels, Swelling, Underwater wearable sensor",

author = "Xueting Li and Rongtong He and Xingxun Liu and Andreas Blennow and Qichao Ye and Bingbing Hong and Xiaonan Li and Lu Lu and Bo Cui",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier B.V.",

year = "2024",

doi = "10.1016/j.susmat.2024.e01049",

language = "English",

volume = "41",

journal = "Sustainable Materials and Technologies",

issn = "2214-9937",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - “Soaking-in-water” strategy stimulated starch/poly(vinyl alcohol)-based flexible hydrogel with heterogeneous network for highly sensitive underwater wearable sensor

AU - Li, Xueting

AU - He, Rongtong

AU - Liu, Xingxun

AU - Blennow, Andreas

AU - Ye, Qichao

AU - Hong, Bingbing

AU - Li, Xiaonan

AU - Lu, Lu

AU - Cui, Bo

PY - 2024

Y1 - 2024

N2 - Underwater wearable sensors utilizing conductive hydrogels have garnered significant attention in recent years. However, the response sensitivity to the mechanical strain, quantified by the gauge factor (GF), of most hydrogels is noticeably diminished when submerged in water, and little consideration has been given to the GF value of sensors operating both in air and underwater. Consequently, the development of underwater sensors with high sensitivity in aquatic environments remains a challenge. In this study, we propose a “soaking-in-water” strategy to enhance the sensitivity of the wearable sensor based on starch/poly(vinyl alcohol)/graphene oxide/ionic liquid hydrogel. Through this approach, the maximum GF of the hydrogel underwater was improved to 9.71, representing an 86.7% increase compared to the unsoaked hydrogel (GF of 5.20). Furthermore, the hydrogel demonstrated adjustable conductivity (from 0.26 to 1.82 S·m−1) and tensile properties (from 0.05 MPa at 244% to 0.21 MPa at 527%). The hydrogel underwent the processes of water-absorbing swelling, exudation of ionic liquid and water-repelling shrinkage. The enhancement in sensitivity and swelling mechanism of the hydrogel were closely linked to the movement of ions and water between the hydrogel and soaking water. Leveraging these properties, we further developed an underwater strain sensor capable of monitoring human motions underwater, offering quick, effective, and stable signal transmission. The proposed soaking method represents a promising avenue for improving the sensitivity of hydrogel sensors, providing a facile strategy for achieving accurate and efficient underwater monitoring applications.

AB - Underwater wearable sensors utilizing conductive hydrogels have garnered significant attention in recent years. However, the response sensitivity to the mechanical strain, quantified by the gauge factor (GF), of most hydrogels is noticeably diminished when submerged in water, and little consideration has been given to the GF value of sensors operating both in air and underwater. Consequently, the development of underwater sensors with high sensitivity in aquatic environments remains a challenge. In this study, we propose a “soaking-in-water” strategy to enhance the sensitivity of the wearable sensor based on starch/poly(vinyl alcohol)/graphene oxide/ionic liquid hydrogel. Through this approach, the maximum GF of the hydrogel underwater was improved to 9.71, representing an 86.7% increase compared to the unsoaked hydrogel (GF of 5.20). Furthermore, the hydrogel demonstrated adjustable conductivity (from 0.26 to 1.82 S·m−1) and tensile properties (from 0.05 MPa at 244% to 0.21 MPa at 527%). The hydrogel underwent the processes of water-absorbing swelling, exudation of ionic liquid and water-repelling shrinkage. The enhancement in sensitivity and swelling mechanism of the hydrogel were closely linked to the movement of ions and water between the hydrogel and soaking water. Leveraging these properties, we further developed an underwater strain sensor capable of monitoring human motions underwater, offering quick, effective, and stable signal transmission. The proposed soaking method represents a promising avenue for improving the sensitivity of hydrogel sensors, providing a facile strategy for achieving accurate and efficient underwater monitoring applications.

KW - Ions/water movement

KW - Sensitivity

KW - Starch-based hydrogels

KW - Swelling

KW - Underwater wearable sensor

U2 - 10.1016/j.susmat.2024.e01049

DO - 10.1016/j.susmat.2024.e01049

M3 - Journal article

AN - SCOPUS:85198534373

VL - 41

JO - Sustainable Materials and Technologies

JF - Sustainable Materials and Technologies

SN - 2214-9937

M1 - e01049

ER -

ID: 400216619