Exploring the Leidenfrost Effect for the Deposition of High-Quality In2 O3 Layers via Spray Pyrolysis at Low Temperatures and Their Application in High Electron Mobility Transistors
Dimitrakopulos, George P.
Patsalas, Panos P.
Anthopoulos, Thomas D.
KAUST DepartmentKAUST Solar Center (KSC)
Materials Science and Engineering Program
Physical Sciences and Engineering (PSE) Division
Permanent link to this recordhttp://hdl.handle.net/10754/623834
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AbstractThe growth mechanism of indium oxide (InO) layers processed via spray pyrolysis of an aqueous precursor solution in the temperature range of 100-300 °C and the impact on their electron transporting properties are studied. Analysis of the droplet impingement sites on the substrate's surface as a function of its temperature reveals that Leidenfrost effect dominated boiling plays a crucial role in the growth of smooth, continuous, and highly crystalline InO layers via a vapor phase-like process. By careful optimization of the precursor formulation, deposition conditions, and choice of substrate, this effect is exploited and ultrathin and exceptionally smooth layers of InO are grown over large area substrates at temperatures as low as 252 °C. Thin-film transistors (TFTs) fabricated using these optimized InO layers exhibit superior electron transport characteristics with the electron mobility reaching up to 40 cm V s, a value amongst the highest reported to date for solution-processed InO TFTs. The present work contributes enormously to the basic understanding of spray pyrolysis and highlights its tremendous potential for large-volume manufacturing of high-performance metal oxide thin-film transistor electronics.
CitationIsakov I, Faber H, Grell M, Wyatt-Moon G, Pliatsikas N, et al. (2017) Exploring the Leidenfrost Effect for the Deposition of High-Quality In2 O3 Layers via Spray Pyrolysis at Low Temperatures and Their Application in High Electron Mobility Transistors. Advanced Functional Materials 27: 1606407. Available: http://dx.doi.org/10.1002/adfm.201606407.
SponsorsI.I., M.G., and T.D.A. acknowledge the financial support from PragmatIC Printing Limited (Company Number 07423954) and from the Engineering and Physical Sciences Research Council (EPSRC) (Grant No. EP/G037515/1). CHESS was supported by the NSF & NIH/NIGMS via NSF Award No. DMR-1332208.
JournalAdvanced Functional Materials