Issue 3, 2022

Progressive changes in crystallographic textures of biominerals generate functionally graded ceramics

Abstract

Biomineralizing organisms are widely praised for their ability to generate structural materials with exceptional crystallographic control. While earlier studies highlighted near-to single-crystalline biominerals, complex polycrystalline features are more widespread yet challenging to account for. Here, we propose that biominerals whose crystal texture varies with depth are functionally graded materials. Using the exemplary case of the nacro-prismatic pearl oyster Pinctada margaritifera, we demonstrate systematic textural changes in a biogenic ceramic. This bivalve employs three synergistic mechanisms to generate a texture gradient across its outer calcitic shell layer. This prismatic layer transitions from an initially weakly-textured to a strongly-textured material. Such changes in texture cause a variation in Young's modulus normal to the shell, owing to the anisotropic mechanical properties of the composing crystallites. Based on finite-element simulations and indentation experiments on the bivalve shell, we conclude that such graded bioceramics yield intrinsic toughening properties similar to those found in compositionally-graded synthetic materials. Notwithstanding, the gradation concept of Pinctada margaritifera is unparalleled among synthetic materials as it rests solely upon elastic anisotropy, making oyster shells potential blueprints for future bioinspired functional materials and damage-resistant ceramics.

Graphical abstract: Progressive changes in crystallographic textures of biominerals generate functionally graded ceramics

Associated articles

Supplementary files

Article information

Article type
Paper
Submitted
04 Nov 2021
Accepted
21 Dec 2021
First published
21 Dec 2021
This article is Open Access
Creative Commons BY-NC license

Mater. Adv., 2022,3, 1527-1538

Progressive changes in crystallographic textures of biominerals generate functionally graded ceramics

D. Wallis, J. Harris, C. F. Böhm, D. Wang, P. Zavattieri, P. Feldner, B. Merle, V. Pipich, K. Hurle, S. Leupold, L. N. Hansen, F. Marin and S. E. Wolf, Mater. Adv., 2022, 3, 1527 DOI: 10.1039/D1MA01031J

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