Heterometallic Benzenehexathiolato Coordination Nanosheets: Periodic Structure Improves Crystallinity and Electrical Conductivity

Ryojun Toyoda; Naoya Fukui; Dionisius H.L. Tjhe; Ekaterina Selezneva; Hiroaki Maeda; Cédric Bourgès; Choon Meng Tan; Kenji Takada; Yuanhui Sun; Ian Jacobs; Kazuhide Kamiya; Hiroyasu Masunaga; Takao Mori; Sono Sasaki; Henning Sirringhaus; Hiroshi Nishihara

doi:10.1002/adma.202106204

Heterometallic Benzenehexathiolato Coordination Nanosheets: Periodic Structure Improves Crystallinity and Electrical Conductivity

Ryojun Toyoda, Naoya Fukui, Dionisius H.L. Tjhe, Ekaterina Selezneva, Hiroaki Maeda, Cédric Bourgès, Choon Meng Tan, Kenji Takada, Yuanhui Sun, Ian Jacobs, Kazuhide Kamiya, Hiroyasu Masunaga, Takao Mori, Sono Sasaki, Henning Sirringhaus, Hiroshi Nishihara

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

6 Citations (Scopus)

Abstract

Coordination nanosheets are an emerging class of 2D, bottom-up materials having fully π-conjugated, planar, graphite-like structures with high electrical conductivities. Since their discovery, great effort has been devoted to expand the variety of coordination nanosheets; however, in most cases, their low crystallinity in thick films hampers practical device applications. In this study, mixtures of nickel and copper ions are employed to fabricate benzenehexathiolato (BHT)-based coordination nanosheet films, and serendipitously, it is found that this heterometallicity preferentially forms a structural phase with improved film crystallinity. Spectroscopic and scattering measurements provide evidence for a bilayer structure with in-plane periodic arrangement of copper and nickel ions with the NiCu₂BHT formula. Compared with homometallic films, heterometallic films exhibit more crystalline microstructures with larger and more oriented grains, achieving higher electrical conductivities reaching metallic behaviors. Low dependency of Seebeck coefficient on the mixing ratio of nickel and copper ions supports that the large variation in the conductivity data is not caused by change in the intrinsic properties of the films. The findings open new pathways to improve crystallinity and to tune functional properties of 2D coordination nanosheets.

Original language	English
Article number	2106204
Journal	Advanced Materials
Volume	34
Issue number	13
DOIs	https://doi.org/10.1002/adma.202106204
Publication status	Published - 2022 Apr 1
Externally published	Yes

Keywords

2D polymers
benzenehexathiolato metal complexes
coordination nanosheets
electrical conductivities
heterometallicity

ASJC Scopus subject areas

Materials Science(all)
Mechanics of Materials
Mechanical Engineering

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10.1002/adma.202106204

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Toyoda, R., Fukui, N., Tjhe, D. H. L., Selezneva, E., Maeda, H., Bourgès, C., Tan, C. M., Takada, K., Sun, Y., Jacobs, I., Kamiya, K., Masunaga, H., Mori, T., Sasaki, S., Sirringhaus, H., & Nishihara, H. (2022). Heterometallic Benzenehexathiolato Coordination Nanosheets: Periodic Structure Improves Crystallinity and Electrical Conductivity. Advanced Materials, 34(13), [2106204]. https://doi.org/10.1002/adma.202106204

Toyoda, R, Fukui, N, Tjhe, DHL, Selezneva, E, Maeda, H, Bourgès, C, Tan, CM, Takada, K, Sun, Y, Jacobs, I, Kamiya, K, Masunaga, H, Mori, T, Sasaki, S, Sirringhaus, H & Nishihara, H 2022, 'Heterometallic Benzenehexathiolato Coordination Nanosheets: Periodic Structure Improves Crystallinity and Electrical Conductivity', Advanced Materials, vol. 34, no. 13, 2106204. https://doi.org/10.1002/adma.202106204

