Growth and Characterization of Epitaxial Al Layers on GaAs and Si Substrates for Superconducting CPW Resonators in Scalable Quantum Computing Systems PDF Download
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Author: Julie Tournet Publisher: ISBN: Category : Molecular beam epitaxy Languages : en Pages : 144
Book Description
The growth of Aluminum (Al) on semiconductors and dielectrics is a cornerstone in the quest for scalable quantum computing systems. Indeed the electrical properties of Al make it an exceptional candidate for the realization of superconducting resonators, pivotal tools for understanding and operating superconducting qubits. Such resonators have been fabricated recently on Sapphire substrates, using molecular beam epitaxy (MBE), and displayed quality factors above a million. Complementary studies of these resonators have demonstrated that the metal-substrate interface was the primary source of decoherence and losses, highlighting the importance of pristine interfaces (free of contaminants), and high quality epitaxial growth in order to minimize the native defects level. In this work we investigate different substrate materials in order to yield equivalent or higher quality factor resonators. Gallium Arsenide (GaAs) and Silicon (Si) were selected for their good dielectric properties, well-established processing techniques and a potential on-chip integration. After thermal substrate annealing, and in some cases deposition of a buffer structure, Al was grown on both substrates at low temperature, using MBE. In view of the extreme sensitivity of the resulting Al crystal orientation to the initial surface conditions, different starting surface reconstructions were investigated. Growth evolution was studied with reflection high energy electron diffraction simultaneously at several azimuths during deposition on rotating substrates. The substrate temperature, the system background pressure and possible sources of contamination were monitored carefully to ensure the reproducibility of the results. Resulting layers were subsequently characterized with X-ray diffraction (XRD) to confirm their epitaxial nature and crystallographic orientation. Finally, atomic force microscopy was used to assess the layers morphology. Different growth modes were observed depending on the material: Al grew in a Stranski-Krastanov mode on GaAs(001) surfaces, in a Frank-van-der-Merwe mode on Si(111) surfaces and in a Volmer-Weber mode on Si(001) surfaces. All yielded crystalline structures. Targeting atomically smooth single crystalline materials, best results were obtained for Al(110) deposited on GaAs(001)-(2x4) substrates with surfaces showing RMS roughness of 0.552nm. While the epitaxy on Si(111)-(``1x1") led to single-crystalline Al(111) layers with a RMS roughness of only 0.487nm, a detailed XRD study indicated a possible misalignment of the crystallites that could induce defects in the material. Similarly, epitaxy on Si(111)-(7x7) substrates yielded Al(111) layers of a RMS roughness of 0.519nm that, however, appeared rougher under the Nomarski microscope, likely due to the surface preparation prior to Al deposition. The deposition on Si(001)-(2x1) substrates led to bi-crystals of Al(110) of higher RMS roughness (0.719nm). Finally, the growth on GaAs(001)-(4x4) reconstruction led to polycrystalline materials with mixed Al(100), Al(110) and Al(111) of RMS roughness 1.20nm. Moreover, the composition of the layers grown on the GaAs(001)-(4x4) reconstruction was inconsistent across multiple growths.
