Ultralow Defect Density at Sub-0.5 nm HfO<sub>2</sub>/SiGe Interfaces via Selective Oxygen Scavenging

Kavrik, Mahmut Sami; Thomson, Emily; Chagarov, Evgueni; Tang, Kechao; Ueda, Scott T.; Hou, Vincent; Aoki, Toshihiro; Kim, Moon J.; Frühberger, Bernd; Taur, Yuan; McIntyre, Paul C.; Kummel, Andrew C.

doi:10.1021/acsami.8b06547

Cited by 31 publications

(36 citation statements)

References 27 publications

(56 reference statements)

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“…S6) indicating similar O and Hf peak decay profiles at the SiGe interface unlike with Ni gates which show offsets between O and Hf peak at the interface (Fig. 6a-f) 17 .…”

Section: Resultsmentioning

confidence: 84%

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeO_x Reduction

Kavrik

Ercius

Cheung

et al. 2019

ACS Appl. Mater. Interfaces

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Suppression of electronic defects induced by GeO x at the high-k gate oxide/SiGe interface is critical for implementation of high mobility SiGe channels in CMOS technology. Theoretical and experimental studies have shown that a low defect density interface can be formed with an SiO xrich interlayer on SiGe. Experimental studies in literature indicates better interface formation with Al 2 O 3 in contrast to HfO 2 on SiGe however the mechanism behind this is not well understood. In this study, the mechanism of forming a low defect density interface between Al 2 O 3 /SiGe is investigated using atomic layer deposited (ALD) Al 2 O 3 insertion into or on top of ALD HfO 2 gate oxides. To elucidate the mechanism, correlations are made between the defect density determined by impedance measurements and the chemical and physical structure of the interface determined by high resolution scanning transmission electron microscopy and electron energy loss spectroscopy (STEM-EELS). Compositional analysis reveals an SiO x rich interlayer for both Al 2 O 3 /SiGe and HfO 2 /SiGe interfaces with insertion of Al 2 O 3 into or on top of the HfO 2 oxide. The data is consistent with the Al 2 O 3 insertion inducing decomposition of the GeO x from the interface to form an electrically passive, SiO x rich interface on SiGe. This mechanism shows that nanolaminate gate oxide chemistry cannot be interpreted as resulting from a simple layer by layer ideal ALD process because the precursor or its reaction products can diffuse though the oxide during growth and react at the semiconductor interface. This result shows that in scaled CMOS, remote oxide ALD (oxide ALD on top of the gate oxide) can be used to suppress electronic defects at gate-oxide semiconductor interfaces by oxygen scavenging.

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“…S6) indicating similar O and Hf peak decay profiles at the SiGe interface unlike with Ni gates which show offsets between O and Hf peak at the interface (Fig. 6a-f) 17 .…”

Section: Resultsmentioning

confidence: 84%

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeO_x Reduction

Kavrik

Ercius

Cheung

et al. 2019

ACS Appl. Mater. Interfaces

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“…Elimination of unstable GeO x species may be possible with Si cap layers epitaxially grown on SiGe channels for planar devices; however it may be problematic for gate-all-around devices or FinFETs due to space constraints and the limitation in Si ALDs which may have low mobility due to defects 14 . Previous studies on defect suppression at the gate oxide-SiGe interface have included pre ALD passivation with nitrides [15][16] and sulfur 17 and post ALD selective oxygen scavenging with physical vapor deposited (PVD) gettering metal gates 12,18 . However, the interfaces are still degraded mainly by Ge out-diffusion 13 during ALD at elevated temperatures.…”

Section: Introductionmentioning

confidence: 99%

“…However, the interfaces are still degraded mainly by Ge out-diffusion 13 during ALD at elevated temperatures. There are also processing challenges, for example the gettering metal inducing a reduction in maximum capacitance by forming thicker gate oxides and PVD being incompatible with nanoscale 3D devices employed 18 . Another approach for defect reduction is selective oxygen scavenging at high temperature (>500C).…”

Section: Introductionmentioning

confidence: 99%

“…For SiGe substrates, it was shown that post ALD oxidation on low Ge content SiGe (30% to 50%) forms a highly defective SiGeO x interface, and the thickness of the IL decreases for higher Ge composition SiGe (Si 0.69 Ge 0.31 to Si 0.5 Ge 0.95 ) due to suppression of SiO x in the IL 21 . However, DFT and experimental studies shown that formation of an SiO x interface between SiGe and oxide results in an extremely low interfacial defect density on low Ge content SiGe 18 .…”

