Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks

Jin Hu Dou; Maxx Q. Arguilla; Yi Luo; Jian Li; Weizhe Zhang; Lei Sun; Jenna L. Mancuso; Luming Yang; Tianyang Chen; Lucas R. Parent; Grigorii Skorupskii; Nicole J. Libretto; Chenyue Sun; Min Chieh Yang; Phat Vinh Dip; Edward J. Brignole; Jeffrey T. Miller; Jing Kong; Christopher H. Hendon; Junliang Sun; Mircea Dincă

doi:10.1038/s41563-020-00847-7

Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks

Jin Hu Dou, Maxx Q. Arguilla, Yi Luo, Jian Li, Weizhe Zhang, Lei Sun, Jenna L. Mancuso, Luming Yang, Tianyang Chen, Lucas R. Parent, Grigorii Skorupskii, Nicole J. Libretto, Chenyue Sun, Min Chieh Yang, Phat Vinh Dip, Edward J. Brignole, Jeffrey T. Miller, Jing Kong, Christopher H. Hendon, Junliang SunMircea Dincă

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

319 Scopus citations

Abstract

Electrically conducting 2D metal–organic frameworks (MOFs) have attracted considerable interest, as their hexagonal 2D lattices mimic graphite and other 2D van der Waals stacked materials. However, understanding their intrinsic properties remains a challenge because their crystals are too small or of too poor quality for crystal structure determination. Here, we report atomically precise structures of a family of 2D π-conjugated MOFs derived from large single crystals of sizes up to 200 μm, allowing atomic-resolution analysis by a battery of high-resolution diffraction techniques. A designed ligand core rebalances the in-plane and out-of-plane interactions that define anisotropic crystal growth. We report two crystal structure types exhibiting analogous 2D honeycomb-like sheets but distinct packing modes and pore contents. Single-crystal electrical transport measurements distinctively demonstrate anisotropic transport normal and parallel to the π-conjugated sheets, revealing a clear correlation between absolute conductivity and the nature of the metal cation and 2D sheet packing motif.

Original language	English (US)
Pages (from-to)	222-228
Number of pages	7
Journal	Nature Materials
Volume	20
Issue number	2
DOIs	https://doi.org/10.1038/s41563-020-00847-7
State	Published - Feb 2021
Externally published	Yes

All Science Journal Classification (ASJC) codes

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

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Dou, J. H., Arguilla, M. Q., Luo, Y., Li, J., Zhang, W., Sun, L., Mancuso, J. L., Yang, L., Chen, T., Parent, L. R., Skorupskii, G., Libretto, N. J., Sun, C., Yang, M. C., Dip, P. V., Brignole, E. J., Miller, J. T., Kong, J., Hendon, C. H., ... Dincă, M. (2021). Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks. Nature Materials, 20(2), 222-228. https://doi.org/10.1038/s41563-020-00847-7

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title = "Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks",

abstract = "Electrically conducting 2D metal–organic frameworks (MOFs) have attracted considerable interest, as their hexagonal 2D lattices mimic graphite and other 2D van der Waals stacked materials. However, understanding their intrinsic properties remains a challenge because their crystals are too small or of too poor quality for crystal structure determination. Here, we report atomically precise structures of a family of 2D π-conjugated MOFs derived from large single crystals of sizes up to 200 μm, allowing atomic-resolution analysis by a battery of high-resolution diffraction techniques. A designed ligand core rebalances the in-plane and out-of-plane interactions that define anisotropic crystal growth. We report two crystal structure types exhibiting analogous 2D honeycomb-like sheets but distinct packing modes and pore contents. Single-crystal electrical transport measurements distinctively demonstrate anisotropic transport normal and parallel to the π-conjugated sheets, revealing a clear correlation between absolute conductivity and the nature of the metal cation and 2D sheet packing motif.",

