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1. Quantitative Assessment of Carrier Density by Cathodoluminescence. II. GaAs nanowires

Author

Chen, Hung-Ling, De Lépinau, Romaric, Scaccabarozzi, Andrea, Oehler, Fabrice, Harmand, Jean-Christophe, Cattoni, Andrea, and Collin, Stéphane

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Precise control of doping in single nanowires (NWs) is essential for the development of NW-based devices. Here, we investigate a series of MBE-grown GaAs NWs with Be (p-type) and Si (n-type) doping using high-resolution cathodoluminescence (CL) mapping at low- and room-temperature. CL spectra are analyzed selectively in different regions of the NWs. Room-temperature luminescence is fitted with the generalized Planck law and an absorption model, and the bandgap and band tail width are extracted. For Be-doped GaAs NWs, the bandgap narrowing provides a quantitative determination of the hole concentration ranging from about $1\times 10^{18}$ to $2\times 10^{19}$~cm$^{-3}$, in good agreement with the targeted doping levels. High-resolution maps of the hole concentration demonstrate the homogeneous doping in the pure zinc-blende segment. For Si-doped GaAs NWs, the electron Fermi level and the full-width at half maximum of low-temperature CL spectra are used to assess the electron concentration to approximately $3\times 10^{17}$ to $6\times 10^{17}$~cm$^{-3}$. These findings confirm the difficulty to obtain highly-doped n-type GaAs NWs, maybe due to doping compensation. Notably, signatures of high concentration (5--9$\times 10^{18}$~cm$^{-3}$) at the very top of NWs are unveiled.

Published
2019
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2. Quantitative Assessment of Carrier Density by Cathodoluminescence. I. GaAs thin films and modeling

Author

Chen, Hung-Ling, Scaccabarozzi, Andrea, De Lépinau, Romaric, Oehler, Fabrice, Lemaître, Aristide, Harmand, Jean-Christophe, Cattoni, Andrea, and Collin, Stéphane

Subjects
Condensed Matter - Materials Science, Physics - Optics
Abstract

Doping is a fundamental property of semiconductors and constitutes the basis of modern microelectronic and optoelectronic devices. Their miniaturization requires contactless characterization of doping with nanometer scale resolution. Here, we use low- and room-temperature cathodoluminescence (CL) measurements to analyze p-type and n-type GaAs thin films over a wide range of carrier densities ($2\times 10^{17}$ to $1\times 10^{19}$ cm$^{-3}$). The spectral shift and broadening of CL spectra induced by shallow dopant states and band filling are the signature doping. We fit the whole spectral lineshapes with the generalized Planck's law and refined absorption models to extract the bandgap narrowing (BGN) and the band tail for both doping types, and the electron Fermi level for n doping. This work provides a rigorous method for the quantitative assessment of p-type and n-type carrier density using CL. Taking advantage of the high spatial resolution of CL, it can be used to map the doping in GaAs nanostructures, and it could be extended to other semiconductor materials.

Published
2019
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15. Quantitative Assessment of Carrier Density by Cathodoluminescence (1): GaAs thin films and modeling

Author

Chen, Hung-Ling, Scaccabarozzi, Andrea, de Lépinau, Romaric, Oehler, Fabrice, Lemaître, Aristide, Harmand, Jean-Christophe, Cattoni, Andrea, Collin, Stéphane, Centre de Nanosciences et Nanotechnologies (C2N (UMR_9001)), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), and Institut Photovoltaïque d’Ile-de-France (ITE) (IPVF)

Subjects
[PHYS]Physics [physics], Condensed Matter::Materials Science, [SPI]Engineering Sciences [physics], Condensed Matter::Superconductivity, [PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci], [SPI.OPTI]Engineering Sciences [physics]/Optics / Photonic, Condensed Matter::Strongly Correlated Electrons, [PHYS.COND]Physics [physics]/Condensed Matter [cond-mat], [SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics
Abstract

Supplemental Material; Doping is a fundamental property of semiconductors and constitutes the basis of modern microelectronic and optoelectronic devices. Their miniaturization requires contactless characterization of doping with nanometer scale resolution. Here, we use low- and room-temperature cathodoluminescence (CL) measurements to analyze p-type and n-type GaAs thin films over a wide range of carrier densities ($2\times 10^{17}$ to $1\times 10^{19}$ cm$^{-3}$). The spectral shift and broadening of CL spectra induced by shallow dopant states and band filling are the signature doping. We fit the whole spectral lineshapes with the generalized Planck's law and refined absorption models to extract the bandgap narrowing (BGN) and the band tail for both doping types, and the electron Fermi level for n doping. This work provides a rigorous method for the quantitative assessment of p-type and n-type carrier density using CL. Taking advantage of the high spatial resolution of CL, it can be used to map the doping in GaAs nanostructures, and it could be extended to other semiconductor materials.

