A family of zeolites with controlled pore size prepared using a top-down method

Wieslaw J. Roth; Petr Nachtigall; Russell Edward Morris; Paul Stewart Wheatley; Valerie Ruth Seymour; Sharon Elizabeth  Ashbrook; Pavla Chlubna; Lukas Grajciar; Miroslav Polozij; Arnost Zukal; Oleksiy Shvets; Jiri Cejka

doi:10.1038/NCHEM.1662

A family of zeolites with controlled pore size prepared using a top-down method

Wieslaw J. Roth^*, Petr Nachtigall, Russell Edward Morris, Paul Stewart Wheatley, Valerie Ruth Seymour, Sharon Elizabeth Ashbrook, Pavla Chlubna, Lukas Grajciar, Miroslav Polozij, Arnost Zukal, Oleksiy Shvets, Jiri Cejka

^*Corresponding author for this work

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

Abstract

The properties of zeolites, and thus their suitability for different applications, are intimately connected with their structures. Synthesizing specific architectures is therefore important, but has remained challenging. Here we report a top-down strategy that involves the disassembly of a parent zeolite, UTL, and its reassembly into two zeolites with targeted topologies, IPC-2 and IPC-4. The three zeolites are closely related as they adopt the same layered structure, and they differ only in how the layers are connected. Choosing different linkers gives rise to different pore sizes, enabling the synthesis of materials with predetermined pore architectures. The structures of the resulting zeolites were characterized by interpreting the X-ray powder-diffraction patterns through models using computational methods; IPC-2 exhibits orthogonal 12- and ten-ring channels, and IPC-4 is a more complex zeolite that comprises orthogonal ten- and eight-ring channels. We describe how this method enables the preparation of functional materials and discuss its potential for targeting other new zeolites.

Original language	English
Pages (from-to)	628-633
Number of pages	6
Journal	Nature Chemistry
Volume	5
Issue number	7
DOIs	https://doi.org/10.1038/NCHEM.1662
Publication status	Published - Jul 2013

Keywords

Structure-directing agent
Interlayer expansion
Channels
Framework
Layer
Transformation
Precursors
Silicates
Cations
System

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10.1038/NCHEM.1662

Roth_ADOR_Final
Copyright 2013, the authors. This is the accepted version manuscript.
Accepted author manuscript, 205 KB

Assembly Disassembly Reassembly: Assembly disassembly reassembly - New routes to extended structures and their impact
Morris, R. E. (PI)
EPSRC
1/08/13 → 31/07/18
Project: Fellowship
Structuring the Future: Structuring the Future - Underpinning world-leading science in EaStCHEM through cutting edge characterisation
Woollins, J. D. (PI), Ashbrook, S. E. (CoI), Morris, R. E. (CoI) & Slawin, A. M. Z. (CoI)
EPSRC
1/01/13 → 31/03/13
Project: Standard
Upgrade Small Equipment Base: Small items of research equipment at the University of St Andrews. Supporting a new generation of physical sciences research
Woollins, J. D. (PI)
EPSRC
1/11/12 → 31/03/13
Project: Standard

Cite this

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title = "A family of zeolites with controlled pore size prepared using a top-down method",

abstract = "The properties of zeolites, and thus their suitability for different applications, are intimately connected with their structures. Synthesizing specific architectures is therefore important, but has remained challenging. Here we report a top-down strategy that involves the disassembly of a parent zeolite, UTL, and its reassembly into two zeolites with targeted topologies, IPC-2 and IPC-4. The three zeolites are closely related as they adopt the same layered structure, and they differ only in how the layers are connected. Choosing different linkers gives rise to different pore sizes, enabling the synthesis of materials with predetermined pore architectures. The structures of the resulting zeolites were characterized by interpreting the X-ray powder-diffraction patterns through models using computational methods; IPC-2 exhibits orthogonal 12- and ten-ring channels, and IPC-4 is a more complex zeolite that comprises orthogonal ten- and eight-ring channels. We describe how this method enables the preparation of functional materials and discuss its potential for targeting other new zeolites.",

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author = "Roth, {Wieslaw J.} and Petr Nachtigall and Morris, {Russell Edward} and Wheatley, {Paul Stewart} and Seymour, {Valerie Ruth} and Ashbrook, {Sharon Elizabeth} and Pavla Chlubna and Lukas Grajciar and Miroslav Polozij and Arnost Zukal and Oleksiy Shvets and Jiri Cejka",

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AU - Seymour, Valerie Ruth

AU - Ashbrook, Sharon Elizabeth

AU - Chlubna, Pavla

AU - Grajciar, Lukas

AU - Polozij, Miroslav

AU - Zukal, Arnost

AU - Shvets, Oleksiy

AU - Cejka, Jiri

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AB - The properties of zeolites, and thus their suitability for different applications, are intimately connected with their structures. Synthesizing specific architectures is therefore important, but has remained challenging. Here we report a top-down strategy that involves the disassembly of a parent zeolite, UTL, and its reassembly into two zeolites with targeted topologies, IPC-2 and IPC-4. The three zeolites are closely related as they adopt the same layered structure, and they differ only in how the layers are connected. Choosing different linkers gives rise to different pore sizes, enabling the synthesis of materials with predetermined pore architectures. The structures of the resulting zeolites were characterized by interpreting the X-ray powder-diffraction patterns through models using computational methods; IPC-2 exhibits orthogonal 12- and ten-ring channels, and IPC-4 is a more complex zeolite that comprises orthogonal ten- and eight-ring channels. We describe how this method enables the preparation of functional materials and discuss its potential for targeting other new zeolites.

KW - Structure-directing agent

KW - Interlayer expansion

KW - Channels

KW - Framework

KW - Layer

KW - Transformation

KW - Precursors

KW - Silicates

KW - Cations

KW - System

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SP - 628

EP - 633

JO - Nature Chemistry

JF - Nature Chemistry

IS - 7

ER -

A family of zeolites with controlled pore size prepared using a top-down method

Abstract

Keywords

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Projects

Assembly Disassembly Reassembly: Assembly disassembly reassembly - New routes to extended structures and their impact

Structuring the Future: Structuring the Future - Underpinning world-leading science in EaStCHEM through cutting edge characterisation

Upgrade Small Equipment Base: Small items of research equipment at the University of St Andrews. Supporting a new generation of physical sciences research

Cite this