2017年第78回応用物理学会秋季学術講演会

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一般セッション(口頭講演)

9 応用物性 » 9.2 ナノワイヤ・ナノ粒子

[6p-S44-1~21] 9.2 ナノワイヤ・ナノ粒子

2017年9月6日(水) 13:15 〜 19:00 S44 (第5会議室)

深田 直樹(物材機構)、石川 史太郎(愛媛大)、清水 智弘(関西大)

13:15 〜 13:30

[6p-S44-1] [JSAP Young Scientist Award Speech] Application-oriented electronic structure engineering in colloidal quantum dot solids

Daniel Balazs1,2、Mark Speirs1、Satria Zulkarnaen Bisri2、Dmitry Dirin3、Loredana Protesescu3、Maksym Kovalenko3、Yoshihiro Iwasa2,4、Maria Antonietta Loi1 (1.Univ. of Groningen、2.RIKEN CEMS、3.ETH Zurich、4.Univ. of Tokyo)

キーワード:colloidal quantum dot, semiconductor nanocrystal, electronic transport

Colloidal quantum dots (CQDs) are semiconductor nanocrystals soluble in common organic solvents, combining the flexibility and low cost of solution-processed materials and the durability and high mobility of the inorganic core. Moreover, the presence of quantum confinement and the large surface-to-volume ratio allow for wide control of the optical and electronic properties such as the band gap, carrier mobility and concentration, all by simple, chemical methods. The particle size, the ligands attached to the surface and the environment play the most important roles in tailoring the material’s behavior.
For a long time, lead-chalcogenide CQD films were thought to be p-type, which was mainly caused by the oxidative environment used for processing and characterization. Once these factors were under control, and more air-stable chemical treatments were introduced, the materials became predominantly n-type. The consequent change in the device structure allowed for boost in the solar cell performances, and set the lack of stable p-type material as the limiting factor in the development. It has been predicted that the lead-to-sulfur ratio in PbS CQDs influences the electronic structure, offering a prospective solution.
In this work, I present a method to fine-tune the layer stoichiometry in order to enhance the hole mobility and the effective p-doping of PbS CQD films. The hole mobility increases 3 orders of magnitudes, while the electron mobility remains the same, pointing to an altered electronic structure as the cause of the change. The developed method was proven useful in improving the photoconversion efficiencies of PbQ CQD solar cells through parallel mobility and hole concentration increase. Further improvement of the method might allow the observation of a strong Seebeck-effect in PbS CQD films, which is promising for their applications in thermoelectric devices.