Bio-Graphene Sensors for Monitoring Moisture Levels in Wood and Ambient Environment

Overview

Journal Glob Chall

Date 2023 Apr 6

PMID 37020627

Authors

Mohammad Yusuf Mulla

Patrik Isacsson

Illia Dobryden

Valerio Beni

Emma Ostmark

Karl Hakansson

Jesper Edberg

Affiliations

Soon will be listed here.

Abstract

Wood is an inherently hygroscopic material which tends to absorb moisture from its surrounding. Moisture in wood is a determining factor for the quality of wood being employed in construction, since it causes weakening, deformation, rotting, and ultimately leading to failure of the structures resulting in costs to the economy, the environment, and to the safety of residents. Therefore, monitoring moisture in wood during the construction phase and after construction is vital for the future of smart and sustainable buildings. Employing bio-based materials for the construction of electronics is one way to mitigate the environmental impact of such electronics. Herein, a bio-graphene sensor for monitoring the moisture inside and around wooden surfaces is fabricated using laser-induced graphitization of a lignin-based ink precursor. The bio-graphene sensors are used to measure humidity in the range of 10% up to 90% at 25 °C. Using laser induced graphitization, conductor resistivity of 18.6 Ω sq is obtained for spruce wood and 57.1 Ω sq for pine wood. The sensitivity of sensors fabricated on spruce and pine wood is 2.6 and 0.74 MΩ per % RH. Surface morphology and degree of graphitization are investigated using scanning electron microscopy, Raman spectroscopy, and thermogravimetric analysis methods.

Citing Articles

Iron-Catalyzed Laser-Induced Graphitization - Multiscale Analysis of the Structural Evolution and Underlying Mechanism.

Dreimol C, Kursteiner R, Ritter M, Parrilli A, Edberg J, Garemark J Small. 2024; 20(49):e2405558.

PMID: 39279332 PMC: 11618722. DOI: 10.1002/smll.202405558.

Bio-Graphene Sensors for Monitoring Moisture Levels in Wood and Ambient Environment.

Mulla M, Isacsson P, Dobryden I, Beni V, Ostmark E, Hakansson K Glob Chall. 2023; 7(4):2200235.

PMID: 37020627 PMC: 10069311. DOI: 10.1002/gch2.202200235.

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