Published
2019

17. GaAs/AlGaAs core/shell nanowires on Si substrates for photovoltaics: toward an optimized tandem solar cell

Author

Vettori, Marco, Cattoni, Andrea, Regreny, Philippe, Penuelas, Jose, Chauvin, Nicolas, Chevallier, Céline, Scaccabarozzi, Andrea, Patriarche, Gilles, Maryasin, Vladimir, Kaminski-Cachopo, Anne, Fave, Alain, Gendry, Michel, INL - Hétéroepitaxie et Nanostructures (INL - H&N), Institut des Nanotechnologies de Lyon (INL), École Centrale de Lyon (ECL), Université de Lyon-Université de Lyon-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-École supérieure de Chimie Physique Electronique de Lyon (CPE)-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-École Centrale de Lyon (ECL), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), INL - Photovoltaïque (INL - PV), Laboratoire de photonique et de nanostructures (LPN), Centre National de la Recherche Scientifique (CNRS), INL - Spectroscopies et Nanomatériaux (INL - S&N), INL - Plateforme Technologique Nanolyon (INL - Nanolyon), Institut de Microélectronique, Electromagnétisme et Photonique - Laboratoire d'Hyperfréquences et Caractérisation (IMEP-LAHC ), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), and Gendry, Michel

Subjects
[SPI.NANO] Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, [SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, tandem solar cell, GaAs/AlGaAs NWs, patterned substrates
Abstract

International audience; Since LaPierre's first theorization of a nanowires (NWs)-based tandem solar cell (TSC) on Si substrate, 1 other theoretical studies have been carried out to investigate the high potentialities of such devices, 2 which can virtually reach an efficiency around 34 %. In spite of these very promising results, the research in this field has not yet developed that much on a practical level: to the best of our knowledge only one prototype of TSC has been realized so far by Yao et al, 3 and although not completely optimized, it reached the high conversion efficiency value of 11.4 %. Based on these considerations, we aimed to develop a fully optimized TSC capable to achieve higher efficiencies. 4 This consists in a top cell made of an ordered array of GaAs/AlGaAs core/shell NWs, with a radial p-in junction in the AlGaAs shell, directly grown on a bottom cell of Si(111), as shown in Figure 1(a). The optimization work has been carried out in different steps, i.e. theoretical simulations to identify the best set up for the array, optimization of the NW structure, composition and morphology, investigation for the most suitable passivation shell and growth on patterned substrates. The last point has notably lead to significant results, since we develop a protocol to obtain very high vertical yields (from 80 % to 90 %) of GaAs/AlGaAs core/shell NWs on large patterned areas (0.9 cm x 0.9 cm), as shown in Figure 1(b). Following these promising results, we are currently committed to using our ordered arrays of NWs for the fabrication of a TSC, now focusing our work on encapsulating and contacting the nanostructures: despite the complexity of the system, EBIC results in this respect (cf. V. Piazza's abstract) are encouraging and suggest that the realization of the TSC is at our fingertips. 5 Figure 1. (a) Scheme of the ultimate structure of the TSC. (b) Ordered array of p-GaAs core / p-in AlGaAs shell NWs on Si(111) with a high vertical yield (80-90 %); white scale bar corresponding to 2 µm.

Published
2018

20. Cathodoluminescence Characterization of Semiconductor Doping at the Nanoscale

Author

Chen, Hung-Ling, primary, Scaccabarozzi, Andrea, additional, Lepinau, Romaric De, additional, Himwas, Chalermchai, additional, Rale, Pierre, additional, Oehler, Fabrice, additional, Lemaitre, Aristide, additional, Tchernycheva, Maria, additional, Harmand, Jean-Christophe, additional, Cattoni, Andrea, additional, and Collin, Stephane, additional

Published
2018
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22. Integration of InGaP/GaAs/Ge triple-junction solar cells on deeply patterned silicon substrates

Author

SCACCABAROZZI, ANDREA, BINETTI, SIMONA OLGA, ACCIARRI, MAURIZIO FILIPPO, Isella, G, Campesato, R, Gori, G, Casale, M, Mancarella, F, Noack, M, von Känel, H, MIGLIO, LEONIDA, Scaccabarozzi, A, Binetti, S, Acciarri, M, Isella, G, Campesato, R, Gori, G, Casale, M, Mancarella, F, Noack, M, von Känel, H, and Miglio, L

Subjects
Sustainability and the Environment, Renewable Energy, Sustainability and the Environment, Electronic, Optical and Magnetic Material, monolithic integration, multi-junction solar cells, silicon integration, substrate patterning, Electronic, Optical and Magnetic Materials, Condensed Matter Physics, Electrical and Electronic Engineering, Condensed Matter Physic, multi-junction solar cell, CHIM/02 - CHIMICA FISICA, FIS/01 - FISICA SPERIMENTALE, Electronic, Optical and Magnetic Materials, Renewable Energy, FIS/03 - FISICA DELLA MATERIA
Abstract

We report preliminary results on InGaP/InGaAs/Ge photovoltaic cells for concentrated terrestrial applications, monolithically integrated on engineered Si(001) substrates. Cells deposited on planar Ge/Si(001) epilayers, grown by plasma-enhanced chemical vapor deposition, provide good efficiency and spectral response, despite the small thickness of the Ge epilayers and a threading dislocation density as large as 107/cm2. The presence of microcracks generated by the thermal misfit is compensated by a dense collection grid that avoids insulated areas. In order to avoid the excessive shadowing introduced by the use of a dense grid, the crack density needs to be lowered. Here, we show that deep patterning of the Si substrate in blocks can be an option, provided that a continuous Ge layer is formed at the top, and it is suitably planarized before the metalorganic chemical vapor deposition. The crack density is effectively decreased, despite that the efficiency is also lowered with respect to unpatterned devices. The reasons of this efficiency reduction are discussed, and a strategy for improvement is proposed and explored. Full morphological analysis of the coalesced Ge blocks is reported, and the final devices are tested under concentrated AM1.5D spectrum. Copyright © 2016 John Wiley & Sons, Ltd.

