Preparation of Model Surfaces to Mimic Porous Cellulose Structures

Tiinamari Seppänen; Kristoffer Meinander; Monika Österberg; Emily D. Cranston; Tekla Tammelin

doi:10.1002/admi.202500498

Preparation of Model Surfaces to Mimic Porous Cellulose Structures

Tiinamari Seppänen
, Kristoffer Meinander
, Monika Österberg
, Emily D. Cranston^*
, Tekla Tammelin^*

^*Corresponding author for this work

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

Abstract

Porous cellulose and nanocellulose materials, such as foams and aerogels, are widely used in numerous applications due to their large surface area, sorption capacity, mechanical resilience, and overall versatility. Additionally, porous cellulose materials provide extensive interaction sites that can facilitate a variety of chemical processes. Herein, ultrathin nanocellulose model surfaces with a 2D open‐pore structure are presented that mimic the complexity of porous cellulose fiber materials. A sacrificial templating approach is used by spin coating a mixture of 2,2,6,6‐tetramethylpiperidin‐1‐oxyl‐oxidized cellulose nanofibrils (TOCNFs) and polystyrene (PS) nanoparticles onto a silicon wafer, followed by selective nanoparticle dissolution. Scanning electron microscopy and atomic force microscopy reveal an ultrathin TOCNF layer with hierarchical morphology and spherical open pores (70 nm diameter), with a root mean square roughness of 19 nm. The surface coverage of nanoparticles is controlled primarily by changing the TOCNF concentration, and to a lesser extent, the ratio between PS nanoparticles and TOCNFs. X‐ray photoelectron spectroscopy supports the complete removal of the PS template, leaving behind a pure TOCNFs layer. Open‐pore structured nanocellulose model surfaces provide a tool to investigate interfacial phenomena in porous materials constructed from fibers and/or nanocelluloses, thus advancing the engineering of functional porous cellulose‐based materials.

Original language	English
Article number	e00498
Journal	Advanced Materials Interfaces
DOIs	https://doi.org/10.1002/admi.202500498
Publication status	E-pub ahead of print - 2025
MoE publication type	A1 Journal article-refereed

Funding

This research was funded by the European Regional Development Fund through Piloting Alternatives for Plastics and Energy 1st projects (grant numbers A75938 and 402755) and the Academy of Finland Flagship Program FinnCERES (grant numbers 318890 and 318891). We gratefully acknowledge Panu Lahtinen for the TOCNF preparation, Jingqian Chen and Orlando Rojas for providing the lignin nanoparticles, the UBC Bioimaging facility (RRID: SCR_021304) for facilities and technical advice for using the SEM, Marcus Johns for the AFM images, and Giuliana Franco for the AFM images and ellipsometry measurements. This work was part of the Academy of Finland Flagship Programme Competence Center for Materials Bioeconomy, FinnCERES, and Bioproducts Institute portfolio administered by The University of British Columbia. T.S. is grateful for the opportunity for mobility to UBC, made possible through the FinnCERES and Boreal Alliance network. E. D. C. is grateful for support and recognition through the University of British Columbia's President's Excellence Chair initiative, the NSERC E.W.R. Steacie Memorial Fellowship, and the Canadian Foundation for Innovation (John R. Evans Leaders Fund) for equipment.

Keywords

Aerogels
Foams
Model surfaces
Nanocellulose
porous cellulose materials
Sacrificial templating
Ultrathin films
nanocellulose
model surfaces
foams
ultrathin films
sacrificial templating
aerogels

