posted on 2021-07-16, 11:33authored byGegu Chen, Tian Li, Chaoji Chen, Weiqing Kong, Miaolun Jiao, Bo Jiang, Qinqin Xia, Zhiqiang Liang, Yang Liu, Shuaiming He, Liangbing Hu
Many efforts have been dedicated
to exploring nanofluidic systems
for various applications including water purification and energy generation.
However, creating robust nanofluidic materials with tunable channel
orientations and numerous nanochannels or nanopores on a large scale
remains challenging. Here, we demonstrate a scalable and cost-effective
method to fabricate a robust and highly conductive nanofluidic wood
hydrogel membrane in which ions can transport across the membrane.
The ionically conductive balsa wood hydrogel membrane is fabricated
by infiltrating poly(vinyl alcohol) (PVA)/acrylic acid (AA) hydrogel
into the inherent bimodal porous wood structure. The balsa wood hydrogel
membrane demonstrates a 3 times higher strength (52.7 MPa) and 2 orders
of magnitude higher ionic conductivity compared to those of natural
balsa both in the radial direction (coded as R direction) and along
the longitudinal direction (coded as L direction). The ionic conductivity
of the balsa wood hydrogel membrane is 1.29 mS cm–1 along the L direction and nearly 1 mS cm–1 along
the R direction at low salt concentrations (up to 10 mM). In addition,
the surface-charge-governed ion transport also renders the balsa wood
hydrogel membrane able to harvest electrical energy from salinity
gradients. A current density of up to 17.65 μA m–2 and an output power density of 0.56 mW m–2 are
obtained under a 1000-fold salt concentration gradient, which can
be further improved to 2.7 mW m–2 by increasing
the AA content from 25 wt % to 50 wt %. These findings make contributions
to develop energy-harvesting systems and other nanofluidic devices
from sustainable wood materials.