Published
2016
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23. An exceptional thermal strain reduction in Ge suspended layer grown on Si by a tilting pillar architecture

Author

MARZEGALLI, ANNA, BASSO BASSET, FRANCESCO, BONERA, EMILIANO, PEZZOLI, FABIO, SCACCABAROZZI, ANDREA, MIGLIO, LEONIDA, Cortinovis, A, Isa, F, Isella, G, Zaumseil, P, Capellini, G, Schröder, T, Marzegalli, A, Cortinovis, A, BASSO BASSET, F, Bonera, E, Pezzoli, F, Scaccabarozzi, A, Isa, F, Isella, G, Zaumseil, P, Capellini, G, Schröder, T, and Miglio, L

Subjects
Epitaxial growth, Patterning, strain vs. temperature, germanium, FIS/03 - FISICA DELLA MATERIA
Abstract

Our work, focused on the heteroepitaxial Ge/Si (001) system shows that patterned Si substrates in appropriate pillar arrays, featuring micrometric dimensions within the common deep-etching capabilities and array size suitable for several applications (up to few hundreds microns), do provide exceptional compliance to the thermal strain of a continuous Ge film deposited on top. Micro-Raman and XRD measurements on the Ge suspended layer, as obtained by Low Energy Plasma Enhanced Chemical Vapor Deposition, confirm the theoretical predictions. Actually, the sharp onset with pillar aspect ratio of such an effect is demonstrated to be triggered by the free rotation of the pillars, as induced by the thermal contraction of the film. The strain relaxation is deeply analyzed both by FEM simulations and experimental XRD results, showing a very good quantitative agreement. Our findings have far reaching consequences beyond the crystalline heteroepitaxial systems, whenever a film of any microstructure, or composition, is deposited in suspended patches on suitable pillar arrays.

Published
2016

24. Determination of n-Type Doping Level in Single GaAs Nanowires by Cathodoluminescence

Author

Chen, Hung-Ling, primary, Himwas, Chalermchai, additional, Scaccabarozzi, Andrea, additional, Rale, Pierre, additional, Oehler, Fabrice, additional, Lemaître, Aristide, additional, Lombez, Laurent, additional, Guillemoles, Jean-François, additional, Tchernycheva, Maria, additional, Harmand, Jean-Christophe, additional, Cattoni, Andrea, additional, and Collin, Stéphane, additional

Published
2017
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25. Cathodoluminescence mapping for the determination of n-type doping in single GaAs nanowires

Author

Chen, Hung-Ling, primary, Harmand, Jean-Christophe, additional, Cattoni, Andrea, additional, Collin, Stephane, additional, Himwas, Chalermchai, additional, Scaccabarozzi, Andrea, additional, Rale, Pierre, additional, Oehler, Fabrice, additional, Lemaitre, Aristide, additional, Lombez, Laurent, additional, Guillemoles, Jean-Francois, additional, and Tchernycheva, Maria, additional

Published
2017
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26. Exceptional thermal strain reduction by a tilting pillar architecture: Suspended Ge layers on Si (001)

Author

Marzegalli, A, Cortinovis, A, BASSO BASSET, F, Bonera, E, Pezzoli, F, Scaccabarozzi, A, Isa, F, Isella, G, Zaumseil, P, Capellini, G, Schroeder, T, Miglio, L, MARZEGALLI, ANNA, BASSO BASSET, FRANCESCO, BONERA, EMILIANO, PEZZOLI, FABIO, SCACCABAROZZI, ANDREA, MIGLIO, LEONIDA, Marzegalli, A, Cortinovis, A, BASSO BASSET, F, Bonera, E, Pezzoli, F, Scaccabarozzi, A, Isa, F, Isella, G, Zaumseil, P, Capellini, G, Schroeder, T, Miglio, L, MARZEGALLI, ANNA, BASSO BASSET, FRANCESCO, BONERA, EMILIANO, PEZZOLI, FABIO, SCACCABAROZZI, ANDREA, and MIGLIO, LEONIDA

Published
2017

27. Engineered coalescence of three-dimensional Ge microcrystals into high-quality suspended layers on Si pillars

Author

BERGAMASCHINI, ROBERTO, SALVALAGLIO, MARCO, SCACCABAROZZI, ANDREA, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, MIGLIO, LEONIDA, Isa, F, Isella, G, Backofen, A, Voigt, A, Capellini, G, Skibitzki, O, Yamamoto, Y, Schroeder, T, von Känel, H, Bergamaschini, R, Salvalaglio, M, Isa, F, Scaccabarozzi, A, Isella, G, Backofen, A, Voigt, A, Marzegalli, A, Capellini, G, Skibitzki, O, Yamamoto, Y, Schroeder, T, von Känel, H, Montalenti, F, and Miglio, L

Subjects
crystal coalescence, Ge, SI, patterned substrate, surface diffusion, FIS/03 - FISICA DELLA MATERIA, Heteroepitaxy
Abstract

