3 research outputs found
Electrically Conductive, Tough Hydrogels with pH Sensitivity
Electrically conductive, mechanically tough hydrogels
based on a double network (DN) comprised of poly(ethylene glycol)
methyl ether methacrylate (PPEGMA) and poly(acrylic acid) (PAA) were
produced. Poly(3,4-ethylenedioxythiophene) (PEDOT) was chemically
polymerized within the tough DN gel to provide electronic conductivity.
The effects of pH on the tensile and compressive mechanical properties
of the fully swollen hydrogels, along with their electrical conductivity
and swelling ratio were determined. Compressive and tensile strengths
as high as 11.6 and 0.6 MPa, respectively, were obtained for hydrogels
containing PEDOT with a maximum conductivity of 4.3 S cm<sup>–1</sup>. This conductivity is the highest yet reported for hydrogel materials
of high swelling ratios. These hydrogels may be useful as soft strain
sensors because their electrical resistance changed significantly
when cyclically loaded in compression
Liquid Crystalline Behavior of Graphene Oxide in the Formation and Deformation of Tough Nanocomposite Hydrogels
In this paper, we report the formation
and transformation of graphene
oxide (GO) liquid crystalline (LC) structures in the synthesis and
deformation of tough GO nanocomposite hydrogels. GO aqueous dispersions
form a nematic LC phase, while the addition of poly(<i>N</i>-vinylpyrrolidone) (PVP) and acrylamide (AAm), which are capable
of forming hydrogen bonding with GO nanosheets, shifts the isotropic/nematic
transition to a lower volume fraction of GO and enhances the formation
of nematic droplets. During the gelation process, a phase separation
of the polymers and GO nanosheets is accompanied by the directional
assembly of GO nanosheets, forming large LC tactoids with a radial
GO configuration. The shape of the large tactoids evolves from a sphere
to a toroid as the tactoids increase in size. Interestingly, during
cyclic uniaxial tensile deformation a reversible LC transition is
observed in the very tough hydrogels. The isolated birefringent domains
and the LC domains in the tactoids in the gels are highly oriented
under a high tensile strain
Facile Fabrication of Tough Hydrogels Physically Cross-Linked by Strong Cooperative Hydrogen Bonding
Novel hydrogels with excellent mechanical
properties have prompted
applications in biomedical and other fields. The reported tough hydrogels
are usually fabricated by complicated chemical and/or physical methods.
To develop more facile fabrication methods is very important for the
practical applications of tough hydrogels. We report a very simple
yet novel method for fabricating tough hydrogels that are totally
physically cross-linked by cooperative hydrogen bonding between a
pre-existing polymer and an <i>in situ</i> polymerized polymer.
In this work, tough hydrogels are prepared by heating aqueous acrylamide
(AAm) solution in the presence of poly(<i>N</i>-vinylpyrrolidone)
(PVP) but without any chemical initiators or covalent bonding cross-linking
agents. Mechanical tests of the as-prepared and swollen PVP-<i>in situ</i>-PAAm hydrogels show that they exhibit very high
tensile strengths, high tensile extensibility, high compressive strengths,
and low moduli. Comparative synthesis experiments, DSC characterization,
and molecular modeling indicate that the formation of strong cooperative
hydrogen bonding between the pre-existing PVP and the <i>in situ</i> formed PAAm chains contributes to the gel formation and the toughening
of the hydrogels. The unique microstructure of the gels with evenly
distributed flexible cross-linking sites and long polymer chains attached
to them endow the hydrogels with an excellent mechanism of distributing
the applied load