Solution-processable polytriazoles from spirocyclic monomers for membrane-based hydrocarbon separations

Nicholas C. Bruno; Ronita Mathias; Young Joo Lee; Guanghui Zhu; Yun Ho Ahn; Neel D. Rangnekar; J. R. Johnson; Scott Hoy; Irene Bechis; Andrew Tarzia; Kim E. Jelfs; Benjamin A. McCool; Ryan Lively; M. G. Finn

doi:10.1038/s41563-023-01682-2

Solution-processable polytriazoles from spirocyclic monomers for membrane-based hydrocarbon separations

Nicholas C. Bruno
, Ronita Mathias
, Young Joo Lee
, Guanghui Zhu
, Yun Ho Ahn
, Neel D. Rangnekar
, J. R. Johnson
, Scott Hoy
, Irene Bechis
, Andrew Tarzia
, Kim E. Jelfs
, Benjamin A. McCool
, Ryan Lively^*
, M. G. Finn^*

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

The thermal distillation of crude oil mixtures is an energy-intensive process, accounting for nearly 1% of global energy consumption. Membrane-based separations are an appealing alternative or tandem process to distillation due to intrinsic energy efficiency advantages. We developed a family of spirocyclic polytriazoles from structurally diverse monomers for membrane applications. The resulting polymers were prepared by a convenient step-growth method using copper-catalysed azide–alkyne cycloaddition, providing very fast reaction rates, high molecular weights and solubilities in common organic solvents and non-interconnected microporosity. Fractionation of whole Arabian light crude oil and atmospheric tower bottom feeds using these materials enriched the low-boiling-point components and removed trace heteroatom and metal impurities (comparable performance with the lighter feed as the commercial polyimide, Matrimid), demonstrating opportunities to reduce the energy cost of crude oil distillation with tandem membrane processes. Membrane-based molecular separation under these demanding conditions is made possible by high thermal stability and a moderate level of dynamic chain mobility, leading to transient interconnections between micropores, as revealed by the calculations of static and swollen pore structures.

Original language	English
Pages (from-to)	1540-1547
Number of pages	8
Journal	Nature Materials
Volume	22
Issue number	12
Early online date	16 Oct 2023
DOIs	https://doi.org/10.1038/s41563-023-01682-2
Publication status	Published - Dec 2023

Bibliographical note

ASJC Scopus subject areas

General Chemistry
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

Bruno, N. C., Mathias, R., Lee, Y. J., Zhu, G., Ahn, Y. H., Rangnekar, N. D., Johnson, J. R., Hoy, S., Bechis, I., Tarzia, A., Jelfs, K. E., McCool, B. A., Lively, R., & Finn, M. G. (2023). Solution-processable polytriazoles from spirocyclic monomers for membrane-based hydrocarbon separations. Nature Materials, 22(12), 1540-1547. https://doi.org/10.1038/s41563-023-01682-2

@article{b46660c7bbbf4179b689414f7e18c090,

title = "Solution-processable polytriazoles from spirocyclic monomers for membrane-based hydrocarbon separations",

abstract = "The thermal distillation of crude oil mixtures is an energy-intensive process, accounting for nearly 1\% of global energy consumption. Membrane-based separations are an appealing alternative or tandem process to distillation due to intrinsic energy efficiency advantages. We developed a family of spirocyclic polytriazoles from structurally diverse monomers for membrane applications. The resulting polymers were prepared by a convenient step-growth method using copper-catalysed azide–alkyne cycloaddition, providing very fast reaction rates, high molecular weights and solubilities in common organic solvents and non-interconnected microporosity. Fractionation of whole Arabian light crude oil and atmospheric tower bottom feeds using these materials enriched the low-boiling-point components and removed trace heteroatom and metal impurities (comparable performance with the lighter feed as the commercial polyimide, Matrimid), demonstrating opportunities to reduce the energy cost of crude oil distillation with tandem membrane processes. Membrane-based molecular separation under these demanding conditions is made possible by high thermal stability and a moderate level of dynamic chain mobility, leading to transient interconnections between micropores, as revealed by the calculations of static and swollen pore structures.",

author = "Bruno, \{Nicholas C.\} and Ronita Mathias and Lee, \{Young Joo\} and Guanghui Zhu and Ahn, \{Yun Ho\} and Rangnekar, \{Neel D.\} and Johnson, \{J. R.\} and Scott Hoy and Irene Bechis and Andrew Tarzia and Jelfs, \{Kim E.\} and McCool, \{Benjamin A.\} and Ryan Lively and Finn, \{M. G.\}",

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doi = "10.1038/s41563-023-01682-2",

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AU - Bruno, Nicholas C.

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AU - Ahn, Yun Ho

AU - Rangnekar, Neel D.

AU - Johnson, J. R.

AU - Hoy, Scott

AU - Bechis, Irene

AU - Tarzia, Andrew

AU - Jelfs, Kim E.

AU - McCool, Benjamin A.

AU - Lively, Ryan

AU - Finn, M. G.

PY - 2023/12

Y1 - 2023/12

N2 - The thermal distillation of crude oil mixtures is an energy-intensive process, accounting for nearly 1% of global energy consumption. Membrane-based separations are an appealing alternative or tandem process to distillation due to intrinsic energy efficiency advantages. We developed a family of spirocyclic polytriazoles from structurally diverse monomers for membrane applications. The resulting polymers were prepared by a convenient step-growth method using copper-catalysed azide–alkyne cycloaddition, providing very fast reaction rates, high molecular weights and solubilities in common organic solvents and non-interconnected microporosity. Fractionation of whole Arabian light crude oil and atmospheric tower bottom feeds using these materials enriched the low-boiling-point components and removed trace heteroatom and metal impurities (comparable performance with the lighter feed as the commercial polyimide, Matrimid), demonstrating opportunities to reduce the energy cost of crude oil distillation with tandem membrane processes. Membrane-based molecular separation under these demanding conditions is made possible by high thermal stability and a moderate level of dynamic chain mobility, leading to transient interconnections between micropores, as revealed by the calculations of static and swollen pore structures.

AB - The thermal distillation of crude oil mixtures is an energy-intensive process, accounting for nearly 1% of global energy consumption. Membrane-based separations are an appealing alternative or tandem process to distillation due to intrinsic energy efficiency advantages. We developed a family of spirocyclic polytriazoles from structurally diverse monomers for membrane applications. The resulting polymers were prepared by a convenient step-growth method using copper-catalysed azide–alkyne cycloaddition, providing very fast reaction rates, high molecular weights and solubilities in common organic solvents and non-interconnected microporosity. Fractionation of whole Arabian light crude oil and atmospheric tower bottom feeds using these materials enriched the low-boiling-point components and removed trace heteroatom and metal impurities (comparable performance with the lighter feed as the commercial polyimide, Matrimid), demonstrating opportunities to reduce the energy cost of crude oil distillation with tandem membrane processes. Membrane-based molecular separation under these demanding conditions is made possible by high thermal stability and a moderate level of dynamic chain mobility, leading to transient interconnections between micropores, as revealed by the calculations of static and swollen pore structures.

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Solution-processable polytriazoles from spirocyclic monomers for membrane-based hydrocarbon separations

Abstract

Bibliographical note

ASJC Scopus subject areas

UN SDGs

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