The move from dimensional to functional scaling in microelectronics has recently revamped the interest towards integration of high-quality Ge on Si [1]. However, due to the 4% lattice misfit, this is quite a technological challenge. In ref. [2] we showed the possibility to grow vertically-aligned micrometric Ge crystals, separated by nanometric gaps, on top of Si pillar patterned substrates, without dislocations at the top region. Herein we show by simulation-driven experiments, how these structures can evolve into a suspended Ge film by simply exploiting their temperature-driven coalescence. By closely comparing experimental data and simulation results based on a phase-field model of surface diffusion [3], we demonstrate that the massive morphological evolution is essentially driven by the lowering of surface-curvature gradients. Scanning Tunneling Electron Microscopy (STEM) and High Resolution - Transmission Electron Microscopy (HR-TEM) measurements indicate that the resulting film has very high crystal quality. In particular, dislocations are not observed to nucleate when the crystals start to coalesce, as confirmed by etch-pit analysis. Our approach thus provides a viable path for the integration on Si of Ge layers with very low defect density. [1] R. Pillarisetty, Nature 479, 324 (2011); [2] C.V. Falub et al., Science 335, 1330 (2012); [3] M. Salvalaglio, R. Backofen, R. Bergamaschini, F. Montalenti, A. Voigt, Cryst. Growth Des, in press (doi: 10.1021/acs.cgd.5b00165)

Published
2015

29. An exceptional thermal strain reduction in Ge suspended layer grown on Si by a tilting pillar architecture

Author

Marzegalli, A, Cortinovis, A, BASSO BASSET, F, Bonera, E, Pezzoli, F, Scaccabarozzi, A, Isa, F, Isella, G, Zaumseil, P, Capellini, G, Schröder, T, Miglio, L, MARZEGALLI, ANNA, BASSO BASSET, FRANCESCO, BONERA, EMILIANO, PEZZOLI, FABIO, SCACCABAROZZI, ANDREA, MIGLIO, LEONIDA, Marzegalli, A, Cortinovis, A, BASSO BASSET, F, Bonera, E, Pezzoli, F, Scaccabarozzi, A, Isa, F, Isella, G, Zaumseil, P, Capellini, G, Schröder, T, Miglio, L, MARZEGALLI, ANNA, BASSO BASSET, FRANCESCO, BONERA, EMILIANO, PEZZOLI, FABIO, SCACCABAROZZI, ANDREA, and MIGLIO, LEONIDA

Abstract

Our work, focused on the heteroepitaxial Ge/Si (001) system shows that patterned Si substrates in appropriate pillar arrays, featuring micrometric dimensions within the common deep-etching capabilities and array size suitable for several applications (up to few hundreds microns), do provide exceptional compliance to the thermal strain of a continuous Ge film deposited on top. Micro-Raman and XRD measurements on the Ge suspended layer, as obtained by Low Energy Plasma Enhanced Chemical Vapor Deposition, confirm the theoretical predictions. Actually, the sharp onset with pillar aspect ratio of such an effect is demonstrated to be triggered by the free rotation of the pillars, as induced by the thermal contraction of the film. The strain relaxation is deeply analyzed both by FEM simulations and experimental XRD results, showing a very good quantitative agreement. Our findings have far reaching consequences beyond the crystalline heteroepitaxial systems, whenever a film of any microstructure, or composition, is deposited in suspended patches on suitable pillar arrays.

Published
2016

30. Kinetic growth mode of epitaxial GaAs on Si(001) micro-pillars

Author

Bergamaschini, R, Bietti, S, Castellano, A, Frigeri, C, Falub, C, Scaccabarozzi, A, Bollani, M, Von Känel, H, Miglio, L, Sanguinetti, S, BERGAMASCHINI, ROBERTO, BIETTI, SERGIO, SCACCABAROZZI, ANDREA, MIGLIO, LEONIDA, SANGUINETTI, STEFANO, Bergamaschini, R, Bietti, S, Castellano, A, Frigeri, C, Falub, C, Scaccabarozzi, A, Bollani, M, Von Känel, H, Miglio, L, Sanguinetti, S, BERGAMASCHINI, ROBERTO, BIETTI, SERGIO, SCACCABAROZZI, ANDREA, MIGLIO, LEONIDA, and SANGUINETTI, STEFANO

Abstract

Three-dimensional, epitaxial GaAs crystals are fabricated on micro-pillars patterned into Si(001) substrates by exploiting kinetically controlled growth conditions in Molecular Beam Epitaxy. The evolution of crystal morphology during growth is assessed by considering samples with increasing GaAs deposit thickness. Experimental results are interpreted by a kinetic growth model, which takes into account the fundamental aspects of the growth and mutual deposition flux shielding between neighboring crystals. Different substrate pattern geometries with dissimilar lateral sizes and periodicities of the Si micro-pillars are considered and self-similar crystal structures are recognized. It is demonstrated that the top faceting of the GaAs crystals is tunable, which can pave the way to locally engineer compound semiconductor quantum structures on Si(001) substrates.

Published
2016

31. Integration of InGaP/GaAs/Ge triple-junction solar cells on deeply patterned silicon substrates

Author

Scaccabarozzi, A, Binetti, S, Acciarri, M, Isella, G, Campesato, R, Gori, G, Casale, M, Mancarella, F, Noack, M, von Känel, H, Miglio, L, SCACCABAROZZI, ANDREA, BINETTI, SIMONA OLGA, ACCIARRI, MAURIZIO FILIPPO, MIGLIO, LEONIDA, Scaccabarozzi, A, Binetti, S, Acciarri, M, Isella, G, Campesato, R, Gori, G, Casale, M, Mancarella, F, Noack, M, von Känel, H, Miglio, L, SCACCABAROZZI, ANDREA, BINETTI, SIMONA OLGA, ACCIARRI, MAURIZIO FILIPPO, and MIGLIO, LEONIDA

