The 70th JSAP Spring Meeting 2023

Presentation information

Oral presentation

21 Joint Session K "Wide bandgap oxide semiconductor materials and devices" » 21.1 Joint Session K "Wide bandgap oxide semiconductor materials and devices"

[15p-E102-1~17] 21.1 Joint Session K "Wide bandgap oxide semiconductor materials and devices"

Wed. Mar 15, 2023 1:30 PM - 6:15 PM E102 (Building No. 12)

Mamoru Furuta(Kochi Univ. of Tech.), Keisuke Ide(Tokyo Tech), Ken Goto(Tokyo Univ. Agri. and Tech.)

3:30 PM - 3:45 PM

[15p-E102-8] Ferroelectric HfO2-ZrO2 Gated Transparent InSnZnOx Thin Film Memories

〇(D)Hui Yang1,2, Prashant Ghediya1, Yuqiao Zhang3, Yasutaka Matsuo1, Yusaku Magari1, Hiromichi Ohta1 (1.RIES-Hokkaido Univ., 2.Beijing Jiaotong Univ., 3.Jiangsu Univ.)

Keywords:Thin Film Memories, InSnZnOx, Ferroelectric

Transparent thin film memory devices are expected as necessary parts for next-generation transparent electronics. In 2011, Lee and Tokumitsu et al. demonstrated transparent ferroelectric TFTs using P(VDF-TrFE) as the ferroelectric layer and amorphous In-Ga-Zn-O (a-IGZO) as the channel. Although the device showed a very large memory window and on-to-off current ratio, the deposition process of the P(VDF-TrFE) was not well matched for the practical device fabrication. Recently, HfO2-ZrO2 (HZO) is a popular ferroelectric material because it shows ferroelectricity even though the film is extremely thin (~10 nm). There are several reports on a-IGZO-based FeTFTs using HZO as a ferroelectric layer. However, most researchers used TiN on Si substrate as the gate electrode, therefore, the FeTFTs are not transparent. Here, we show the fabrication and characterization of transparent FeTFTs using InSnZnOx (ITZO) as the channel layer. We deposited a 20-nm-thick HZO layer on an ITO-coated alkali-free glass substrate (Corning® EAGLE XG®) by the ALD method. Then, we deposited a 10-nm-thick ITZO channel and a 30-nm-thick ITO electrode by the PLD method. After the film deposition, the devices were annealed at 300 °C in air for 10 min. The resultant transparent FeTFTs showed clear anticlockwise hysteresis with a memory window of ~0.2 V. We measured the thermopower of the channel during/after a gate voltage application and confirmed the carrier accumulation after the gate voltage application. Since the present ITZO-based FeTFT exhibits high mobility, it would be an excellent device for the next-generation transparent electronics.