@article{e197aa2e447041b88f42fa41b6e4fc34,

title = "Heterometallic Benzenehexathiolato Coordination Nanosheets: Periodic Structure Improves Crystallinity and Electrical Conductivity",

abstract = "Coordination nanosheets are an emerging class of 2D, bottom-up materials having fully π-conjugated, planar, graphite-like structures with high electrical conductivities. Since their discovery, great effort has been devoted to expand the variety of coordination nanosheets; however, in most cases, their low crystallinity in thick films hampers practical device applications. In this study, mixtures of nickel and copper ions are employed to fabricate benzenehexathiolato (BHT)-based coordination nanosheet films, and serendipitously, it is found that this heterometallicity preferentially forms a structural phase with improved film crystallinity. Spectroscopic and scattering measurements provide evidence for a bilayer structure with in-plane periodic arrangement of copper and nickel ions with the NiCu2BHT formula. Compared with homometallic films, heterometallic films exhibit more crystalline microstructures with larger and more oriented grains, achieving higher electrical conductivities reaching metallic behaviors. Low dependency of Seebeck coefficient on the mixing ratio of nickel and copper ions supports that the large variation in the conductivity data is not caused by change in the intrinsic properties of the films. The findings open new pathways to improve crystallinity and to tune functional properties of 2D coordination nanosheets.",

keywords = "2D polymers, benzenehexathiolato metal complexes, coordination nanosheets, electrical conductivities, heterometallicity",

author = "Ryojun Toyoda and Naoya Fukui and Tjhe, {Dionisius H.L.} and Ekaterina Selezneva and Hiroaki Maeda and C{\'e}dric Bourg{\`e}s and Tan, {Choon Meng} and Kenji Takada and Yuanhui Sun and Ian Jacobs and Kazuhide Kamiya and Hiroyasu Masunaga and Takao Mori and Sono Sasaki and Henning Sirringhaus and Hiroshi Nishihara",

note = "Funding Information: R.T. and N.F. contributed equally to this work. The authors acknowledge financial support from JST‐CREST JPMJCR15F2, JSPS KAKENHI Grant Number 19H05460, EPSRC‐JSPS core‐to‐core program (EP/S030662/1, JPJSCCA20190005), and White Rock Foundation. R.T. thanks JSPS Research Fellowships for Young Scientists. C.B. and T.M. acknowledge support from JST‐Mirai JPMJMI19A1. D.H.L.T. acknowledges support from the Jardine Foundation and the Cambridge Commonwealth European and International Trust. HS thanks the Royal Society for a Royal Society Research Professorship (RP\R1\201082). 2D WAXS measurements were performed at BL45 or BL05XU at SPring‐8 with approval of RIKEN. PXRD measurements were performed at BL44B2 at SPring‐8 with approval of RIKEN (20190021, 20210072). EXAFS experiments were performed using the BL01B1 Beam Line of SPring‐8 with the approval of JASRI (Proposal No.2019A1394). The authors acknowledge the Advanced Characterization Nanotechnology Platform (The University of Tokyo) JPMXP09‐A‐21‐UT‐0027 for the XPS and HAADF‐STEM/EDS measurements. Raman spectroscopy was supported by Y. Soma (Horiba Techno Service Co. Ltd). ICP analysis was supported by Dr. K. Fujimoto and Dr. A. Aimi (Department of Pure and Applied Chemistry, Tokyo University of Science). TEM observations were supported by Prof. Y. Idemoto (Department of Pure and Applied Chemistry, Tokyo University of Science) and Dr. T. Ichihashi (Research Equipment Centre, Tokyo University of Science). Funding Information: R.T. and N.F. contributed equally to this work. The authors acknowledge financial support from JST-CREST JPMJCR15F2, JSPS KAKENHI Grant Number 19H05460, EPSRC-JSPS core-to-core program (EP/S030662/1, JPJSCCA20190005), and White Rock Foundation. R.T. thanks JSPS Research Fellowships for Young Scientists. C.B. and T.M. acknowledge support from JST-Mirai JPMJMI19A1. D.H.L.T. acknowledges support from the Jardine Foundation and the Cambridge Commonwealth European and International Trust. HS thanks the Royal Society for a Royal Society Research Professorship (RP\R1\201082). 2D WAXS measurements were performed at BL45 or BL05XU at SPring-8 with approval of RIKEN. PXRD measurements were performed at BL44B2 at SPring-8 with approval of RIKEN (20190021, 20210072). EXAFS experiments were performed using the BL01B1 Beam Line of SPring-8 with the approval of JASRI (Proposal No.2019A1394). The authors acknowledge the Advanced Characterization Nanotechnology Platform (The University of Tokyo) JPMXP09-A-21-UT-0027 for the XPS and HAADF-STEM/EDS measurements. Raman spectroscopy was supported by Y. Soma (Horiba Techno Service Co. Ltd). ICP analysis was supported by Dr. K. Fujimoto and Dr. A. Aimi (Department of Pure and Applied Chemistry, Tokyo University of Science). TEM observations were supported by Prof. Y. Idemoto (Department of Pure and Applied Chemistry, Tokyo University of Science) and Dr. T. Ichihashi (Research Equipment Centre, Tokyo University of Science). Publisher Copyright: {\textcopyright} 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.",

