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Cellulose

pp 1–13 | Cite as

Printing and mechanical characterization of cellulose nanofibril materials

  • Lisa M. Mariani
  • William R. JohnsonIII
  • John M. Considine
  • Kevin T. TurnerEmail author
Original Research
  • 52 Downloads

Abstract

Cellulose nanofibrils (CNF) are a promising building block of structural materials because they are biodegradable, can be made into optically transparent bulk materials, and have exceptional specific strength and stiffness compared to common synthetic polymers. The manufacturing of bulk materials from CNFs is a challenge because CNFs form networks in solution at low solids concentration, which can result in long processing times as well as large residual stresses and distortion upon water removal. Here, a method to form materials from CNF suspensions via direct ink writing, a type of additive manufacturing, is demonstrated. Multilayer printing of CNFs provides a route to control drying time by depositing thin layers one at a time. A printing system with a pressure-controlled dispensing system was used to deposit aqueous CNF suspensions onto a temperature-controlled substrate. The geometry, roughness, and mechanical properties of the printed structures were characterized. The shape of the printed line profile is controlled by a combination of the wettability of the substrate, dispense rate, printing speed, and temperature of the substrate. Spatial variation of the elastic modulus of printed CNF structures was assessed with nanoindentation and the average percent difference was found to be small at ± 2.6% of the mean over the area of the printed lines. Through multilayer printing freestanding films with thicknesses greater than 60 μm were achieved. Tensile specimens were printed and characterized; a tensile strength of 72.6 MPa ± 7.4 MPa and a Young’s modulus of 10.2 GPa ± 1.2 GPa were measured.

Graphical abstract

Keywords

Nanocellulose Cellulose nanofibers Nanofibrillated cellulose Printing Additive manufacturing Mechanical properties 

Notes

Acknowledgments

This work was supported by the U.S. Endowment for Forestry and Communities, Inc. as part of the P3Nano program. This work was performed in part at the University of Pennsylvania’s Singh Center for Nanotechnology, an NNCI member supported by NSF Grant ECCS-1542153. The authors thank Dr. Joseph E. Jakes (USDA Forest Service, Forest Products Laboratory) for insightful nanoindentation discussions. The authors also thank Dr. Alexander I. Bennett (University of Pennsylvania) for helpful discussions and assistance in preparing Figs. 1 and 2.

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Copyright information

© Springer Nature B.V. 2019

Authors and Affiliations

  1. 1.Department of Mechanical Engineering and Applied MechanicsUniversity of PennsylvaniaPhiladelphiaUSA
  2. 2.USDA Forest Service, Forest Products LaboratoryMadisonUSA

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