Characterization of drying-induced changes in moduli and internal stresses in a constrained gel using laser vibrometry

Characterization of drying-induced changes in moduli and internal stresses in a constrained gel using laser vibrometry

Hydrogels, water-saturated polymer networks find widespread use in soft robotics, biomedical, pharmaceutical and food industries. Both solid and water constituents of hydrogels are sensitive to external stimuli such as temperature, humidity, osmolarity, and light. For instance, common hydrogels swel...

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Veröffentlicht in:Soft matter 2024-01, Vol.2 (4), p.813-822
Hauptverfasser: Yerrapragada, Karthik, Yang, Haocheng, Lee, Wonhyeok, Eriten, Melih
Format: Artikel
Sprache:eng
Schlagworte:
Broadband
Chemical potential
Damping capacity
Damping ratio
Dehydration
Disks
Drying
External stimuli
Food industry
Gelatin
Hydrogels
Internal water
Mechanical analysis
Mechanical properties
Modal damping
Modulus of elasticity
Moisture content
Osmolarity
Polymers
Potential gradient
Residual stress
Resonant frequencies
Robotics
Thick plates
Transverse oscillation
Vibration
Vibration measurement
Vibration mode
Water content
Water loss
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creator Yerrapragada, Karthik
Yang, Haocheng
Lee, Wonhyeok
Eriten, Melih
description Hydrogels, water-saturated polymer networks find widespread use in soft robotics, biomedical, pharmaceutical and food industries. Both solid and water constituents of hydrogels are sensitive to external stimuli such as temperature, humidity, osmolarity, and light. For instance, common hydrogels swell or shrink in the presence of chemical potential gradient between the sample and surrounding environment. Corresponding changes in internal water content lead to significant changes in mechanical properties of hydrogels. Besides, internal stresses build up if the gel samples are constrained during swelling or dehydration. In the present research, we utilize modal analyses technique on drying hydrogels to identify dehydration-induced changes in elastic moduli and internal stresses. In particular, natural frequencies and damping ratios of the first two axisymmetric transverse vibration modes are measured on clamped gelatin disks using non-contact laser vibrometry at various water loss states. Experimental modal frequencies are then compared to the predictions of a pre-stressed thick plate model. The evolutions of elastic moduli and internal stresses for water losses up to 80% are identified. The broadband loss capacity of gelatin is also determined from the measured modal damping ratios. Highly transient mechanical response observed on the gelatin disks further demonstrates the need for non-contact and rapid mechanical characterization of hydrogels. As illustrated in this work, vibration and wave-based techniques are promising candidates to fulfill that need. Water loss in clamped gelatin disks leads to built-up of in-plane stress (A) and increase in elastic modulus (B), as characterized by the laser vibrometry of the first two axisymmetric vibration modes of the disks (C).
doi_str_mv 10.1039/d3sm01328f
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source Royal Society Of Chemistry Journals; Alma/SFX Local Collection
subjects Broadband
Chemical potential
Damping capacity
Damping ratio
Dehydration
Disks
Drying
External stimuli
Food industry
Gelatin
Hydrogels
Internal water
Mechanical analysis
Mechanical properties
Modal damping
Modulus of elasticity
Moisture content
Osmolarity
Polymers
Potential gradient
Residual stress
Resonant frequencies
Robotics
Thick plates
Transverse oscillation
Vibration
Vibration measurement
Vibration mode
Water content
Water loss
title Characterization of drying-induced changes in moduli and internal stresses in a constrained gel using laser vibrometry
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