Section: Introductionmentioning

confidence: 99%

“…Gate metal and back contacts were formed with Ni thermal evaporation and Al sputtering. Optimized forming gas annealing (5%H 2 /95%N 2 ) was employed in 3 steps 300C-330C-350C for 10 min each, de tails of the very similar MOSCAP fabrication process can be found elsewhere 18 . Electrical characterization of the MOSCAP devices was performed with a Keysight B1500 at 300 K by I-V and multifrequency C-V, G-V measurements from inversion at 2V to accumulation at -2V.…”

Section: Introductionmentioning

confidence: 99%

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Understanding the Mechanism of Electronic Defect Suppression Enabled by Nonidealities in Atomic Layer Deposition

et al. 2019

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Silicon germanium (SiGe) is a multi-functional material considered for quantum computing, neuromorphic devices and CMOS transistors. However, implementation of SiGe in nano-scale electronic devices necessitates suppression of surface states dominating on electronic properties. The absence of a stable and passive surface oxide for SiGe results formation of charge traps at the SiGe -oxide interface induced by GeO x . In an ideal ALD process in which oxide is grown layer-by-layer, the GeO x formation should be prevented with selective surface oxidation (i.e. formation of an SiO x interface) by controlling oxidant dose in first few ALD cycles of the oxide deposition on SiGe. However, in a real ALD process, the interface evolves during entire ALD oxide deposition due to diffusion of reactant species through the gate oxide. In this work, this diffusion process in non-ideal ALD is investigated and exploited: the diffusion through the oxide during ALD is utilized to passivate the interfacial defects by employing ozone as a secondary oxidant. Periodic ozone exposure during gate oxide ALD on SiGe is shown to reduce the integrated trap density (D it ) across the band gap by nearly an order of magnitude in Al 2 O 3 (< 6×10 10 cm -2 ) and in HfO 2 (< 3.9×10 11 cm -2 ) by forming a SiO x rich interface on SiGe. Depletion of Ge from the interfacial layer (IL) by enhancement of volatile GeO x formation and consequent desorption from the SiGe with ozone insertion during ALD growth process is confirmed by electron energy loss spectroscopy (STEM-EELS) and hypothesized to be the mechanism for reduction of the interfacial defects. In this work, the nanoscale mechanism for defect suppression at SiGe oxide interface is demonstrated which is engineering of diffusion species in ALD process due to facile diffusion of reactant species in non-ideal ALD.

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Al2O3/Si0.7Ge0.3(001) & HfO2/Si0.7Ge0.3(001) interface trap state reduction via in-situ N2/H2 RF downstream plasma passivation

Breeden

Wolf

Ueda

et al. 2019

Applied Surface Science

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Ultralow Defect Density at Sub-0.5 nm HfO₂/SiGe Interfaces via Selective Oxygen Scavenging

Cited by 31 publications

References 27 publications

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeO_x Reduction

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeO_x Reduction

Understanding the Mechanism of Electronic Defect Suppression Enabled by Nonidealities in Atomic Layer Deposition

Al2O3/Si0.7Ge0.3(001) & HfO2/Si0.7Ge0.3(001) interface trap state reduction via in-situ N2/H2 RF downstream plasma passivation

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Ultralow Defect Density at Sub-0.5 nm HfO2/SiGe Interfaces via Selective Oxygen Scavenging

Cited by 31 publications

References 27 publications

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeOx Reduction

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeOx Reduction

Understanding the Mechanism of Electronic Defect Suppression Enabled by Nonidealities in Atomic Layer Deposition

Al2O3/Si0.7Ge0.3(001) & HfO2/Si0.7Ge0.3(001) interface trap state reduction via in-situ N2/H2 RF downstream plasma passivation

Contact Info

Product

Resources

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Ultralow Defect Density at Sub-0.5 nm HfO₂/SiGe Interfaces via Selective Oxygen Scavenging

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeO_x Reduction

Engineering High-k/SiGe Interface with ALD Oxide for Selective GeO_x Reduction