Author: Julie Tournet Publisher: ISBN: Category : Molecular beam epitaxy Languages : en Pages : 144
Book Description
The growth of Aluminum (Al) on semiconductors and dielectrics is a cornerstone in the quest for scalable quantum computing systems. Indeed the electrical properties of Al make it an exceptional candidate for the realization of superconducting resonators, pivotal tools for understanding and operating superconducting qubits. Such resonators have been fabricated recently on Sapphire substrates, using molecular beam epitaxy (MBE), and displayed quality factors above a million. Complementary studies of these resonators have demonstrated that the metal-substrate interface was the primary source of decoherence and losses, highlighting the importance of pristine interfaces (free of contaminants), and high quality epitaxial growth in order to minimize the native defects level. In this work we investigate different substrate materials in order to yield equivalent or higher quality factor resonators. Gallium Arsenide (GaAs) and Silicon (Si) were selected for their good dielectric properties, well-established processing techniques and a potential on-chip integration. After thermal substrate annealing, and in some cases deposition of a buffer structure, Al was grown on both substrates at low temperature, using MBE. In view of the extreme sensitivity of the resulting Al crystal orientation to the initial surface conditions, different starting surface reconstructions were investigated. Growth evolution was studied with reflection high energy electron diffraction simultaneously at several azimuths during deposition on rotating substrates. The substrate temperature, the system background pressure and possible sources of contamination were monitored carefully to ensure the reproducibility of the results. Resulting layers were subsequently characterized with X-ray diffraction (XRD) to confirm their epitaxial nature and crystallographic orientation. Finally, atomic force microscopy was used to assess the layers morphology. Different growth modes were observed depending on the material: Al grew in a Stranski-Krastanov mode on GaAs(001) surfaces, in a Frank-van-der-Merwe mode on Si(111) surfaces and in a Volmer-Weber mode on Si(001) surfaces. All yielded crystalline structures. Targeting atomically smooth single crystalline materials, best results were obtained for Al(110) deposited on GaAs(001)-(2x4) substrates with surfaces showing RMS roughness of 0.552nm. While the epitaxy on Si(111)-(``1x1") led to single-crystalline Al(111) layers with a RMS roughness of only 0.487nm, a detailed XRD study indicated a possible misalignment of the crystallites that could induce defects in the material. Similarly, epitaxy on Si(111)-(7x7) substrates yielded Al(111) layers of a RMS roughness of 0.519nm that, however, appeared rougher under the Nomarski microscope, likely due to the surface preparation prior to Al deposition. The deposition on Si(001)-(2x1) substrates led to bi-crystals of Al(110) of higher RMS roughness (0.719nm). Finally, the growth on GaAs(001)-(4x4) reconstruction led to polycrystalline materials with mixed Al(100), Al(110) and Al(111) of RMS roughness 1.20nm. Moreover, the composition of the layers grown on the GaAs(001)-(4x4) reconstruction was inconsistent across multiple growths.
Author: Takashi Hariu Publisher: World Scientific ISBN: 9789971508395 Category : Technology & Engineering Languages : en Pages : 356
Book Description
Low temperature processes for semiconductors have been recently under intensive development to fabricate controlled device structures with minute dimensions in order to achieve the highest device performance and new device functions as well as high integration density. Comprising reviews by experts long involved in the respective pioneering work, this volume makes a useful contribution toward maturing the process of low temperature epitaxy as a whole.
Author: B Baliga Publisher: Elsevier ISBN: 0323155456 Category : Technology & Engineering Languages : en Pages : 337
Book Description
Epitaxial Silicon Technology is a single-volume, in-depth review of all the silicon epitaxial growth techniques. This technology is being extended to the growth of epitaxial layers on insulating substrates by means of a variety of lateral seeding approaches. This book is divided into five chapters, and the opening chapter describes the growth of silicon layers by vapor-phase epitaxy, considering both atmospheric and low-pressure growth. The second chapter discusses molecular-beam epitaxial growth of silicon, providing a unique ability to grow very thin layers with precisely controlled doping characteristics. The third chapter introduces the silicon liquid-phase epitaxy, in which the growth of silicon layers arose from a need to decrease the growth temperature and to suppress autodoping. The fourth chapter addresses the growth of silicon on sapphire for improving the radiation hardness of CMOS integrated circuits. The fifth chapter deals with the advances in the application of silicon epitaxial growth. This chapter also discusses the formation of epitaxial layers of silicon on insulators, such as silicon dioxide, which do not provide a natural single crystal surface for growth. Each chapter begins with a discussion on the fundamental transport mechanisms and the kinetics governing the growth rate, followed by a description of the electrical properties that can be achieved in the layers and the restrictions imposed by the growth technique upon the control over its electrical characteristics. Each chapter concludes with a discussion on the applications of the particular growth technique. This reference material will be useful for process technologists and engineers who may need to apply epitaxial growth for device fabrication.
