posted on 2024-10-01, 14:08authored byAnne Sehnal, Sean P. Ogilvie, Keiran Clifford, Hannah J. Wood, Aline Amorim Graf, Frank Lee, Manoj Tripathi, Peter J. Lynch, Matthew J. Large, Shayan Seyedin, Kathleen Maleski, Yury Gogotsi, Alan B. Dalton
Solution-processed nanomaterials can be assembled by
a range of
interfacial techniques, including as stabilizers in Pickering emulsions.
Two-dimensional (2D) materials present a promising route toward nanosheet-stabilized
emulsions for functional segregated networks, while also facilitating
surface energy studies. Here, we demonstrate emulsions stabilized
by the 2D materials including the transition metal carbide MXene,
titanium carbide (Ti3C2Tx), and develop an approach for in situ measurement
of nanosheet surface energy based on emulsion inversion. This approach
is applied to determine the influence of pH and nanosheet size on
surface energy for MXene, graphene oxide, pristine graphene, and molybdenum
disulfide. The surface energy values of hydrophilic Ti3C2Tx and graphene oxide decrease
significantly upon protonation of usually dissociated functional groups,
facilitating emulsion stabilization. Similarly, pristine graphene
and molybdenum disulfide increase in surface energy when their surface
functional groups are deprotonated under basic conditions. In addition,
the surface energies of these pristine materials are correlated with
nanosheet size, which allows for the calculation of the basal plane
and edge surface energies of pristine nanosheets. This understanding
of surface energies and control of emulsion inversion will allow design
of emulsion-templated structures and surface energy studies of a wide
range of solution-processable nanomaterials.