2015年 第76回応用物理学会秋季学術講演会

講演情報

一般セッション(口頭講演)

12 有機分子・バイオエレクトロニクス » 12.3 機能材料・萌芽的デバイス

[14p-2A-1~17] 12.3 機能材料・萌芽的デバイス

2015年9月14日(月) 14:00 〜 18:30 2A (211-1)

座長:野々口 斐之(奈良先端大),小柴 康子(神戸大)

17:45 〜 18:00

[14p-2A-15] Polaron Effect on Electronic Transport of Colloidal Quantum Dot Ambipolar Field-Effect Transistors

〇Satria Bisri1,2, M. Insan Nugraha2, Mykhailo Sytnyk3, Wolfgang Heiss3,4, Maria Loi2 (1.RIKEN-CEMS, 2.Univ. Groningen, 3.Univ. Linz, 4.Univ. Erlangen-Nurnberg)

キーワード:self-assembled materials,device physics (mechanism, Charge injection and transport, surface and interface properties),organic-inorganic hybrids

Colloidal quantum dots (CQDs) are nanometer size single crystal inorganic materials, which are stabilized by organic molecules to make them soluble, ideal for solution-processable electronics. The size-dependent quantum confinement effect makes these semiconducting materials to have analogous properties to organic materials. Despite CQD assemblies have been proven ideal for photovoltaics and displays applications, many aspects of the charge carrier transport properties have not been investigated yet.
Here we show that the electronic transport in the assembly of CQDs are strongly influenced by the polaron of the insulator dielectric. Ambipolar field-effect transistors of PbS CQDs have been fabricated using various kinds of polymer dielectric that can be spin-coated on top of the QD film without changing its properties. Among them are three types of high-k ferroelectric polymers. All of these polymers can support the ambipolar transport operation of the PbS QD FETs. At room temperature, the charge carrier mobilities of these FETs do not differ so much from the state-of-the-art.1,2,3 However, decreasing the FET operation temperature, signify the influence of the usage of dielectric towards the charge carrier mobility values. The higher the dielectric coefficient of the insulating polymers, the lower the holes and electron mobility values. These findings can be attributed to the Fröhlich polaron formation at the semiconductor/insulator interface. The observation in nanostructured inorganic semiconductors might indicate that this phenomenon is not only limited for organic semiconductors,4 but might be more general occurrence in systems having modest carrier mobility values.
References:[1] S. Z. Bisri, et al. Adv. Mater. 26, 1176 (2014); [2] S. Z. Bisri, et al. Adv. Mater. 25, 4309 (2013); [3] M. I. Nugraha, S. Z. Bisri, et al. Adv. Mater. 27, 2107 (2015); [4] I. N. Hulea, et al. Nature Mater. 5, 982 (2006)