Acidic macromolecules are traditionally considered key to calcium carbonate biomineralisation and have long been first choice in the bio-inspired synthesis of crystalline materials. Here, we challenge this view and demonstrate that low-charge macromolecules can vastly outperform their acidic counterparts in the synthesis of nanocomposites. Using gold nanoparticles functionalised with low charge, hydroxyl-rich proteins and homopolymers as growth additives, we show that extremely high concentrations of nanoparticles can be incorporated within calcite single crystals, while maintaining the continuity of the lattice and the original rhombohedral morphologies of the crystals. The nanoparticles are perfectly dispersed within the host crystal and at high concentrations are so closely apposed that they exhibit plasmon coupling and induce an unexpected contraction of the crystal lattice. The versatility of this strategy is then demonstrated by extension to alternative host crystals. This simple and scalable occlusion approach opens the door to a novel class of single crystal nanocomposites.
Atomistic simulations provide insight into an example of the superiority of biogenic crystals, where Mg-rich nanoprecipitates in calcite inhibit crack propagation.
The classical model of crystal growth assumes that kinks
grow via
a sequence of independent adsorption events where each solute transitions
from the solution directly to the crystal lattice site. Here, we challenge
this view by showing that some calcite kinks grow via a multistep
mechanism where the solute adsorbs to an intermediate site and only
transitions to the lattice site upon the adsorption of a second solute.
We compute the free energy curves for Ca and CO
3
ions adsorbing
to a large selection of kink types, and we identify kinks terminated
both by Ca ions and by CO
3
ions that grow in this multistep
way.
Calcite crystals grow by means of molecular steps that develop on {10.4} faces. These steps can arise stochastically via two-dimensional (2D) nucleation or emerge steadily from dislocations to form spiral hillocks. Here, we determine the kinetics of these two growth mechanisms as a function of supersaturation. We show that calcite crystals larger than ∼1 μm favor spiral growth over 2D nucleation, irrespective of the supersaturation. Spirals prevail beyond this length scale because slow boundary layer diffusion creates a low surface supersaturation that favors the spiral mechanism. Submicron crystals favor 2D nucleation at high supersaturations, although diffusion can still limit the growth of nanoscopic crystals. Additives can change the dominant mechanism by impeding spiral growth or by directly promoting 2D nucleation.
Incorporation of
guest additives within inorganic single crystals
offers a unique strategy for creating nanocomposites with tailored
properties. While anionic additives have been widely used to control
the properties of crystals, their effective incorporation remains
a key challenge. Here, we show that cationic additives are an excellent
alternative for the synthesis of nanocomposites, where they are shown
to deliver exceptional levels of incorporation of up to 70 wt % of
positively charged amino acids, polymer particles, gold nanoparticles,
and silver nanoclusters within inorganic single crystals. This high
additive loading endows the nanocomposites with new functional properties,
including plasmon coupling, bright fluorescence, and surface-enhanced
Raman scattering (SERS). Cationic additives are also shown to outperform
their acidic counterparts, where they are highly active in a wider
range of crystal systems, owing to their outstanding colloidal stability
in the crystallization media and strong affinity for the crystal surfaces.
This work demonstrates that although often overlooked, cationic additives
can make valuable crystallization additives to create composite materials
with tailored composition–structure–property relationships.
This versatile and straightforward approach advances the field of
single-crystal composites and provides exciting prospects for the
design and fabrication of new hybrid materials with tunable functional
properties.
Soluble additives are widely used to control crystallization processes, modifying the morphologies, sizes, polymorphs, and physical properties of the product crystals. Here, a simple and versatile strategy is shown to significantly enhance the potency of soluble additives, ranging from ions and amino acids to large dye molecules, enabling them to be effective even at low concentrations. Addition of small amounts of miscible organic cosolvents to an aqueous crystallization solution can yield enhanced morphological changes and an order of magnitude increase of additive incorporation within single crystalsa level that cannot be achieved in pure aqueous solutions at any additive concentration. The generality of this strategy is demonstrated by application to crystals of calcium carbonate, manganese carbonate, and strontium sulfate, with a more pronounced effect observed for co-solvents with lower dielectric constants and polarities, indicating a general underlying mechanism that alters water activity. This work increases the understanding of additive/crystal interactions and may see great application in industrial-scale crystal synthesis.
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