High-k Al2O3 MOS structures with Si interface control layer formed on air-exposed GaAs and InGaAs wafers

Akazawa, Masamichi; Hasegawa, Hideki

doi:10.1016/j.apsusc.2010.03.087

Cited by 16 publications

(13 citation statements)

References 16 publications

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“…For the decapped surface (solid blue curves), Fermi level on both the n-type and p-type samples is positioned near the valance band (VB) indicating the decapped surface is pinned. For InGaAs, it is common that the Fermi level is pinned near the conduction band edge; 39 however, STS is a conductance based technique and will ignore fixed charge or deep traps, a more detailed analysis of this topic can be seen in Ref. 40.…”

Section: Sts Of Tma On Ingaas(001) (4 × 2) Vs (2 × 4)mentioning

confidence: 99%

Atomic imaging of atomic layer deposition oxide nucleation with trimethylaluminum on As-rich InGaAs(001) 2 × 4 vs Ga/In-rich InGaAs(001) 4 × 2

Melitz

Kent

Kummel

et al. 2012

The Journal of Chemical Physics

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Formation of a contaminant free, flat, electrically passive interface to a gate oxide such as a-Al(2)O(3) is the critical step in fabricating III-V metal oxide semiconductor field effect transistors; while the bulk oxide is amorphous, the interface may need to be ordered to prevent electrical defect formation. A two temperature in situ cleaning process is shown to produce a clean, flat group III or group V rich InGaAs surface. The dependence of initial surface reconstruction and dosing temperature of the seeding of aluminum with trimethylaluminum dosing is observed to produce an ordered unpinned passivation layer on InGaAs(001)-(4 × 2) surface at sample temperatures below 190 °C. Conversely, the InGaAs(001)-(2 × 4) surface is shown to generate an unpinned passivation layer with a seeding temperature up to 280 °C. For both reconstructions, the chemical drive force is consistent with formation of As-Al-As bonds. The optimal seed layer protects the surface from background contamination.

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Section: Sts Of Tma On Ingaas(001) (4 × 2) Vs (2 × 4)mentioning

confidence: 99%

Atomic imaging of atomic layer deposition oxide nucleation with trimethylaluminum on As-rich InGaAs(001) 2 × 4 vs Ga/In-rich InGaAs(001) 4 × 2

Melitz

Kent

Kummel

et al. 2012

The Journal of Chemical Physics

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“…Gate stack quality on GaAs can thus be improved over conventional direct dielectric deposition. This was first demonstrated in 1988 using Si-based dielectrics (32)(33)(34) and verified later with high-k dielectrics (35,36). A beneficial impact of atomic hydrogen on interface trap density has been observed with both types of gate stacks (37,38).…”

Section: Iii-v Channel Interface Control: Direct Deposition and Cappimentioning

confidence: 81%

(Invited) Gate Stacks for Silicon, Silicon Germanium, and III-V Channel MOSFETs

Frank¹,

Zhu²,

Bedell³

et al. 2014

ECS Trans.

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High-k gate dielectrics such as HfO 2 and metal gates such as TiN have been deployed across a wide range of silicon-based CMOS logic products. In some gate-first technologies, SiGe channels (cSiGe) have been implemented simultaneously for threshold voltage control in p-channel metal-oxide-semiconductor fieldeffect transistors (pMOSFET). Herein, we review aspects related to the impact of high-k/channel interfacial layers on Si, SiGe, and III-V gate stack quality and device performance. First, we review remote oxygen scavenging approaches for interfacial SiO 2 thinning in HfO 2 /Si nFET and HfO 2 /cSiGe pFET devices. We show that they allow equivalent oxide thickness (EOT) to be reduced to 0.4-0.5 nm, and we discuss device performance and reliability tradeoffs that may limit continued EOT scaling. For later technology nodes, high-carrier-mobility III-V semiconductors channels such as InGaAs are under consideration. We summarize three high-k/InGaAs channel interface approaches: Direct high-k deposition, Si capping, and InP capping.

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“…Controlling III-V surface oxidation, which leads to the formation of a high density of extrinsic defect states (D it ) at the high-k/InGaAs interface, is a major challenge to optimum device operation. Passivation procedures aimed at controlling D it by removal of the native oxide have been developed [4][5][6][7][8]. The use of sulphur based chemicals such as ammonium sulphide (NH 4 ) 2 S [1,9] have been extensively investigated due to its effectiveness at removing native oxides and passivating the surface thereby improving the electrical characteristics of devices [1,3,10,11].…”

Section: Introductionmentioning

confidence: 99%

High temperature thermal stability studies of ultrathin Al2O3 layers deposited on native oxide and sulphur passivated InGaAs surfaces

Chauhan

Gajula

Neill

et al. 2015

Microelectronic Engineering

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High-k Al2O3 MOS structures with Si interface control layer formed on air-exposed GaAs and InGaAs wafers

Cited by 16 publications

References 16 publications

Atomic imaging of atomic layer deposition oxide nucleation with trimethylaluminum on As-rich InGaAs(001) 2 × 4 vs Ga/In-rich InGaAs(001) 4 × 2

Atomic imaging of atomic layer deposition oxide nucleation with trimethylaluminum on As-rich InGaAs(001) 2 × 4 vs Ga/In-rich InGaAs(001) 4 × 2

(Invited) Gate Stacks for Silicon, Silicon Germanium, and III-V Channel MOSFETs

High temperature thermal stability studies of ultrathin Al2O3 layers deposited on native oxide and sulphur passivated InGaAs surfaces

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