Smart membranes that
can open and/or close their pores in a controlled
manner by external stimuli possess potential in various applications,
such as water flow manipulation, indoor climate regulation, and sensing.
The design of smart gating membranes with high flux, immediate response,
and mechanical robustness is still an open challenge, limiting their
versatility and practical applicability. Inspired by the controlled
opening and closure of plant stomata, we have developed a smart gating
wood membrane, taking advantage of the unique wood scaffold with its
hierarchical porous structure to carry thermoresponsive hydrogel gates.
Laser drilling was applied to cut channels in the wood scaffold with
well-aligned pores to incorporate the smart gating membranes. In situ
polymerization of poly(N-isopropylacrylamide) above its lower critical
solution temperature inside the channels resulted in a hydrogel with
a heterogeneous microstructure acting as a thermoresponsive gate.
The wood-based smart gating membranes exhibited reversible and stable
pore opening/closing under heating/cooling stimuli. The achieved rapid
response and feasibility of scale-up open the venue for various practical
applications. In this work, we demonstrated their potential for indoor
light regulation and as a water flow manipulator.