universidad autónoma de nuevo leóncdigital.dgb.uanl.mx/la/1080017189_c/1080017189_t1/... · 2011....
Home
Documents
Universidad Autónoma de Nuevo Leóncdigital.dgb.uanl.mx/la/1080017189_C/1080017189_T1/... · 2011. 3. 30. · poner de modelo. Jamas el pueblo americano debia haber olyidado ni la
1 9
100%
Actual Size
Fit Width
Fit Height
Fit Page
Automatic
Research Article Performance Analysis of Ti-Doped In 2 O 3 Thin Films Prepared by Various Doping Concentrations Using RF Magnetron Sputtering for Light-Emitting Device Wittawat Poonthong, 1 Narong Mungkung , 1 Pakpoom Chansri, 1 Somchai Arunrungrusmi, 1 and Toshifumi Yuji 2 1 Plasma and Electrical Discharge Laboratory, Department of Electrical Technology Education, King Mongkut ’ s University of Technology Thonburi, Bangkok 10140, Thailand 2 Faculty of Education, University of Miyazaki, Miyazaki, Japan Correspondence should be addressed to Narong Mungkung; [email protected] Received 29 May 2020; Revised 13 July 2020; Accepted 3 August 2020; Published 28 August 2020 Academic Editor: Jinn Kong Sheu Copyright © 2020 Wittawat Poonthong et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. The in fl uences of doping amounts of TiO 2 on the structure and electrical properties of In 2 O 3 fi lms were experimentally studied. In this study, titanium-doped indium oxide (ITiO) conductions were deposited on glass substrate by the dual-target-type radio frequency magnetron sputtering (RFS) system under di ff erent conditions of Ti-doped In 2 O 3 targets, from Ti-0.5 wt% to Ti- 5.0 wt%, along with 10 mTorr and 300 W pressure of RF power control that was used as a cost-e ff ective transparent electrochemiluminescence (ECL) cell. From this process, the correlation between structural, optical, and electrical properties is reported. It was found that the best 1 : 14 × 10 - 4 Ω cm of resistivity was from Ti-2.5 wt% with the highest carrier concentration (1.15 × 10 21 cm -3 ), Hall mobility (46.03 cm 2 /V · s), relatively transmittance (82%), and ECL e ffi ciency (0.43 lm · W -1 ) with well crystalline structured and smooth morphology. As a result, researchers can be responsible for preparing ITiO thin fi lms with signi fi cantly improved microstructure and light intensity performance for the e ff ectiveness of the display devices, as well as its simple process and high performance. 1. Introduction The transparent conducting oxide (TCO) fi lms have become of interest in the study of light-emitting materials because they have a high electrical conductivity and good transpar- ency in the visible region. The potential application of TCO materials includes fl at panel displays, electrooptical devices, and solar cells [1 – 4]. Particularly, electrochemiluminescence (ECL) has been developed due to their advantages (cost-e ff ec- tive manufacturing, simpli fi ed optical con fi guration, and high luminescence e ffi ciency) and fl exibility that can improve the light-emission performance of the application with the TCO devices [5, 6]. Among the conventional TCO fi lms, indium tin oxide (ITO) fi lms have been reported as TCO materials due to their good optical and electrical properties (resistivity about 10 -4 Ω cm) [7, 8]. However, ITO materials are toxic and they more often than not lack fl exibility and thermal sta- bility. To address these problems, a new alternative material to ITO was needed. In this sense, thin- fi lm materials were devel- oped with numerous channel materials incorporated with impurity doping such as Zn-doped In 2 O 3 [9], Mo-doped In 2 O 3 [8, 9], or Ti-In 2 O 3 [10 – 12] that are found to be an ITO alternative for the transparent conducting application [13]. Titanium-doped indium oxide (ITiO) was considered the best choice because ITiO has a relatively low sheet resis- tance and demonstrates a high transmission in the near infra- red (NIR), apart from its high mobility [10]. Many deposition techniques have been experimented in the preparation of ITiO thin fi lms. Some of them are listed as pulsed laser deposition (PLD) [14], spray pyrolysis [15], ion beam sputtering [16], radio frequency (RF) magnetron sputtering [17], and chemical vapor deposition (CVD) [18]. Among the wide range of fi lm
Upload: others
Post on 25-Feb-2021
3 views
Embed Size (px):
344 x 292
429 x 357
514 x 422
599 x 487