Abstract
Transition metal oxides offer functional properties beyond conventional semiconductors. Bridging the gap between the fundamental research frontier in oxide electronics and their realization in commercial devices demands a wafer-scale growth approach for high-quality transition metal oxide thin films. Such a method requires excellent control over the transition metal valence state to avoid performance deterioration, which has been proved challenging. Here we present a scalable growth approach that enables a precise valence state control. By creating an oxygen activity gradient across the wafer, a continuous valence state library is established to directly identify the optimal growth condition. Single-crystalline VO 2 thin films have been grown on wafer scale, exhibiting more than four orders of magnitude change in resistivity across the metal-to-insulator transition. It is demonstrated that "electronic grade" transition metal oxide films can be realized on a large scale using a combinatorial growth approach, which can be extended to other multivalent oxide systems.
Original language | English |
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Article number | 8475 |
Journal | Nature Communications |
Volume | 6 |
DOIs | |
State | Published - Oct 9 2015 |
Externally published | Yes |
Funding
The financial support from the National Science Foundation through Grant No. DMR-1352502 and the Penn State MRSEC program DMR-1420620 is gratefully acknowledged. We thank Y.-C. Lin for the help in KPFM measurements, G. Barber and the Materials Characterization Lab (MCL) at Penn State for the help in XPS measurements, as well as B. Jalan, M. Brahlek and C. Eaton for helpful discussions.