Enhancement in electrical conductivity of a porous indium based metal-organic framework upon I uptake: combined experimental and theoretical investigations

To date, the direct synthesis of conductive metal-organic frameworks (C-MOFs) has been a very challenging task, which limits the applications of MOF materials in the field of electronics. In this study, we have incorporated the guest molecule (iodine) into the micropores of an indium-based MOF, whic...

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Published in:Journal of materials chemistry. C, Materials for optical and electronic devices Materials for optical and electronic devices, 2020-04, Vol.8 (14), p.4836-4842
Main Authors: Mani, Prabu, Mandal, Nilangshu, Roopesh, Mekkat, Gopalakrishnan, Harikrishnan, Datta, Ayan, Mandal, Sukhendu
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container_title Journal of materials chemistry. C, Materials for optical and electronic devices
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creator Mani, Prabu
Mandal, Nilangshu
Roopesh, Mekkat
Gopalakrishnan, Harikrishnan
Datta, Ayan
Mandal, Sukhendu
description To date, the direct synthesis of conductive metal-organic frameworks (C-MOFs) has been a very challenging task, which limits the applications of MOF materials in the field of electronics. In this study, we have incorporated the guest molecule (iodine) into the micropores of an indium-based MOF, which resulted in an enhancement of electrical conductivity by about a thousandfold. Optical band gap energy was lowered by ∼58% through this I 2 uptake process. Combined experimental and theoretical studies confirmed the presence of I 2 molecules inside the pore. DFT calculations showed that the dispersive interactions between thiophenedicarboxylate linkers and I 2 facilitate to hold the I 2 unit inside the cavity and give higher binding energy, which give rise to a new pathway for charge transport. Combined experimental and theoretical calculations shed light on the enhancement of conductivity through I 2 incorporation in an indium metal-organic framework.
doi_str_mv 10.1039/d0tc00475h
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title Enhancement in electrical conductivity of a porous indium based metal-organic framework upon I uptake: combined experimental and theoretical investigations
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