posted on 2020-01-03, 15:34authored bySubhankar Mandal, Anant Seth, Vikas Yadav, Srishti Kumari, Milan Kumar, Umaprasana Ojha
Hydrogels
possessing stretchability, toughness, and conductivity
together are promising candidates for soft electronics applications.
In this report, ionic grafting of poly(acryloyl hydrazide) (PAHz)–silver
(Ag) nanocomposites (NC) is used to improve the mechanical properties
and conductivity of poly(acrylamidopropanesulfonic acid)
(PAMPS) hydrogels. PAHz–Ag NCs possessing different sizes of
Ag NPs (3–40 nm) are grafted in the PAMPS hydrogel matrix via
−CONHNH3+---–O3S ionic linkage. The resulting PAHz–Ag NC grafted hydrogels
at ∼62 wt % water content exhibited ultimate tensile strength
(UTS) and fracture energy up to ∼1.14 MPa and ∼1600
J/m2, respectively. The UTS of hydrogels was dependent
on the size of Ag NP in PAHz–Ag NCs, and the value increased
from 0.70 to 1.14 MPa with the decrease in Ag NP size from ∼40
to 5 nm. The hydrogel samples exhibited adequate skin adhesiveness
(tack adhesive strength ≈10.8 kPa), conductivity (50.5 mS/cm),
and strain sensing ability (gauge factor ≈0.9), suggesting
these samples are potentially useful for various soft electronics
applications. As a proof of concept, the hydrogels were employed as
soft electrode in an electrocardiogram (ECG) device, and the efficiency
was monitored under real-time conditions. The data exhibited noise-free
reproducible patterns of ECG with defined P, Q, R, S, and T peaks
under different locomotion of the body, suggesting the viability of
developed hydrogels for the ECG sensing applications.