Intrinsic glassy-metallic transport in an amorphous coordination polymer

Xie, Jiaze; Ewing, Simon; Boyn, Jan-Niklas; Filatov, Alexander S.; Cheng, Baorui; Ma, Tengzhou; Grocke, Garrett L.; Zhao, Norman; Itani, Ram; Sun, Xiaotong; Cho, Himchan; Chen, Zhihengyu; Chapman, Karena W.; Patel, Shrayesh N.; Talapin, Dmitri V.; Park, Jiwoong; Mazziotti, David A.; Anderson, John S.

Intrinsic glassy-metallic transport in an amorphous coordination polymer

Jiaze Xie, Simon Ewing, Jan-Niklas Boyn, Alexander S. Filatov, Baorui Cheng, Tengzhou Ma, Garrett L. Grocke, Norman Zhao, Ram Itani, Xiaotong Sun, Himchan Cho, Zhihengyu Chen, Karena W. Chapman, Shrayesh N. Patel, Dmitri V. Talapin, Jiwoong Park, David A. Mazziotti and John S. Anderson ()
Additional contact information
Jiaze Xie: University of Chicago
Simon Ewing: University of Chicago
Jan-Niklas Boyn: University of Chicago
Alexander S. Filatov: University of Chicago
Baorui Cheng: University of Chicago
Tengzhou Ma: University of Chicago
Garrett L. Grocke: University of Chicago
Norman Zhao: University of Chicago
Ram Itani: University of Chicago
Xiaotong Sun: University of Chicago
Himchan Cho: University of Chicago
Zhihengyu Chen: Stony Brook University
Karena W. Chapman: Stony Brook University
Shrayesh N. Patel: University of Chicago
Dmitri V. Talapin: University of Chicago
Jiwoong Park: University of Chicago
David A. Mazziotti: University of Chicago
John S. Anderson: University of Chicago

Nature, 2022, vol. 611, issue 7936, 479-484

Abstract: Abstract Conducting organic materials, such as doped organic polymers1, molecular conductors2,3 and emerging coordination polymers4, underpin technologies ranging from displays to flexible electronics5. Realizing high electrical conductivity in traditionally insulating organic materials necessitates tuning their electronic structure through chemical doping6. Furthermore, even organic materials that are intrinsically conductive, such as single-component molecular conductors7,8, require crystallinity for metallic behaviour. However, conducting polymers are often amorphous to aid durability and processability9. Using molecular design to produce high conductivity in undoped amorphous materials would enable tunable and robust conductivity in many applications10, but there are no intrinsically conducting organic materials that maintain high conductivity when disordered. Here we report an amorphous coordination polymer, Ni tetrathiafulvalene tetrathiolate, which displays markedly high electronic conductivity (up to 1,200 S cm−1) and intrinsic glassy-metallic behaviour. Theory shows that these properties are enabled by molecular overlap that is robust to structural perturbations. This unusual set of features results in high conductivity that is stable to humid air for weeks, pH 0–14 and temperatures up to 140 °C. These findings demonstrate that molecular design can enable metallic conductivity even in heavily disordered materials, raising fundamental questions about how metallic transport can exist without periodic structure and indicating exciting new applications for these materials.

Date: 2022
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DOI: 10.1038/s41586-022-05261-4

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