Fractional rheology of colloidal hydrogels with cellulose nanofibers

Isaac Y. Miranda-Valdez; Marie Sourroubille; Tero Mäkinen; Jesús G. Puente-Córdova; Antti Puisto; Juha Koivisto; Mikko J. Alava

doi:10.1007/s10570-023-05694-8

Fractional rheology of colloidal hydrogels with cellulose nanofibers

Isaac Y. Miranda-Valdez^*, Marie Sourroubille, Tero Mäkinen, Jesús G. Puente-Córdova, Antti Puisto, Juha Koivisto, Mikko J. Alava

^*Corresponding author for this work

BA5510 ProperTune Soft Condensed Materials

Research output: Contribution to journal › Article › Scientific › peer-review

12 Citations (Scopus)

Abstract

Abstract: Colloidal gels are soft solids composed of particles dispersed in a fluid phase. Their rheological behavior highly depends on the particle concentration, but establishing a relationship can be challenging. This article showcases the potential of fractional rheology to model and predict linear viscoelastic responses of colloidal hydrogels containing TEMPO-oxidized cellulose nanofibers. Cellulose nanofiber hydrogels are soft solids whose rheology is directly related to the particle concentration. Therefore, this work defined the rheological behavior of the hydrogels using a fractional order derivative analytically solved to determine rheological responses in frequency, stress relaxation, and creep. Using two parameters, it evaluated the rheology of cellulose nanofiber hydrogels and established tests that predict rheological behaviors for given particle concentrations. The findings suggested that the fractional approach could become a standard method for characterizing cellulose nanofiber hydrogels in the reported concentration regime. The two parameters of the fractional model build a comparison framework to assess the rheology of different viscoelastic materials. Graphic abstract: (Figure presented.).

Original language	English
Pages (from-to)	1545-1558
Journal	Cellulose
Volume	31
Issue number	3
DOIs	https://doi.org/10.1007/s10570-023-05694-8
Publication status	Published - Feb 2024
MoE publication type	A1 Journal article-refereed

Funding

Open Access funding provided by Aalto University. I.M-V. thanks to the Finnish Ministry of Education and Culture for financial support via its Finland Fellowship scholarship program. M.J.A. and J.K. thank FinnCERES flagship (151830423), Business Finland (211835), and Future Makers programs. M.J.A., T.M. and I.M-V. thank Business Finland (211909).

Keywords

Cellulose nanofibers
Colloidal gel
Fractional rheology
Linear viscoelasticity
Scott-Blair model

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title = "Fractional rheology of colloidal hydrogels with cellulose nanofibers",

abstract = "Abstract: Colloidal gels are soft solids composed of particles dispersed in a fluid phase. Their rheological behavior highly depends on the particle concentration, but establishing a relationship can be challenging. This article showcases the potential of fractional rheology to model and predict linear viscoelastic responses of colloidal hydrogels containing TEMPO-oxidized cellulose nanofibers. Cellulose nanofiber hydrogels are soft solids whose rheology is directly related to the particle concentration. Therefore, this work defined the rheological behavior of the hydrogels using a fractional order derivative analytically solved to determine rheological responses in frequency, stress relaxation, and creep. Using two parameters, it evaluated the rheology of cellulose nanofiber hydrogels and established tests that predict rheological behaviors for given particle concentrations. The findings suggested that the fractional approach could become a standard method for characterizing cellulose nanofiber hydrogels in the reported concentration regime. The two parameters of the fractional model build a comparison framework to assess the rheology of different viscoelastic materials. Graphic abstract: (Figure presented.).",

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AU - Miranda-Valdez, Isaac Y.

AU - Sourroubille, Marie

AU - Mäkinen, Tero

AU - Puente-Córdova, Jesús G.

AU - Puisto, Antti

AU - Koivisto, Juha

AU - Alava, Mikko J.

PY - 2024/2

Y1 - 2024/2

N2 - Abstract: Colloidal gels are soft solids composed of particles dispersed in a fluid phase. Their rheological behavior highly depends on the particle concentration, but establishing a relationship can be challenging. This article showcases the potential of fractional rheology to model and predict linear viscoelastic responses of colloidal hydrogels containing TEMPO-oxidized cellulose nanofibers. Cellulose nanofiber hydrogels are soft solids whose rheology is directly related to the particle concentration. Therefore, this work defined the rheological behavior of the hydrogels using a fractional order derivative analytically solved to determine rheological responses in frequency, stress relaxation, and creep. Using two parameters, it evaluated the rheology of cellulose nanofiber hydrogels and established tests that predict rheological behaviors for given particle concentrations. The findings suggested that the fractional approach could become a standard method for characterizing cellulose nanofiber hydrogels in the reported concentration regime. The two parameters of the fractional model build a comparison framework to assess the rheology of different viscoelastic materials. Graphic abstract: (Figure presented.).

AB - Abstract: Colloidal gels are soft solids composed of particles dispersed in a fluid phase. Their rheological behavior highly depends on the particle concentration, but establishing a relationship can be challenging. This article showcases the potential of fractional rheology to model and predict linear viscoelastic responses of colloidal hydrogels containing TEMPO-oxidized cellulose nanofibers. Cellulose nanofiber hydrogels are soft solids whose rheology is directly related to the particle concentration. Therefore, this work defined the rheological behavior of the hydrogels using a fractional order derivative analytically solved to determine rheological responses in frequency, stress relaxation, and creep. Using two parameters, it evaluated the rheology of cellulose nanofiber hydrogels and established tests that predict rheological behaviors for given particle concentrations. The findings suggested that the fractional approach could become a standard method for characterizing cellulose nanofiber hydrogels in the reported concentration regime. The two parameters of the fractional model build a comparison framework to assess the rheology of different viscoelastic materials. Graphic abstract: (Figure presented.).

KW - Cellulose nanofibers

KW - Colloidal gel

KW - Fractional rheology

KW - Linear viscoelasticity

KW - Scott-Blair model

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Fractional rheology of colloidal hydrogels with cellulose nanofibers

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