The role of Al on Ohmic contact formation on n-type GaN and AlGaN∕GaN

Chu

Journal of Applied Physics

et al. 2006

The surface chemistry and electrical properties of p-type and n-type AlGaN surfaces were studied via x-ray photoelectron spectroscopy before and after oxidation and wet chemical treatments. Shifts in the surface Fermi level were measured with the change in onset of the valence-band spectra. Oxidation and HF and (NH4)2Sx treatments on p-type AlGaN (n-type AlGaN) led to an increase (the reduction) in the surface band bending due to more N vacancies and N vacancies being occupied by S (i.e., donorlike states) than Al vacancies and Ga vacancies (i.e., acceptorlike states) near the p-type AlGaN (n-type AlGaN) surface region. The changes in surface chemistry indicate that oxidation and wet chemical treatments alter the surface state density through the formation of more donorlike states.

Section: Resultssupporting

confidence: 76%

Induced changes in surface band bending of n-type and p-type AlGaN by oxidation and wet chemical treatments

Chu

Journal of Applied Physics

et al. 2006

Journal of Applied Physics

“…This phenomenon of N reduction at interface is consistent with previous report for low Al content case. 24,25 Thus, it is convinced that the desired Al-rich bonding state at the interface has been achieved.…”

Section: Resultsmentioning

confidence: 85%

Ohmic contact to n-AlGaN through bonding state transition at TiAl interface

Zhang

Wang

et al. 2012

We report the optimized ohmic contact to high Al content n-AlGaN through modification of the interfacial bonding state of TiAl alloy. First-principles calculations demonstrate that the change of interfacial bonding state (N rich to Al rich) at the TiAl/n-AlGaN interface is crucial for the formation of low barrier contact. The significant electron-transfer and strong orbital hybridization between the Ti atoms and the nearest Al atoms plays a key role in lowering the contact barrier. After treatment of the TiAl/n-AlGaN sample via rapid thermal annealing, perfectly linear I-V characteristic is achieved and the elemental profile by Auger electron spectroscopy confirms the N-rich-to-Al-rich local state transition in the interfacial layers. (C) 2012 American Institute of Physics. [http://dx.doi.org/10.1063/1.4727848

“…Becase the binding energy of the N-Ti [13] and N-Al [22] bonds are too close to distinguish. This can simply be explained by considering the enthalpies of formation of GaN, TiN, and AlN (respectively, -110.9, -265.5, and -318.1 kJ/mol) [6]. However, because the Al-N bond is stronger than the Ti-N bond, resulting in the formation of thin AlN layer at the GaN:O interface.…”

Section: Resultsmentioning

confidence: 99%

Investigation of the Ti/Al/Pt/Au and Ti/Au contact materials on the N‐face surface of oxygen doped GaN

Tsai

Chen³

et al. 2014

Phys. Status Solidi C

Ti/Al/Pt/Au and Ti/Au ohmic contact materials on the N‐face surface of oxygen doped GaN (GaN:O) were investigated by measuring the specific contact resistivity (ρc) with respect to annealing temperature. Ti/Au contact showed good ohmic property in contrast to Ti/Al/Pt/Au contact on the N‐face surface of GaN:O. Based on the x‐ray photoelectron spectroscopy results, we found that the formation of N‐Al bonds with the increase of annealing treatment temperature and the increase of upward band bending near the N‐face GaN:O surface might lead to an increase in the effective Schottky barrier high, resulting in an increase in the ρc of N‐face GaN:O. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)