Crystal Growth

Crystal Growth

Using only simple salts from the soil or water and only themselves as factories, living organisms from bacteria to sea sponges to mammals construct an endless variety of mineral architectures exquisitely patterned in 3D across the macro-, meso-, and nanoscales. Our studies have shown that inorganic crystallization is finely tuned at the molecular level by organized assemblies of proteins and cells, but the details of how this is achieved are still largely a mystery. 

To uncover underlying principles we can adapt to create new designs, our group has pioneered the growth of crystals on surface-bound organic monolayers and discovered an unexpectedly rich, multilingual “conversation” that takes place between the organic layer and the growing crystal.

By deciphering the complex interplay of chemical, mechanical, and geometric information within the system, we have learned how subtle template adjustments can be used to control nearly every feature of crystallization, to generate asymmetry from symmetric components, and even to stabilize amorphous states and guide their transitions to patterned single crystalas.

Yet even these advances remain humble next to the elaborate inorganic materials small creatures build from scratch, and we are exploring template nanotopography, amorphous-polycrystalline composites, mechanical stress, patterning and other features of the organic-inorganic interface that may take part in the generation of multiscale 3D complexity.

Publications

2024

Mader AV, Williams RM, Aizenberg J, Noorduin WL. Directing Sequential Self-Organization with Self-Assembled Nanocrystals. Crystal Growth & Design. 2024.
Mader AV, Williams RM, Aizenberg J, Noorduin WL. Directing Sequential Self-Organization with Self-Assembled Nanocrystals. Crystal Growth & Design. 2024.

2022

Schroeder TBH, Aizenberg J. Patterned crystal growth and heat wave generation in hydrogels. Nature Communications. 2022;13(1):1–11. doi:10.1038/s41467-021-27505-z
Schroeder TBH, Aizenberg J. Patterned crystal growth and heat wave generation in hydrogels. Nature Communications. 2022;13(1):1–11. doi:10.1038/s41467-021-27505-z

2017

Kaplan C, Noorduin W, Li L, Sadza R, Folkertsma L, Aizenberg J, Mahadevan L. Controlled growth and form of precipitating microstructures. Science. 2017;355(6332):1395–1399.
Kaplan C, Noorduin W, Li L, Sadza R, Folkertsma L, Aizenberg J, Mahadevan L. Controlled growth and form of precipitating microstructures. Science. 2017;355(6332):1395–1399.

2016

Grinthal A, Noorduin W, Aizenberg J. A Constructive Chemical Conversation. American Scientist. 2016;104(4):228–235.
Grinthal A, Noorduin W, Aizenberg J. A Constructive Chemical Conversation. American Scientist. 2016;104(4):228–235.

2013

Noorduin W, Grinthal A, Mahadevan L, Aizenberg J. Rationally Designed Complex Hierarchical Microarchitectures. Science. 2013;340:832–837. doi:10.1126/science.1234621
Noorduin W, Grinthal A, Mahadevan L, Aizenberg J. Rationally Designed Complex Hierarchical Microarchitectures. Science. 2013;340:832–837. doi:10.1126/science.1234621

2011

Vasquez Y, Fenton EM, Chernow VF, Aizenberg J. Growth of polygonal rings and wires of CuS on structured surfaces. Cryst. Eng. Comm. 2011;13:1077–1080. doi:10.1039/C0CE00499E
Vasquez Y, Fenton EM, Chernow VF, Aizenberg J. Growth of polygonal rings and wires of CuS on structured surfaces. Cryst. Eng. Comm. 2011;13:1077–1080. doi:10.1039/C0CE00499E

2010

Pokroy B, Aichmayer B, Schenk AS, Haimov B, Kang SH, Fratzl P, Aizenberg J. Sonication-assisted synthesis of large, high-quality mercury-thiolate single crystals directly from liquid mercury. J. Am. Chem. Soc,. 2010;132(41):14355–14357. doi:10.1021/ja1056449
Pokroy B, Aichmayer B, Schenk AS, Haimov B, Kang SH, Fratzl P, Aizenberg J. Sonication-assisted synthesis of large, high-quality mercury-thiolate single crystals directly from liquid mercury. J. Am. Chem. Soc,. 2010;132(41):14355–14357. doi:10.1021/ja1056449

2009

Killian CE, Metzler A, Gong Y, Olson IC, Aizenberg J, Politi Y, Wilt FH, Scholl A, Young A, Doran A, et al. Mechanism of Calcite Co-Orientation in the Sea Urchin Tooth. J. Am. Chem. Soc. 2009;131:18404–18409.
Killian CE, Metzler A, Gong Y, Olson IC, Aizenberg J, Politi Y, Wilt FH, Scholl A, Young A, Doran A, et al. Mechanism of Calcite Co-Orientation in the Sea Urchin Tooth. J. Am. Chem. Soc. 2009;131:18404–18409.

2008

Aizenberg J. Self-Assembled Monolayers as Templates for Inorganic Crystallization: A Bio-Inspired Approach. In: Novoa J, editor. Springer WB/Nato Publishing Unit: Dordrecht, Netherlands; 2008. pp. 17–32.
Aizenberg J. Self-Assembled Monolayers as Templates for Inorganic Crystallization: A Bio-Inspired Approach. In: Novoa J, editor. Springer WB/Nato Publishing Unit: Dordrecht, Netherlands; 2008. pp. 17–32.