Abstract
TEMPO-oxidized cellulose nanofibrils (TCNFs) have unique properties, which can be utilised in many application fields from printed electronics to packaging. Visual characterisation of TCNFs has been commonly performed using Scanning Electron Microscopy (SEM). However, a novel imaging technique, Helium Ion Microscopy (HIM), offers benefits over SEM, including higher resolution and the possibility of imaging non-conductive samples uncoated. HIM has not been widely utilized so far, and in this study the capability of HIM for imaging of TCNFs was evaluated. Freeze drying and critical point drying (CPD) techniques were applied to preserve the open fibril structure of the gel-like TCNFs. Both drying methods worked well, but CPD performed better resulting in the specific surface area of 386 m2 g−1 when compared to 172 m2 g−1 and 42 m2 g−1 of freeze dried samples frozen in propane and nitrogen, respectively. HIM imaging of TCNFs was successful but high magnification imaging was challenging because the ion beam tended to degrade the TCNFs. The effect of the imaging parameters on the degradation was studied and an ion dose as low as 0.9 ion per nm2 was required to prevent the damage. This study points out the differences between the gentle drying methods of TCNFs and demonstrates beam damage during imaging like none previously reported with HIM. The results can be utilized in future studies of cellulose or other biological materials as there is a growing interest for both the HIM technique and bio-based materials.
Highlights
Cellulose nano brils (CNFs) have been under intensive investigation due to their unique properties, such as high tensile strength, large speci c surface area, rheology and tendency for lm formation.[1]
Blue colour could be a result of the Rayleigh scattering in the material with small length scales, previously observed with TEMPO-oxidized liquid crystalline CNF-aerogels dried by using CPD34 and silica-based aerogels.[46]
Highresolution helium ion microscopy (HIM)-imaging of TEMPO-oxidized cellulose nanofibrils (TCNFs) was compromised by the dose-related damage as not described before with ion beams
Summary
Cellulose nano brils (CNFs) have been under intensive investigation due to their unique properties, such as high tensile strength, large speci c surface area, rheology and tendency for lm formation.[1]. BUniversity of Jyvaskyla, Nanoscience Centre, Department of Physics and Department of Biological and Environmental Science, FI-40014 Jyvaskyla, Finland cAbo Akademi University, Johan Gadolin Process Chemistry Centre, Porthansgatan 3, FI-20500 Abo/Turku, Finland dimensions in the mm to nm scale.[9,10,11,12,13] Transmission electron microscopy (TEM) is the most powerful imaging technique and can be utilized for detailed nanoscale evaluation of single bril dimensions of CNFs.[9,14,15,16,17] SEM usually requires a conductive coating before imaging and the TEM method is limited to thin samples like single brils, and because of that, the new imaging method scanning helium ion microscopy (HIM) has aroused interest during recent years
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