Nacre,
an organic–inorganic composite biomaterial that forms
an ordered multilayer microstructure after years of slow biomineralization,
is known as the strongest and toughest material within the mollusc
family. Its unique structure provides inspiration for robust artificial
engineering materials. Lignocellulose is ultralightweight, abundant,
and possesses a high mechanical performance and has been used for
ages as a significant renewable raw material in wooden engineering
composites. However, the inherent lack of mechanical properties of
current wooden composites associated with the fragile microstructure
has limited their applications in advanced engineering materials.
Here, we develop a large-size ultralightweight artificial “wood
nacre” with an ordered layer structure through a fast and scalable
“mechanical/chemical mineralization and assembly” approach.
The millimeter-thick artificial wooden nacre mimics the stratified
construction of natural nacre, resulting in a bulk hybrid material
that can achieve almost the same strength as natural nacre while consisting
of only one-sixth of the total inorganic content of natural nacre.
The specific strength and toughness of the artificial wooden nacre
is even superior to engineering alloy materials (such as Cu and Fe).
This approach represents an efficient strategy for the mass production
of lightweight sustainable structural materials with high strength
and toughness.