Engineering of tunnel junctions for prospective spin injection in germanium

Even though the strong Fermi-level pinning at the metal/germanium (Ge) interface can be alleviated by inserting a thin layer of tunneling oxide, the still sizeable Schottky barriers and the wide depletion regions of the Fe/oxide/n-Ge contacts make the junction resistances strongly dependent of tempe...

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Veröffentlicht in:Applied physics letters 2009-06, Vol.94 (24)
Hauptverfasser: Zhou, Yi, Ogawa, Masaaki, Bao, Mingqiang, Han, Wei, Kawakami, Roland K., Wang, Kang L.
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Ogawa, Masaaki
Bao, Mingqiang
Han, Wei
Kawakami, Roland K.
Wang, Kang L.
description Even though the strong Fermi-level pinning at the metal/germanium (Ge) interface can be alleviated by inserting a thin layer of tunneling oxide, the still sizeable Schottky barriers and the wide depletion regions of the Fe/oxide/n-Ge contacts make the junction resistances strongly dependent of temperature. The resistance-area (RA) products of these junctions are too high for spin injection and cannot be tuned by simply varying oxide thickness or using ferromagnetic metal (FM) with a lower work function. In this work, low energy ion implantation and rapid thermal annealing were utilized to degenerately dope the Ge surface layer to facilitate single-step tunneling transport. The RA products of the junctions with surface doping are significantly reduced and weakly dependent of temperature. This method gives a prospect for spin injection to Ge from FM.
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title Engineering of tunnel junctions for prospective spin injection in germanium
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