Abstract

We report preliminary results on InGaP/InGaAs/Ge photovoltaic cells for concentrated terrestrial applications, monolithically integrated on engineered Si(001) substrates. Cells deposited on planar Ge/Si(001) epilayers, grown by plasma-enhanced chemical vapor deposition, provide good efficiency and spectral response, despite the small thickness of the Ge epilayers and a threading dislocation density as large as 107/cm2. The presence of microcracks generated by the thermal misfit is compensated by a dense collection grid that avoids insulated areas. In order to avoid the excessive shadowing introduced by the use of a dense grid, the crack density needs to be lowered. Here, we show that deep patterning of the Si substrate in blocks can be an option, provided that a continuous Ge layer is formed at the top, and it is suitably planarized before the metalorganic chemical vapor deposition. The crack density is effectively decreased, despite that the efficiency is also lowered with respect to unpatterned devices. The reasons of this efficiency reduction are discussed, and a strategy for improvement is proposed and explored. Full morphological analysis of the coalesced Ge blocks is reported, and the final devices are tested under concentrated AM1.5D spectrum. Copyright © 2016 John Wiley & Sons, Ltd.

Published
2016

32. Temperature-controlled coalescence during the growth of Ge crystals on deeply patterned Si substrates

Author

Bergamaschini, R, Salvalaglio, M, Scaccabarozzi, A, Isa, F, Falub, C, Isella, G, Von Känel, H, Montalenti, F, Miglio, L, BERGAMASCHINI, ROBERTO, SALVALAGLIO, MARCO, SCACCABAROZZI, ANDREA, MONTALENTI, FRANCESCO CIMBRO MATTIA, MIGLIO, LEONIDA, Bergamaschini, R, Salvalaglio, M, Scaccabarozzi, A, Isa, F, Falub, C, Isella, G, Von Känel, H, Montalenti, F, Miglio, L, BERGAMASCHINI, ROBERTO, SALVALAGLIO, MARCO, SCACCABAROZZI, ANDREA, MONTALENTI, FRANCESCO CIMBRO MATTIA, and MIGLIO, LEONIDA

Abstract

A method for growing suspended Ge films on micron-sized Si pillars in Si(001) is discussed. In [C.V. Falub et al., Science 335 (2012) 1330] vertically aligned three-dimensional Ge crystals, separated by a few tens of nanometers, were obtained by depositing several micrometers of Ge using Low-Energy Plasma-Enhanced Chemical Vapor Deposition. Here a different regime of high growth temperature is exploited in order to induce the merging of the crystals into a connected structure eventually forming a continuous, two-dimensional film. The mechanisms leading to such a behavior are discussed with the aid of an effective model of crystal growth. Both the effects of deposition and curvature-driven surface diffusion are considered to reproduce the main features of coalescence. The key enabling role of high temperature is identified with the activation of the diffusion process on a time scale competitive with the deposition rate. We demonstrate the versatility of the deposition process, which allows to switch between the formation of individual crystals and a continuous suspended film simply by tuning the growth temperature.

Published
2016

33. Kinetic growth mode of epitaxial GaAs on Si(001) micro-pillars

Author

Bergamaschini, Roberto, primary, Bietti, Sergio, additional, Castellano, Andrea, additional, Frigeri, Cesare, additional, Falub, Claudiu V., additional, Scaccabarozzi, Andrea, additional, Bollani, Monica, additional, von Känel, Hans, additional, Miglio, Leo, additional, and Sanguinetti, Stefano, additional

Published
2016
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35. Size control of GaAs quantum dots grown by droplet epitaxy for device applications

Author

BIETTI, SERGIO, ESPOSITO, LUCA, SCACCABAROZZI, ANDREA, SANGUINETTI, STEFANO, Fedorov, A, Bietti, S, Esposito, L, Scaccabarozzi, A, Fedorov, A, and Sanguinetti, S

Subjects
quantum dot size control, droplet epitaxy: GaAs quantum dot
Abstract

Droplet epitaxy (DE) is a growth technique based on molecular beam epitaxy proposed in 1991 by Dr. N. Koguchi [1]. This method allows for the fabrication of wetting layer free, lattice-matched and strain-free III-V nanostructures self-assembled, reducing the size dispersion between 5 and 20%. Thanks to the separation of the group III and group V atom irradiation on the substrate, it is possible to obtain a fine tuning of the quantum dot (QD) shape and density by simply changing the parameters that control the group III atom diffusion on the surface. It is possible to select a density between 107 and 1011 cm-2 and the aspect ratio of the dots, thus allowing to change the quantum confinement and to tailor the optical and electronic property of the dots to fit the needs of different applications. In this presentation we discuss the main aspects of the growth and characterization of DE nanostructures, together with the advantage of shape control for different applications recently developed. The first application is related to the fabrication of intermediate band solar cells, introducing a layer of quantum dots grown by DE in a standard AlGaAs solar cell. By tuning the size of the QDs it is possible to change the position of the intermediate band, and by tuning the aspect ratio of the QDs the high energy states of the QDs can also be tuned in order to have a small electron-phonon coupling with the barrier. Moreover, the lack of defect and wetting layer states can greatly reduce thermal escape of carriers from the intermediate band, leaving photon-induced transitions the dominant ones, as requested by intermediate band theory [2]. The second application is related to the fabrication of GaAs single photon emitters integrated on Si substrates. Hanbury-Brown-Twiss measurements demonstrates how the single nanostructure is a single photon emitter up to temperature of liquid nitrogen, thus demonstrating how DE makes also possible the growth of bright III-V quantum emitters on silicon substrates and paving the route to the integration of optically efficient III-V nanostructures on CMOS technology [3]. The last application is the growth of ultra high density QDs for the fabrication of quantum dot infrared photodetectors (QDIP) active in the range between 2 and 8 µm, as a first step toward the the fabrication of a III-V based QDIP integrated on Si [4].[1] N.Koguchi, S.Takahashi, T.Chikyow, Journal of Crystal Growth 111, 688 (1991) [2] A.Scaccabarozzi, S.Adorno, S.Bietti, M.Acciarri, S.Sanguinetti, Physica Status Solidi (RRL) - Rapid Research Letters 3, 173, (2013) [3] L.Cavigli, S.Bietti, M.Accanto et al., Applied Physics Letters, 100, 231112, 2012. [4] J.Frigerio, G.Isella, S.Bietti, S.Sanguinetti, SPIE Newsroom, 2013

