Hierarchically ordered porous transition metal compounds from one-pot type 3D printing approaches

Fei Yu; R. Paxton Thedford; Thomas A. Tartaglia; Sejal S. Sheth; Guillaume Freychet; William R. T. Tait; Peter A. Beaucage; William L. Moore; Yuanzhi Li; Jörg G. Werner; Julia Thom-Levy; Sol M. Gruner; R. Bruce van Dover; Ulrich B. Wiesner

doi:10.1038/s41467-025-62794-8

Nature Communications (Aug 2025)

Hierarchically ordered porous transition metal compounds from one-pot type 3D printing approaches

Fei Yu,
R. Paxton Thedford,
Thomas A. Tartaglia,
Sejal S. Sheth,
Guillaume Freychet,
William R. T. Tait,
Peter A. Beaucage,
William L. Moore,
Yuanzhi Li,
Jörg G. Werner,
Julia Thom-Levy,
Sol M. Gruner,
R. Bruce van Dover,
Ulrich B. Wiesner

Affiliations

Fei Yu: Department of Materials Science and Engineering, Cornell University
R. Paxton Thedford: Department of Materials Science and Engineering, Cornell University
Thomas A. Tartaglia: Department of Materials Science and Engineering, Cornell University
Sejal S. Sheth: Department of Materials Science and Engineering, Cornell University
Guillaume Freychet: National Synchrotron Light Source-II, Brookhaven National Laboratory
William R. T. Tait: Department of Materials Science and Engineering, Cornell University
Peter A. Beaucage: NIST Center for Neutron Research, National Institute of Standards and Technology
William L. Moore: Department of Materials Science and Engineering, Cornell University
Yuanzhi Li: Department of Mechanical Engineering, Boston University
Jörg G. Werner: Department of Mechanical Engineering, Boston University
Julia Thom-Levy: Department of Physics, Cornell University
Sol M. Gruner: Department of Physics, Cornell University
R. Bruce van Dover: Department of Materials Science and Engineering, Cornell University
Ulrich B. Wiesner: Department of Materials Science and Engineering, Cornell University

DOI: https://doi.org/10.1038/s41467-025-62794-8
Journal volume & issue: Vol. 16, no. 1
pp. 1 – 12

Abstract

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Abstract Solution-based soft matter self-assembly (SA) promises unique material structures and properties from approaches including additive manufacturing/three-dimensional (3D) printing. The 3D printing of periodically ordered porous functional inorganic materials through SA unfolding during printing remains a major challenge, however, due to the often vastly different ordering kinetics of separate processes at different length scales. Here, we report a “one-pot” direct ink writing process to produce hierarchically porous transition metal nitrides and precursor oxides from block copolymer (BCP) SA. Heat treatment protocols identified in various environments enable mesostructure retention in the final crystalline materials with periodic lattices on three distinct length scales. Moreover, embedded printing enables the first BCP directed mesoporous non-self-supporting helical oxides and nitrides. Resulting nitrides are superconducting, with record nanoconfinement-induced upper critical fields correlated with BCP molar mass and record surface areas for compound superconductors. Results suggest scalable porous functional inorganic material formation approaches for applications including catalysis, sensing, and microelectronics.

Published in Nature Communications

ISSN: 2041-1723 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science
Website: https://www.nature.com/ncomms/

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