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title = "Preparation of Model Surfaces to Mimic Porous Cellulose Structures",

abstract = "Porous cellulose and nanocellulose materials, such as foams and aerogels, are widely used in numerous applications due to their large surface area, sorption capacity, mechanical resilience, and overall versatility. Additionally, porous cellulose materials provide extensive interaction sites that can facilitate a variety of chemical processes. Herein, ultrathin nanocellulose model surfaces with a 2D open‐pore structure are presented that mimic the complexity of porous cellulose fiber materials. A sacrificial templating approach is used by spin coating a mixture of 2,2,6,6‐tetramethylpiperidin‐1‐oxyl‐oxidized cellulose nanofibrils (TOCNFs) and polystyrene (PS) nanoparticles onto a silicon wafer, followed by selective nanoparticle dissolution. Scanning electron microscopy and atomic force microscopy reveal an ultrathin TOCNF layer with hierarchical morphology and spherical open pores (70 nm diameter), with a root mean square roughness of 19 nm. The surface coverage of nanoparticles is controlled primarily by changing the TOCNF concentration, and to a lesser extent, the ratio between PS nanoparticles and TOCNFs. X‐ray photoelectron spectroscopy supports the complete removal of the PS template, leaving behind a pure TOCNFs layer. Open‐pore structured nanocellulose model surfaces provide a tool to investigate interfacial phenomena in porous materials constructed from fibers and/or nanocelluloses, thus advancing the engineering of functional porous cellulose‐based materials.",

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author = "Tiinamari Sepp{\"a}nen and Kristoffer Meinander and Monika {\"O}sterberg and Cranston, \{Emily D.\} and Tekla Tammelin",

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N2 - Porous cellulose and nanocellulose materials, such as foams and aerogels, are widely used in numerous applications due to their large surface area, sorption capacity, mechanical resilience, and overall versatility. Additionally, porous cellulose materials provide extensive interaction sites that can facilitate a variety of chemical processes. Herein, ultrathin nanocellulose model surfaces with a 2D open‐pore structure are presented that mimic the complexity of porous cellulose fiber materials. A sacrificial templating approach is used by spin coating a mixture of 2,2,6,6‐tetramethylpiperidin‐1‐oxyl‐oxidized cellulose nanofibrils (TOCNFs) and polystyrene (PS) nanoparticles onto a silicon wafer, followed by selective nanoparticle dissolution. Scanning electron microscopy and atomic force microscopy reveal an ultrathin TOCNF layer with hierarchical morphology and spherical open pores (70 nm diameter), with a root mean square roughness of 19 nm. The surface coverage of nanoparticles is controlled primarily by changing the TOCNF concentration, and to a lesser extent, the ratio between PS nanoparticles and TOCNFs. X‐ray photoelectron spectroscopy supports the complete removal of the PS template, leaving behind a pure TOCNFs layer. Open‐pore structured nanocellulose model surfaces provide a tool to investigate interfacial phenomena in porous materials constructed from fibers and/or nanocelluloses, thus advancing the engineering of functional porous cellulose‐based materials.

AB - Porous cellulose and nanocellulose materials, such as foams and aerogels, are widely used in numerous applications due to their large surface area, sorption capacity, mechanical resilience, and overall versatility. Additionally, porous cellulose materials provide extensive interaction sites that can facilitate a variety of chemical processes. Herein, ultrathin nanocellulose model surfaces with a 2D open‐pore structure are presented that mimic the complexity of porous cellulose fiber materials. A sacrificial templating approach is used by spin coating a mixture of 2,2,6,6‐tetramethylpiperidin‐1‐oxyl‐oxidized cellulose nanofibrils (TOCNFs) and polystyrene (PS) nanoparticles onto a silicon wafer, followed by selective nanoparticle dissolution. Scanning electron microscopy and atomic force microscopy reveal an ultrathin TOCNF layer with hierarchical morphology and spherical open pores (70 nm diameter), with a root mean square roughness of 19 nm. The surface coverage of nanoparticles is controlled primarily by changing the TOCNF concentration, and to a lesser extent, the ratio between PS nanoparticles and TOCNFs. X‐ray photoelectron spectroscopy supports the complete removal of the PS template, leaving behind a pure TOCNFs layer. Open‐pore structured nanocellulose model surfaces provide a tool to investigate interfacial phenomena in porous materials constructed from fibers and/or nanocelluloses, thus advancing the engineering of functional porous cellulose‐based materials.

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Preparation of Model Surfaces to Mimic Porous Cellulose Structures

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