Author: Chih-Chun Wang Publisher: ISBN: Category : Languages : en Pages : 119
Book Description
Research on the epitaxial growth and characterization of GaAs on magnesium aluminate spinel has been carried out. Single crystal GaAs films (unintentionally doped) with thicknesses up to 70 micrometers have been grown on a spinel substrate using the vapor phase reaction between (CH3)3Ga and AsH3. The effect of growth conditions on the layer characteristics has been studied in order to achieve optimization of the film properties. Growth parameters studied include substrate orientation, substrate surface preparation, growth temperature, gas flow conditions, reactor geometry, and source material purification. The purity of the source material has been found to play a critically important role in determining both the crystallinity and the electrical properties of the films. Films with electron and hold mobilities up to, respectively, 4000 and 300 sq cm/V-sec have been prepared. Epitaxial growth of GaAs on GaAs/spinel composite using vapor phase and liquid phase techniques was explored with encouraging results. The epitaxial GaAs-spinel composites have been characterized by x-ray diffraction, electron diffraction, electron microscopy, and optical techniques. Information on the crystalline perfection, epitaxial orientation relationships, surface structures, and optical constants has been obtained. The overall single crystalline GaAs deposits are composed of crystallites which are misoriented by plus or minus 0.1 degree from the nominal orientation of the layer. The stress in the epitaxial GaAs was determined to be 1x10 to the 9th power dyne/sq cm. (Author).
Author: Mahsa Mahtab Publisher: ISBN: Category : Languages : en Pages :
Book Description
GaAs(1-x)Bi(x) (x = 0 to 17%) optical properties were investigated by spectroscopic ellipsometry (in energy ranges of 0.37-9.0 eV). Optical features in the dielectric function, known as the critical points, were distinguished and modeled using standard analytic line shapes. The energy dependence of the critical points energies was thoroughly investigated as a function of Bi content and thin film strain. Critical points analysis in the Brillion zone showed that the top of the valence band is most strongly dependent on Bi content compared to other parts of the band structure. In addition, an interesting new critical point was observed that is attributed to alternative allowed optical transitions made possible by changes to the top of the valence band caused by resonant interactions with Bi orbitals. Several of the critical points were extrapolated to 100% Bi and showed reasonable agreement with the calculated band structure of GaBi. GaAs(1-x)Bi(x) (x= 03, 0.7 and 1.1%) based p+/n and n+/p heterostructure photovoltaic performance was characterized through IV and CV measurement. By introduction of Bi into GaAs, a non-zero EQE below the GaAs band edge energy was observed while the highest efficiency was obtained by ~ 0.7% Bi incorporation. EQE spectrum was modeled to find the minority carrier diffusion lengths of ~ Ln = 1600 and Lp = 140 nm for p-doped and n-doped GaAs92Bi08 in the doping profile of 10^15 - 10^16 cm^-3. Analysis of the CV measurement confirmed the background n-doping effect of Bi atom and the essential role of the cap layer to reduce multi-level recombination mechanisms at the cell edge to improve ideality factor. Low temperature grown GaAs was optimized to be used as photoconductive antenna in THz time-domain spectroscopy setup. The As content was investigated to optimize photo-carrier generation using 1550 nm laser excitation while maintaining high mobility and resistivity required for optical switching. A barrier layer of AlAs was added below the LT-GaAs to limit carrier diffusion into the GaAs substrate. Moreover, LT-GaAs layer thickness and post-growth annealing condition was optimized. The optimized structure (2-μm LT-GaAs on 60-nm AlAs, under As2:Ga BEP of ~7, annealed at 550°C for 1 minute) outperformed a commercial InGaAs antenna by a factor of 15 with 4.5 THz bandwidth and 75 dB signal-to-noise ratio at 1550 nm wavelength.
Author: Julie Tournet
Author: Julie Tournet
Author: Takashi Hariu
Author: B Baliga
Author: Chih-Chun Wang
Author: Hyunchul Sohn
Author: Peter Sheldon
Author: Christian Fuchs
Author: E. Lendvay
Author: Mahsa Mahtab
Author: Din-How Mei