Ti Alloyed α-Ga2O3 : route towards Wide Band Gap Engineering

Barthel, Armin; Roberts, Joseph; Napari, Mari; Frentrup, Martin; Huq, Tahmid; Kovács, András; Oliver, Rachel; Chalker, Paul; Sajavaara, Timo; Massabuau, Fabien

doi:10.3390/mi11121128

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Barthel, A., Roberts, J., Napari, M., Frentrup, M., Huq, T., Kovács, A., Oliver, R., Chalker, P., Sajavaara, T., & Massabuau, F. (2020). Ti Alloyed α-Ga2O3 : route towards Wide Band Gap Engineering. Micromachines, 11(12), Article 1128. https://doi.org/10.3390/mi11121128

Published in

Micromachines

Authors

Barthel, Armin |

Roberts, Joseph |

Napari, Mari |

Frentrup, Martin |

Huq, Tahmid |

Kovács, András |

Oliver, Rachel |

Chalker, Paul |

Sajavaara, Timo |

Massabuau, Fabien

Date

2020

Discipline

Fysiikka Kiihdytinlaboratorio Physics Accelerator Laboratory

Copyright

The suitability of Ti as a band gap modifier for alpha-Ga2O3 was investigated, taking advantage of the isostructural alpha phases and high band gap difference between Ti2O3 and Ga2O3. Films of (Ti,Ga)(2)O-3 were synthesized by atomic layer deposition on sapphire substrates, and characterized to determine how crystallinity and band gap vary with composition for this alloy. We report the deposition of high quality alpha-(TixGa1-x)(2)O-3 films with x = 3.7%. For greater compositions the crystalline quality of the films degrades rapidly, where the corundum phase is maintained in films up to x = 5.3%, and films containing greater Ti fractions being amorphous. Over the range of achieved corundum phase films, that is 0% <= x <= 5.3%, the band gap energy varies by similar to 270 meV. The ability to maintain a crystalline phase at low fractions of Ti, accompanied by a modification in band gap, shows promising prospects for band gap engineering and the development of wavelength specific solar-b ... showmore

Publisher

MDPI

ISSN Search the Publication Forum

2072-666X

Additional information about funding

This project is funded by the Engineering and Physical Sciences Research Council (EPSRC Grants No. EP/P00945X/1 and No. EP/M010589/1). T.N.H. acknowledges funding from the EPSRC Centre for Doctoral Training in Graphene Technology (Grant No. EP/L016087/1). This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 823717 – ES ... showmore

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Except where otherwise noted, this item's license is described as CC BY 4.0