Breakthrough on new material for making high performance components for use in next gen electronic devices

16 November 2021

Gwangju Institute of Science & Technology infographic_Nature of the surface space charge layer on undoped SrTiO3
Gwangju Institute of Science & Technology infographic_Nature of the surface space charge layer on undoped SrTiO3

New research from South Korea's Gwangju Institute of Science & Technology reveals the easy tunability of a perovskite material, opening doors to its widespread use in next generation electronics.

Electronic device makers are introducing high performance technologies every day to adapt with the advancement in next generation electronic devices. With same objective in mind, researchers at South Korea's Gwangju Institute of Science & Technology (GIST) evaluated the process to use the tuning of perovskite material to fabricate thin films for making high performance electronic components of such devices. The finding about this promising alternative to silicon-based components for next gen electronics has been published in the Journal of Materials Chemistry C.

Perovskites are semiconducting materials that are a promising alternative to silicon for use in electronics. In a new study, researchers highlight how fabrication of thin films of a particular perovskite in different environments leads to altered electronic properties. This flexibility allows for the development of films with tunable electronic properties, opening doors to a wide variety of next generation electronic devices.

As our lifestyles become ingrained with flexible electronics, smart devices, artificial intelligence and  the internet of things, high performance, electronic components that can perform high speed data collection, processing and execution become a necessity. Certain perovskites are crystal structures that can be promising alternatives to silicon-based components for these next generation electronic applications. Their cubic-like lattice makes them ideal for use as a base for growing oxide films to form heterostructures with unique electrical properties. The properties of these heterostructures depend on the charge transfer in the interfacial layer between the perovskite substrate and oxide overlayer. This charge transfer can be manipulated via either doping or through the fabrication process.

Now, researchers from Korea, led by Professor Bongjin Simon Mun from Gwangju Institute of Science & Technology, have used ambient pressure X-ray photoelectron spectroscopy (AP-XPS) and low energy electron diffraction (LEED) to investigate how fabrication conditions (annealing in an oxygen-rich environment and an oxygen deficit, low-pressure environment) for a particular perovskite material, SrTiO3—one of the most popular substrates for growing oxide films—affects its undoped surface and the resulting interfacial layer of the heterostructure. By using an undoped surface, the researchers wanted to examine the changes that occur on the surface of the substrate without interference from the dopants. “The presence of doping can interfere with correct interpretation of the surface defect states, which can be critical to apprehend the electrical properties of heterostructures. Our study on undoped SrTiO3 provides unbiased characteristics of SrTiO3 substrate,” says Prof. Mun. Their findings were made available online on 16 September 2021 and published in Volume 9 Issue 38 of the Journal of Materials Chemistry C.

In the oxygen environment, an electron depletion layer formed as the Sr atoms in the substrate migrated to the surface of the film to react with oxygen and form a stable oxide layer. In the low-pressure oxygen deficit environment, the formation of such a depletion layer was limited as the oxide layer was formed due to the reduction of the TiO2 layer that generated electrons.

In both environments, a similar oxide layer was formed, but the electronic properties of the structure differed as the electron depletion layer is key to the conductivity of the structure. “Our work shows clearly how the electrical properties of devices can be tuned by adjusting the population of electrons near the surface region, which is a very fundamental and important result indicating that future electronic devices can be realised with material characterization at the atomic level,” says Prof. Mun. “In the long run, our study on SrTiO3 will lay out a solid foundation for advanced electronic devices that will enable a better lifestyle for us.


Title of original paper: Nature of the surface space charge layer on undoped SrTiO3 (001)
Journal: Journal of Materials Chemistry C
Authors: From Gwangju Institute of Science and Technology, Republic of Korea: Bongjin Simon Mun; Hojoon Lim; Chanyang Song; Minsik Seo; Dongwoo Kim; Moonjung Jung; Habin Kang; Seunghwan Kim; Kyung-Jae Lee. From Korea Basic Science Institute, Republic of Korea: Youngseok Yu. From Pohang Accelerator Laboratory, Republic of Korea: Geonhwa Kim; Ki-Jeong Kim.
DOI: https://doi.org/10.1039/D1TC03436G
Author’s email
: bsmun@gist.ac.kr


About Gwangju Institute of Science & Technology (GIST)
The Gwangju Institute of Science & Technology (GIST) is a research-oriented university situated in Gwangju, South Korea. As one of the most prestigious schools in South Korea, it was founded in 1993. The university aims to create a strong research environment to spur advancements in science and technology and to promote collaboration between foreign and domestic research programmes. With its motto, “A Proud Creator of Future Science and Technology,” GIST has consistently received one of the highest university rankings in Korea. Website
: http://www.gist.ac.kr/

About the author
Bongjin Simon Mun
is a Professor of Physics & Photon Science at the Gwangju Institute of Science & Technology in Korea. His main research interest is to understand the correlation between surface chemical reactions and electronic structures under various reaction conditions. Mun has been actively involved with the development and application of ambient pressure X-ray photoelectron spectroscopy. Before moving to Korea, Mun worked at Advanced Light Source as a staff scientist. After receiving a Ph.D. in physics from the University of California Davis under the supervision of Prof. Chuck S. Fadley, Mun completed his postdoctoral training at the Phil Ross Group at the Lawrence Berkeley National Laboratory.


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