Published
2014

36. Epitaxial self-assembly of 3-D semiconductor structures on deeply patterned Si substrates at the microscale

Author

MIGLIO, LEONIDA, BERGAMASCHINI, ROBERTO, BIETTI, SERGIO, BONERA, EMILIANO, GRILLI, EMANUELE ENRICO, GUZZI, MARIO, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, PEZZOLI, FABIO, SALVALAGLIO, MARCO, SANGUINETTI, STEFANO, SCACCABAROZZI, ANDREA, Falub, CV, Isa, F, Kreiliger, T, Taboada, AG, Chrastina, D, Frigerio, I, Isella, G, Meduna, M, Wewior, L, Fuster, D, Alen, B, Bollani, M, Dommann, A, Neels, A, Niedermann, P, Frigeri, C, Fompeyrine, J, Richter, M, Uccelli, E, Mancarella, F, von Kanel, H., Miglio, L, Bergamaschini, R, Bietti, S, Bonera, E, Grilli, E, Guzzi, M, Marzegalli, A, Montalenti, F, Pezzoli, F, Salvalaglio, M, Sanguinetti, S, Scaccabarozzi, A, Falub, C, Isa, F, Kreiliger, T, Taboada, A, Chrastina, D, Frigerio, I, Isella, G, Meduna, M, Wewior, L, Fuster, D, Alen, B, Bollani, M, Dommann, A, Neels, A, Niedermann, P, Frigeri, C, Fompeyrine, J, Richter, M, Uccelli, E, Mancarella, F, and von Kanel, H

Subjects
patterning, crystals, FIS/03 - FISICA DELLA MATERIA, heteroepitaxy
Published
2014

37. GaAs/AlGaAs quantum dot intermediate band solar cells

Author

SCACCABAROZZI, ANDREA, Scaccabarozzi, A, and ACCIARRI, MAURIZIO FILIPPO

Subjects
III-V nanostructure, quantum dot, intermediate band solar cell, Photovoltaic, FIS/03 - FISICA DELLA MATERIA, droplet epitaxy
Abstract

This thesis presents my Ph.D. work about quantum dot GaAs/AlGaAs solar cells grown by droplet epitaxy, exploring the potential of this materials system for the realization of intermediate band photovoltaic devices. In the first chapter a general introduction to the field of solar energy is given, outlining the reasons why this research has been performed. The physics of the photovoltaic cell is briefly explained in its most important points, to give the reader clear understanding of what is presented in the following chapters. Intermediate band devices are presented in the second chapter. The theoretical foundations presented do not aim at constituting an exhaustive explanation of the theory underlying intermediate band solar cells, but the scope is again to give clear understanding of the characterization of the quantum dot devices reported in the following chapters. A survey of the state of the art in the field is given, pointing out the differences with our technology. The initial part of my Ph.D. work was spent in developing the technology to design and grow (Al)GaAs photovoltaic devices, as well as the characterization techniques required to understand the behavior of such devices. In chapter 3 the method developed to design the solar cell structure is illustrated, and in chapter 5 the experimental setup used for characterization is presented, along with the measurements on the single junction devices realized during this work. Chapter 4 is dedicated to the description of the growth and fabrication methods used to grow the samples reported here. The development of the fabrication technology proceeded in close contact with the characterizations of the devices, in order to optimize the process. Finally in chapter 6 the results on quantum dot photovoltaic cells are reported: the key working principles of intermediate band devices have been demonstrated with our materials system, and this, to the knowledge of the author, is the first time that strain free quantum dot solar cells are reported of intermediate band behavior. The role of defects in the AlGaAs matrix is explained in connection with both the optical and electrical characterizations presented.

Published
2013

38. GaAs/AlGaAs Quantum Dot Intermediate-band Solar Cell grown by Droplet Epitaxy

Author

SCACCABAROZZI, ANDREA, BIETTI, SERGIO, ACCIARRI, MAURIZIO FILIPPO, SANGUINETTI, STEFANO, Adorno, S, Scaccabarozzi, A, Adorno, S, Bietti, S, Acciarri, M, and Sanguinetti, S

Subjects
III-V solar cell, GaAs quantum dot, intermediate band solar cell, droplet epitaxy
Abstract