author = "Dou, {Jin Hu} and Arguilla, {Maxx Q.} and Yi Luo and Jian Li and Weizhe Zhang and Lei Sun and Mancuso, {Jenna L.} and Luming Yang and Tianyang Chen and Parent, {Lucas R.} and Grigorii Skorupskii and Libretto, {Nicole J.} and Chenyue Sun and Yang, {Min Chieh} and Dip, {Phat Vinh} and Brignole, {Edward J.} and Miller, {Jeffrey T.} and Jing Kong and Hendon, {Christopher H.} and Junliang Sun and Mircea Dinc{\u a}",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2021",

month = feb,

doi = "10.1038/s41563-020-00847-7",

language = "English (US)",

volume = "20",

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Dou, JH, Arguilla, MQ, Luo, Y, Li, J, Zhang, W, Sun, L, Mancuso, JL, Yang, L, Chen, T, Parent, LR, Skorupskii, G, Libretto, NJ, Sun, C, Yang, MC, Dip, PV, Brignole, EJ, Miller, JT, Kong, J, Hendon, CH, Sun, J & Dincă, M 2021, 'Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks', Nature Materials, vol. 20, no. 2, pp. 222-228. https://doi.org/10.1038/s41563-020-00847-7

TY - JOUR

T1 - Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks

AU - Dou, Jin Hu

AU - Arguilla, Maxx Q.

AU - Luo, Yi

AU - Li, Jian

AU - Zhang, Weizhe

AU - Sun, Lei

AU - Mancuso, Jenna L.

AU - Yang, Luming

AU - Chen, Tianyang

AU - Parent, Lucas R.

AU - Skorupskii, Grigorii

AU - Libretto, Nicole J.

AU - Sun, Chenyue

AU - Yang, Min Chieh

AU - Dip, Phat Vinh

AU - Brignole, Edward J.

AU - Miller, Jeffrey T.

AU - Kong, Jing

AU - Hendon, Christopher H.

AU - Sun, Junliang

AU - Dincă, Mircea

PY - 2021/2

Y1 - 2021/2

N2 - Electrically conducting 2D metal–organic frameworks (MOFs) have attracted considerable interest, as their hexagonal 2D lattices mimic graphite and other 2D van der Waals stacked materials. However, understanding their intrinsic properties remains a challenge because their crystals are too small or of too poor quality for crystal structure determination. Here, we report atomically precise structures of a family of 2D π-conjugated MOFs derived from large single crystals of sizes up to 200 μm, allowing atomic-resolution analysis by a battery of high-resolution diffraction techniques. A designed ligand core rebalances the in-plane and out-of-plane interactions that define anisotropic crystal growth. We report two crystal structure types exhibiting analogous 2D honeycomb-like sheets but distinct packing modes and pore contents. Single-crystal electrical transport measurements distinctively demonstrate anisotropic transport normal and parallel to the π-conjugated sheets, revealing a clear correlation between absolute conductivity and the nature of the metal cation and 2D sheet packing motif.

AB - Electrically conducting 2D metal–organic frameworks (MOFs) have attracted considerable interest, as their hexagonal 2D lattices mimic graphite and other 2D van der Waals stacked materials. However, understanding their intrinsic properties remains a challenge because their crystals are too small or of too poor quality for crystal structure determination. Here, we report atomically precise structures of a family of 2D π-conjugated MOFs derived from large single crystals of sizes up to 200 μm, allowing atomic-resolution analysis by a battery of high-resolution diffraction techniques. A designed ligand core rebalances the in-plane and out-of-plane interactions that define anisotropic crystal growth. We report two crystal structure types exhibiting analogous 2D honeycomb-like sheets but distinct packing modes and pore contents. Single-crystal electrical transport measurements distinctively demonstrate anisotropic transport normal and parallel to the π-conjugated sheets, revealing a clear correlation between absolute conductivity and the nature of the metal cation and 2D sheet packing motif.

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VL - 20

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EP - 228

JO - Nature Materials

JF - Nature Materials

IS - 2

ER -

Atomically precise single-crystal structures of electrically conducting 2D metal–organic frameworks

Abstract

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