year = "2022",

month = apr,

day = "1",

doi = "10.1002/adma.202106204",

language = "English",

volume = "34",

journal = "Advanced Materials",

issn = "0935-9648",

publisher = "Wiley-VCH Verlag",

number = "13",

}

TY - JOUR

T1 - Heterometallic Benzenehexathiolato Coordination Nanosheets

T2 - Periodic Structure Improves Crystallinity and Electrical Conductivity

AU - Toyoda, Ryojun

AU - Fukui, Naoya

AU - Tjhe, Dionisius H.L.

AU - Selezneva, Ekaterina

AU - Maeda, Hiroaki

AU - Bourgès, Cédric

AU - Tan, Choon Meng

AU - Takada, Kenji

AU - Sun, Yuanhui

AU - Jacobs, Ian

AU - Kamiya, Kazuhide

AU - Masunaga, Hiroyasu

AU - Mori, Takao

AU - Sasaki, Sono

AU - Sirringhaus, Henning

AU - Nishihara, Hiroshi

N1 - Funding Information: R.T. and N.F. contributed equally to this work. The authors acknowledge financial support from JST‐CREST JPMJCR15F2, JSPS KAKENHI Grant Number 19H05460, EPSRC‐JSPS core‐to‐core program (EP/S030662/1, JPJSCCA20190005), and White Rock Foundation. R.T. thanks JSPS Research Fellowships for Young Scientists. C.B. and T.M. acknowledge support from JST‐Mirai JPMJMI19A1. D.H.L.T. acknowledges support from the Jardine Foundation and the Cambridge Commonwealth European and International Trust. HS thanks the Royal Society for a Royal Society Research Professorship (RP\R1\201082). 2D WAXS measurements were performed at BL45 or BL05XU at SPring‐8 with approval of RIKEN. PXRD measurements were performed at BL44B2 at SPring‐8 with approval of RIKEN (20190021, 20210072). EXAFS experiments were performed using the BL01B1 Beam Line of SPring‐8 with the approval of JASRI (Proposal No.2019A1394). The authors acknowledge the Advanced Characterization Nanotechnology Platform (The University of Tokyo) JPMXP09‐A‐21‐UT‐0027 for the XPS and HAADF‐STEM/EDS measurements. Raman spectroscopy was supported by Y. Soma (Horiba Techno Service Co. Ltd). ICP analysis was supported by Dr. K. Fujimoto and Dr. A. Aimi (Department of Pure and Applied Chemistry, Tokyo University of Science). TEM observations were supported by Prof. Y. Idemoto (Department of Pure and Applied Chemistry, Tokyo University of Science) and Dr. T. Ichihashi (Research Equipment Centre, Tokyo University of Science). Funding Information: R.T. and N.F. contributed equally to this work. The authors acknowledge financial support from JST-CREST JPMJCR15F2, JSPS KAKENHI Grant Number 19H05460, EPSRC-JSPS core-to-core program (EP/S030662/1, JPJSCCA20190005), and White Rock Foundation. R.T. thanks JSPS Research Fellowships for Young Scientists. C.B. and T.M. acknowledge support from JST-Mirai JPMJMI19A1. D.H.L.T. acknowledges support from the Jardine Foundation and the Cambridge Commonwealth European and International Trust. HS thanks the Royal Society for a Royal Society Research Professorship (RP\R1\201082). 2D WAXS measurements were performed at BL45 or BL05XU at SPring-8 with approval of RIKEN. PXRD measurements were performed at BL44B2 at SPring-8 with approval of RIKEN (20190021, 20210072). EXAFS experiments were performed using the BL01B1 Beam Line of SPring-8 with the approval of JASRI (Proposal No.2019A1394). The authors acknowledge the Advanced Characterization Nanotechnology Platform (The University of Tokyo) JPMXP09-A-21-UT-0027 for the XPS and HAADF-STEM/EDS measurements. Raman spectroscopy was supported by Y. Soma (Horiba Techno Service Co. Ltd). ICP analysis was supported by Dr. K. Fujimoto and Dr. A. Aimi (Department of Pure and Applied Chemistry, Tokyo University of Science). TEM observations were supported by Prof. Y. Idemoto (Department of Pure and Applied Chemistry, Tokyo University of Science) and Dr. T. Ichihashi (Research Equipment Centre, Tokyo University of Science). Publisher Copyright: © 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.