Quantum dot intermediate band (IB) solar cells have been proposed in order to increase the efficiency of traditional solar cells and immediately attracted a lot of attention and research since the time they were first proposed [1]. The IB introduces an extension of the absorption coefficient of the semiconductor to lower energies, allowing a more thorough collection of the solar spectrum, via a two-step absorption of low-energy photons. Quantum dot (QD) structures are good candidates for IB solar cells, because their confined energy levels can overlap and form a miniband in dense arrays and the position of these levels and bands can be tuned varying the size and spacing of the QDs. The IB working mechanisms have been demonstrated for InAs QDs in GaAs [2], and a lot of research is devoted to reduce the problems due to strain, and defect nucleation increasing carrier escape [3]. Droplet epitaxy (DE) [4] is a molecular beam epitaxy technique that allows for the growth of quantum dots of materials lattice matched to the barrier and the removal of the wetting layer. DE makes possible to indipendently control density, size and shape of the nanostructures. Densities as high as some 1011 cm-2 per layer have been reported [5] and potentially a large number of layers can be stacked because the system is strain-free, leading to a much higher density of states in the IB than the more conventional Stranski-Krastanov techniques. Since it is a strain-free technique, there are virtually no defects in DE-grown materials, and this is fundamental to have high performance devices. Moreover, DE nanostructures can be grown without the presence of a wetting layer [6], that would introduce unwanted quantum-well-like states in the system. By tuning the size of the QDs it is obviously possible to change the position of the IB, and by tuning their aspect ratio the high energy states of the QDs can also be tuned in order to have a small electron-phonon coupling with the barrier. The lack of defect and wetting layer states can greatly reduce thermal escape of carriers from the IB, leaving photon-induced transitions the dominant ones, as requested by IB theory [1]. For these reasons DE is a good candidate for the realization of QD-IB solar cells. We demonstrate the key working principle of IB materials, that is the production of sub-gap two-photon photocurrent, with Al0.3Ga0.7As solar cells containing GaAs QDs grown by DE (figure 1a). The devices were illuminated at 15K by continuous monochromatic light and chopped broadband IR light (1.5 – 20 m), and the signal was demodulated by a lock-in amplifier. The continuous light pumps electrons into the QDs and the chopped IR promotes them to the CB where they can be collected generating an electric signal. As a control, a reference sample without QDs was grown and measured in the same conditions, but no two-photon signal was detected (see figure 2b). Measurements show that the shape of the two-photon photocurrent signal is different from the VB-CB photoresponse, indicating clearly that a two-photon process involving the QD levels is taking place. The two-photon signal response is in good agreement with the PL spectrum of the QD samples (figure 1b), that lets us easily understand the position of the energy levels of the system. [1] A. Luque, A. Martì, Physical Review Letters, 78, 5014 (1997). [2] A. Martì, E. Antolìn, C. R. Stanley, C. D. Farmer, N. Lòpez, P. Dìaz, E. Cànovas, P. G. Linares and A. Luque, Physical Review Letters 97, 247701 (2006). [3] A. Luque and A. Martì, Prog. Photovolt: Res. Appl. 9, 73-86 (2001) [4] N. Koguchi and K. Ishige, Japanese Journal of Applied Physics 32, 2052–2058 (1993). [5] M. Jo, T. Mano, Y. Sakuma and K. Sakoda, Applied Physics Letters 100, 212113 (2012) [6] S. Sanguinetti, K. Watanabe, T. Tateno, M. Wakaki, N. Koguchi, T. Kuroda, F. Minami, and M. Gurioli, Applied Physics Letters 81, 613 (2002)

Published
2013

39. Quantum Dot Intermediate-band Solar Cell grown by Droplet Epitaxy

Author

SCACCABAROZZI, ANDREA, ADORNO, SILVIA, BIETTI, SERGIO, ACCIARRI, MAURIZIO FILIPPO, SANGUINETTI, STEFANO, Scaccabarozzi, A, Adorno, S, Bietti, S, Acciarri, M, and Sanguinetti, S

Subjects
intermediate band solar cell (IBSC), GaAs quantum dot, droplet epitaxy
Abstract

Quantum dot intermediate band (IB) solar cells have been proposed in order to increase the efficiency of traditional solar cells and immediately attracted a lot of attention and research since the time they were first proposed. The IB introduces an extension of the absorption coefficient of the semiconductor to lower energies, allowing a more thorough collection of the solar spectrum, via a two-step absorption of low-energy photons. Quantum dot (QD) structures are good candidates for IB solar cells, because their confined energy levels can overlap and form a miniband in dense arrays and the position of these levels and bands can be tuned varying the size and spacing of the QDs. The IB working mechanisms have been demonstrated for InAs QDs in GaAs, and many efforts are devoted to reduce the problems due to strain, and defect nucleation increasing carrier escape. Droplet epitaxy (DE) is a molecular beam epitaxy technique that allows for the growth of quantum dots of materials lattice matched to the barrier and the removal of the wetting layer. DE makes possible to indipendently control density, size and shape of the nanostructures. Densities as high as some 1011 cm-2 per layer have been reported and potentially a large number of layers can be stacked because the system is strain-free. Being a strain-free technique, there are virtually no defects in DE-grown materials. By tuning the size of the QDs it is obviously possible to change the position of the IB, and by tuning their aspect ratio the high energy states of the QDs can also be tuned in order to have a small electron-phonon coupling with the barrier. The lack of defect and wetting layer states can greatly reduce thermal escape of carriers from the IB, leaving photon-induced transitions the dominant ones, as requested by IB theory. For these reasons DE is a good candidate for the realization of QD-IB solar cells. We demonstrate the key working principle of IB materials, that is the production of sub-gap two-photon photocurrent, with Al0.3Ga0.7As solar cells containing GaAs QDs grown by DE. Measurements show that the shape of the two-photon photocurrent signal is different from the VB-CB photoresponse, indicating clearly that a two-photon process involving the QD levels is taking place. The two-photon signal response is in good agreement with the PL spectrum of the QD samples, that lets us easily understand the position of the energy levels of the system.

