期刊
ACS APPLIED MATERIALS & INTERFACES
卷 14, 期 41, 页码 47255-47261出版社
AMER CHEMICAL SOC
DOI: 10.1021/acsami.2c13352
关键词
InP; Fermi level pinning; band bending; water adsorption; P-rich; dangling bond defect; surface reactivity
资金
- DFG
- Hchstleistungs-Rechenzentrum Stuttgart (HLRS)
- [JA859/35-1]
- [SCHM1361/26]
Based on density functional theory calculations and experimental results, it is shown that surface defects formed on the InP (001) surface lead to band gap states, and these defects are stable for water adsorption, with significant water dissociation expected to occur at steps rather than terraces.
Stable InP (001) surfaces are characterized by fully occupied and empty surface states close to the bulk valence and conduction band edges, respectively. The present photoemission data show, however, a surface Fermi level pinning only slightly below the midgap energy which gives rise to an appreciable surface band bending. By means of density functional theory calculations, it is shown that this apparent discrepancy is due to surface defects that form at finite temperature. In particular, the desorption of hydrogen from metalorganic vapor phase epitaxy grown P-rich InP (001) surfaces exposes partially filled P dangling bonds that give rise to band gap states. These defects are investigated with respect to surface reactivity in contact with molecular water by low -temperature water adsorption experiments using photoemission spectroscopy and are compared to our computational results. Interestingly, these hydrogen-related gap states are robust with respect to water adsorption, provided that water does not dissociate. Because significant water dissociation is expected to occur at steps rather than terraces, surface band bending of a flat InP (001) surface is not affected by water exposure.
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