PY - 2022/4/1

Y1 - 2022/4/1

N2 - Coordination nanosheets are an emerging class of 2D, bottom-up materials having fully π-conjugated, planar, graphite-like structures with high electrical conductivities. Since their discovery, great effort has been devoted to expand the variety of coordination nanosheets; however, in most cases, their low crystallinity in thick films hampers practical device applications. In this study, mixtures of nickel and copper ions are employed to fabricate benzenehexathiolato (BHT)-based coordination nanosheet films, and serendipitously, it is found that this heterometallicity preferentially forms a structural phase with improved film crystallinity. Spectroscopic and scattering measurements provide evidence for a bilayer structure with in-plane periodic arrangement of copper and nickel ions with the NiCu2BHT formula. Compared with homometallic films, heterometallic films exhibit more crystalline microstructures with larger and more oriented grains, achieving higher electrical conductivities reaching metallic behaviors. Low dependency of Seebeck coefficient on the mixing ratio of nickel and copper ions supports that the large variation in the conductivity data is not caused by change in the intrinsic properties of the films. The findings open new pathways to improve crystallinity and to tune functional properties of 2D coordination nanosheets.

AB - Coordination nanosheets are an emerging class of 2D, bottom-up materials having fully π-conjugated, planar, graphite-like structures with high electrical conductivities. Since their discovery, great effort has been devoted to expand the variety of coordination nanosheets; however, in most cases, their low crystallinity in thick films hampers practical device applications. In this study, mixtures of nickel and copper ions are employed to fabricate benzenehexathiolato (BHT)-based coordination nanosheet films, and serendipitously, it is found that this heterometallicity preferentially forms a structural phase with improved film crystallinity. Spectroscopic and scattering measurements provide evidence for a bilayer structure with in-plane periodic arrangement of copper and nickel ions with the NiCu2BHT formula. Compared with homometallic films, heterometallic films exhibit more crystalline microstructures with larger and more oriented grains, achieving higher electrical conductivities reaching metallic behaviors. Low dependency of Seebeck coefficient on the mixing ratio of nickel and copper ions supports that the large variation in the conductivity data is not caused by change in the intrinsic properties of the films. The findings open new pathways to improve crystallinity and to tune functional properties of 2D coordination nanosheets.

KW - 2D polymers

KW - benzenehexathiolato metal complexes

KW - coordination nanosheets

KW - electrical conductivities

KW - heterometallicity

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U2 - 10.1002/adma.202106204

DO - 10.1002/adma.202106204

M3 - Article

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SN - 0935-9648

VL - 34

JO - Advanced Materials

JF - Advanced Materials

IS - 13

M1 - 2106204

ER -

Heterometallic Benzenehexathiolato Coordination Nanosheets: Periodic Structure Improves Crystallinity and Electrical Conductivity

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