Abstract
Simultaneous rheological, polarized light imaging, and small-angle X-ray scattering experiments (Rheo-PLI-SAXS) are developed, thereby providing unprecedented level of insight into the multiscale orientation of hierarchical systems in simple shear. Notably, it is observed that mesoscale alignment in the flow direction does not develop simultaneously across nano-micro lengthscales in sheared suspensions of rod-like chiral-nematic (meso) phase forming cellulose nanocrystals. Rather, with increasing shear rate, orientation is observed first at mesoscale and then extends to the nanoscale, with influencing factors being the aggregation state of the hierarchy and concentration. In biphasic systems, where an isotropic phase co-exists with self-assembled liquid crystalline mesophase domains, the onset of mesodomain alignment towards the flow direction can occur at shear rates nearing one decade before a progressive increase in preferential orientation at nanoscale is detected. If physical confinement prevents the full formation of a cholesteric phase, mesoscale orientation occurs in shear rate ranges that correspond to de-structuring at nanoscale. Interestingly, nano- and mesoscale orientations appear to converge only for biphasic suspensions with primary nanoparticles predominantly made up of individual crystallites and in a high-aspect ratio nematic-forming thin-wall nanotube system. The nano-micro orientation propagation is attributed to differences in the elongation and breakage of mesophase domains.
| Original language | English |
|---|---|
| Article number | 2410920 |
| Journal | Advanced Science |
| Volume | 12 |
| Issue number | 7 |
| DOIs | |
| Publication status | Published - Feb 2025 |
| MoE publication type | A1 Journal article-refereed |
Funding
The work was supported by Chalmers Foundation through the project Chalmers Center for Advanced Neutron and X\u2010ray scattering techniques in cooperation with MAX IV. The authors acknowledge MAX IV Laboratory for time on the CoSAXS beamline under proposals 20200458, 2022143, and 20230947 and on the ForMAX beamline under proposal 20230038. Research conducted at MAX IV, a Swedish national user facility, was supported by the Swedish Research council under contract 2018\u201007152, the Swedish Governmental Agency for Innovation Systems under contract 2018\u201004969, and Formas under contract 2019\u201002496. S.W., K.S., and R.K. are grateful for the financial support of the Wallenberg Wood Science Center (5.2.2 and III\u201312), and M.B. and R.K. to the FibRe Vinnova Competence Centre. T.N. and R.K. gratefully acknowledge the financial support of the Chalmers Area of Advance Materials Science through the All\u2010Wood Composite Platform. R.K. and V.G. are grateful for the financial support of the \u201C2D material\u2010based technology for industrial applications\u201D 2D\u2010TECH Vinnova Competence Centre (Ref. 2019\u201000068). Since the timescale for compiling, analyzing and understanding the data exceeds the timescale of individual research grants, the last author wishes to further acknowledge the several generations of group members that have contributed to the work by developing samples, performing experiments and helping with the data analysis without the chance to see the full picture: starting with R.G., S.W., and A.K.S., and finally with MB, KS and VG. The authors are additionally grateful to Alexandra Aulova, Ases A. Mishra, Sajjad Pashazadeh, Ehsan Hadi and Arvindh S. Suresh for supporting the SAXS experiments and to the technical support of Jackson da Silva and Vahid Haghighat. S.B. thanks the University of Glasgow for funding.
Keywords
- advanced rheological techniques
- cellulose nanocrystals
- liquid crystalline suspensions
- multiscale orientation
- polarized light imaging
- small-angle X-ray scattering