Crystal Lattice Analysis for 2D Nanomorphology Prediction of Phase-Separated Materials

Tobias Schnitzer; Bart W.L. van den Bersselaar; Brigitte A.G. Lamers; Martin H.C. van Son; Stefan J.D. Maessen; Freek V. de Graaf; Bas F.M. de Waal; Nils Trapp; Ghislaine Vantomme; E.W. Meijer

doi:10.1021/jacs.4c14964

Crystal Lattice Analysis for 2D Nanomorphology Prediction of Phase-Separated Materials

Tobias Schnitzer, Bart W.L. van den Bersselaar, Brigitte A.G. Lamers, Martin H.C. van Son, Stefan J.D. Maessen, Freek V. de Graaf, Bas F.M. de Waal, Nils Trapp, Ghislaine Vantomme, E.W. Meijer (Corresponding author)

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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Spontaneous phase separation of materials is a powerful strategy to generate highly defined 2D nanomorphologies with novel properties and functions. Exemplary are such morphologies in block copolymers or amphiphilic systems, whose formation can be well predicted based on parameters such as volume fraction and shape factor. In contrast, the formation of 2D nanomorphologies is currently unpredictable in materials perfectly defined at the molecular level, in which crystallinity plays a significant role. Here, we introduce a crystal lattice analysis to predict a priori the formation of 2D nanomorphologies from the crystalline units in phase-separated soft materials. We show that the formation of lamellar morphologies, their domain spacings, and thermal transition temperatures of such materials can be predicted using a straightforward crystal lattice analysis workflow. We envision this approach to facilitate the design and discovery of new materials with 2D nanomorphologies that are essential for next-generation electronic applications.

Originele taal-2	Engels
Pagina's (van-tot)	1991-1999
Aantal pagina's	9
Tijdschrift	Journal of the American Chemical Society
Volume	147
Nummer van het tijdschrift	2
Vroegere onlinedatum	5 jan. 2025
DOI's	https://doi.org/10.1021/jacs.4c14964
Status	Gepubliceerd - 15 jan. 2025

Bibliografische nota

Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society.

Financiering

This work was supported by the European Research Council (SYNMAT project ID 788618) and the Dutch Ministry of Education, Culture and Science (Gravity program 024.001.035). T.S. thanks the Swiss National Science Foundation for a Postdoc Mobility fellowship.

Financiers	Financiernummer
Ministerie van Onderwijs, Cultuur en Wetenschap	024.001.035

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Schnitzer, T., van den Bersselaar, B. W. L., Lamers, B. A. G., van Son, M. H. C., Maessen, S. J. D., de Graaf, F. V., de Waal, B. F. M., Trapp, N., Vantomme, G., & Meijer, E. W. (2025). Crystal Lattice Analysis for 2D Nanomorphology Prediction of Phase-Separated Materials. Journal of the American Chemical Society, 147(2), 1991-1999. https://doi.org/10.1021/jacs.4c14964

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abstract = "Spontaneous phase separation of materials is a powerful strategy to generate highly defined 2D nanomorphologies with novel properties and functions. Exemplary are such morphologies in block copolymers or amphiphilic systems, whose formation can be well predicted based on parameters such as volume fraction and shape factor. In contrast, the formation of 2D nanomorphologies is currently unpredictable in materials perfectly defined at the molecular level, in which crystallinity plays a significant role. Here, we introduce a crystal lattice analysis to predict a priori the formation of 2D nanomorphologies from the crystalline units in phase-separated soft materials. We show that the formation of lamellar morphologies, their domain spacings, and thermal transition temperatures of such materials can be predicted using a straightforward crystal lattice analysis workflow. We envision this approach to facilitate the design and discovery of new materials with 2D nanomorphologies that are essential for next-generation electronic applications.",

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AU - van Son, Martin H.C.

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AU - de Graaf, Freek V.

AU - de Waal, Bas F.M.

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AB - Spontaneous phase separation of materials is a powerful strategy to generate highly defined 2D nanomorphologies with novel properties and functions. Exemplary are such morphologies in block copolymers or amphiphilic systems, whose formation can be well predicted based on parameters such as volume fraction and shape factor. In contrast, the formation of 2D nanomorphologies is currently unpredictable in materials perfectly defined at the molecular level, in which crystallinity plays a significant role. Here, we introduce a crystal lattice analysis to predict a priori the formation of 2D nanomorphologies from the crystalline units in phase-separated soft materials. We show that the formation of lamellar morphologies, their domain spacings, and thermal transition temperatures of such materials can be predicted using a straightforward crystal lattice analysis workflow. We envision this approach to facilitate the design and discovery of new materials with 2D nanomorphologies that are essential for next-generation electronic applications.

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Crystal Lattice Analysis for 2D Nanomorphology Prediction of Phase-Separated Materials

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