Dislocation Formation and Filtering in III–V Regrowth on GaAs Bonded on Si

Hughes, Eamonn T.; Dumont, Mario; Hu, Yingtao; Liang, Di; Beausoleil, Raymond G.; Bowers, John E.; Mukherjee, Kunal

doi:10.1021/acs.cgd.2c00309

Cited by 2 publications

(1 citation statement)

References 31 publications

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“…Hydrogen gas (H 2 ) was used as the carrier gas. To limit the defects arising from the disparity in the CTE between GaAs and Si, the growth temperature was ensured not to exceed 595 • C at any point during the epitaxy (following a similar argument as in [29]). Furthermore, in order to prevent the cracking and buckling of the bonded GaAs membrane, a gradual heating (0.95 • C s −1 ) and cooling (0.6 • C s −1 ) procedure was implemented at the start and the end of the epitaxy, respectively.…”

Section: Epitaxial Regrowth On Gaas/si Templatementioning

confidence: 99%

Growth of telecom C-band In(Ga)As quantum dots for silicon quantum photonics

Vijayan,

Joos,

Werner

et al. 2024

Mater. Quantum. Technol.

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Photonic integrated circuits based on the silicon-on-insulator platform currently allow high-density integration of optical and electro-optical components on the same chip. This high complexity is also transferred to quantum photonic integrated circuits, where non-linear processes are used for the generation of quantum light onthe silicon chip. However, these intrinsically probabilistic light emission processes pose challenges to the ultimately achievable scalability. Here, an interesting solutionwould be employing on-demand sources of quantum light based on III-V platforms, which are nonetheless very complex to grow directly on silicon. In this paper, weshow the integration of InAs quantum dots on silicon via the growth on a wafer bonded GaAs/Si template. To ensure emission in the telecom C-band (∼1550 nm), a metamorphic buffer layer approach is utilized. We show that the deposited single quantum dots show similar performance to their counterparts directly grown on thewell-established GaAs platform. Our results demonstrate that on-demand telecom emitters can be directly and effectively integrated on silicon, without compromises onthe performances of either the platforms

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Section: Epitaxial Regrowth On Gaas/si Templatementioning

confidence: 99%

Growth of telecom C-band In(Ga)As quantum dots for silicon quantum photonics

Vijayan,

Joos,

Werner

et al. 2024

Mater. Quantum. Technol.

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Revealing the mechanism of interfacial adhesion enhancement between the SiO2 film and the GaAs substrate via plasma pre-treatments

He,

Liu,

Gao

et al. 2024

Journal of Vacuum Science &Amp; Technology A

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The formation mechanism of a highly adherent silicon dioxide (SiO2) film on gallium arsenide (GaAs) substrate by plasma enhanced chemical vapor deposition (PECVD) is proposed. Ar, N2, and NH3 were used as pre-treatment gas to improve the interfacial adhesion. The interfacial adhesion was measured by the cross-cut tape test. By the measurement of spectroscopic ellipsometry and x-ray photoelectron spectroscopy (XPS), it is revealed that nitrogen plasma pre-treatment had formed a very thin GaN transition layer on the surface, which was responsible for the improvement of interfacial adhesion. XPS depth-profiling further confirmed various pre-treatment gases generate plasma mixtures and form thin film layers with different compositions on the GaAs surface. These layers have a significant impact on the adhesion of the subsequently prepared SiO2 film. The primary mechanism for improving interfacial adhesion is the renovation of the substrate composition via plasma pre-treatment by PECVD, which forms a transition layer of nitrides that eliminates the negative effects of oxides on adhesion. This study reveals the mechanism of interfacial adhesion enhancement between SiO2 film and GaAs substrate, which is of significant importance in fabricating high-performance and reliable semiconductor devices.

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Dislocation Formation and Filtering in III–V Regrowth on GaAs Bonded on Si

Cited by 2 publications

References 31 publications

Growth of telecom C-band In(Ga)As quantum dots for silicon quantum photonics

Growth of telecom C-band In(Ga)As quantum dots for silicon quantum photonics

Revealing the mechanism of interfacial adhesion enhancement between the SiO2 film and the GaAs substrate via plasma pre-treatments

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