Publikation: Multilevel Resonant Tunneling through Purely Organic Radical Molecules in a Si-Based Double-Tunnel Junction
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The use of purely organic radicals is promising, especially for future applications in molecular spintronics. However, the techniques used to form their molecular junctions, including break-junction and scanning tunneling microscopy techniques, are unsuitable for the integration of molecular devices in a large-scale setting. In this study, a Si-based double-tunnel junction with purely organic radicals, where adamantyl nitronyl nitroxide p-terphenyl (NN-TP) molecules are embedded as quantum dots in the oxide layer of a metal–oxide–semiconductor (MOS) structure, was demonstrated. Notably, this MOS structure functions as a tunnel junction, which has a high affinity for the current Si technology. In this study, multilevel resonant tunneling through the discrete energy levels of the NN-TP molecules at 7 K was achieved; moreover, the tunneling current was observed at 100 K. Furthermore, our device exhibited resonant tunneling through a singly occupied molecular orbital, indicating the survival of an unpaired electron in the radical molecules. Thus, our findings hold promise for incorporating the attractive functions of organic radicals into Si-based solid-state devices, thereby enabling the large-scale integration of molecular devices.
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BERA, Jayanta, Mikhail KABDULOV, Yutaka WAKAYAMA, Thomas HUHN, Ryoma HAYAKAWA, 2025. Multilevel Resonant Tunneling through Purely Organic Radical Molecules in a Si-Based Double-Tunnel Junction. In: ACS Applied Materials & Interfaces. ACS Publications. ISSN 1944-8244. eISSN 1944-8252. Verfügbar unter: doi: 10.1021/acsami.5c00839BibTex
@article{Bera2025-04-06Multi-73043,
title={Multilevel Resonant Tunneling through Purely Organic Radical Molecules in a Si-Based Double-Tunnel Junction},
year={2025},
doi={10.1021/acsami.5c00839},
issn={1944-8244},
journal={ACS Applied Materials & Interfaces},
author={Bera, Jayanta and Kabdulov, Mikhail and Wakayama, Yutaka and Huhn, Thomas and Hayakawa, Ryoma}
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<dcterms:abstract>The use of purely organic radicals is promising, especially for future applications in molecular spintronics. However, the techniques used to form their molecular junctions, including break-junction and scanning tunneling microscopy techniques, are unsuitable for the integration of molecular devices in a large-scale setting. In this study, a Si-based double-tunnel junction with purely organic radicals, where adamantyl nitronyl nitroxide p-terphenyl (NN-TP) molecules are embedded as quantum dots in the oxide layer of a metal–oxide–semiconductor (MOS) structure, was demonstrated. Notably, this MOS structure functions as a tunnel junction, which has a high affinity for the current Si technology. In this study, multilevel resonant tunneling through the discrete energy levels of the NN-TP molecules at 7 K was achieved; moreover, the tunneling current was observed at 100 K. Furthermore, our device exhibited resonant tunneling through a singly occupied molecular orbital, indicating the survival of an unpaired electron in the radical molecules. Thus, our findings hold promise for incorporating the attractive functions of organic radicals into Si-based solid-state devices, thereby enabling the large-scale integration of molecular devices.</dcterms:abstract>
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