Published
2013

40. Evidence of two-photon absorption in strain-free quantum dot GaAs/AlGaAs solar cells

Author

SCACCABAROZZI, ANDREA, ADORNO, SILVIA, BIETTI, SERGIO, ACCIARRI, MAURIZIO FILIPPO, SANGUINETTI, STEFANO, Scaccabarozzi, A, Adorno, S, Bietti, S, Acciarri, M, and Sanguinetti, S

Subjects
photovoltaics, GaAs, Molecular Beam Epitaxy, quantum nanostructures, FIS/03 - FISICA DELLA MATERIA
Abstract

We report the fabrication procedure and the characterization of an Al0.3Ga0.7As solar cell containing high-density GaAs strain-free quantum dots grown by droplet epitaxy. The production of photocurrent when two sub-bandgap energy photons are absorbed simultaneously is demonstrated. The high quality of the quantum dot/barrier pair, allowed by the high quality of nanostructured strain-free materials, opens new opportunities for quantum dot based solar cells. Left: Scheme of the fabricated quantum dot solar cell. Right: 1 × 1 μm2 image of the dot layer. Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Published
2013

41. 3D heteroepitaxy on patterned Si substrates: a new monolithic integration strategy

Author

SANGUINETTI, STEFANO, BERGAMASCHINI, ROBERTO, BIETTI, SERGIO, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, PEZZOLI, FABIO, SCACCABAROZZI, ANDREA, MIGLIO, LEONIDA, Isa, F, Isella, G, Frigeri, C, Falub, CV, von Kaenel, H, Sanguinetti, S, Bergamaschini, R, Bietti, S, Isa, F, Isella, G, Marzegalli, A, Frigeri, C, Montalenti, F, Pezzoli, F, Scaccabarozzi, A, Falub, C, von Kaenel, H, and Miglio, L

Subjects
molecular beam epitaxy, deep substrate patterning, threading dislocations, III-V integration on Si
Abstract

We have recently shown that crystal defects and internal stresses commonly hampering Ge heteroepitaxy on Si can be greatly reduced by promoting the nucleation of micro-crystals at the top of Si pillars deeply patterned on the substrate [1]. Ge-on-Si epitaxy by low-energy plasma-enhanced CVD (LEPECVD), allows for controlling the microcrystal faceting, in turn affecting the evolution of threading dislocations and providing complete expulsion of threading arms to the microcrystal sidewalls [2]. In addition, the microcrystals are self-assembled in dense arrays, with a spacing ranging from tens to one hundred nanometers. The growth mechanism of the micro-crystals is an intriguing “nano” effect, which has been interpreted in terms of independent facet growth. This effect is not a unique feature of Ge deposition by LEPECVD, but a more general growth mode, which can be extended to other materials systems and deposition techniques. GaAs microcrystals deposited by MBE on patterned Si substrates show as well the complete tessellation of the surface by closely separated microcrystals. The complete elimination of thermal strain and reduction of threading dislocations is confirmed by the high photoluminescence yield. [1] C. V Falub et al. Science 2012, 335, 1330–4 ; [2] A. Marzegalli et al., Advanced materials 2013, 25, 4408

Published
2013

42. Monolithic integration of GaAs on deeply patterned Si substrates by self-assembled arrays of three-dimensional microcrystals

Author

MIGLIO, LEONIDA, BIETTI, SERGIO, SCACCABAROZZI, ANDREA, BERGAMASCHINI, ROBERTO, BONERA, EMILIANO, SANGUINETTI, STEFANO, Frigeri, C, Isella, G, Isa, F, Falub, CV, Bollani, M, Niedermann, P, von Kanel, H, Miglio, L, Bietti, S, Scaccabarozzi, A, Bergamaschini, R, Frigeri, C, Isella, G, Isa, F, Falub, C, Bonera, E, Bollani, M, Niedermann, P, von Kanel, H, and Sanguinetti, S

Subjects
patterning, crystals, GaA, Si, FIS/03 - FISICA DELLA MATERIA
Published
2013

43. Thermal and UV Hydrosilylation of Alcohol-Based Bifunctional Alkynes on Si (111) surfaces: How surface radicals influence surface bond formation

Author

Khung, Y, Ngalim, S, Scaccabarozzi, A, Narducci, D, KHUNG, YIT LUNG, SCACCABAROZZI, ANDREA, NARDUCCI, DARIO, Ngalim, SH, Khung, Y, Ngalim, S, Scaccabarozzi, A, Narducci, D, KHUNG, YIT LUNG, SCACCABAROZZI, ANDREA, NARDUCCI, DARIO, and Ngalim, SH

Abstract

Using two different hydrosilylation methods, low temperature thermal and UV initiation, silicon (111) hydrogenated surfaces were functionalized in presence of an OH-terminated alkyne, a CF 3 -terminated alkyne and a mixed equimolar ratio of the two alkynes. XPS studies revealed that in the absence of premeditated surface radical through low temperature hydrosilylation, the surface grafting proceeded to form a Si-O-C linkage via nucleophilic reaction through the OH group of the alkyne. This led to a small increase in surface roughness as well as an increase in hydrophobicity and this effect was attributed to the surficial etching of silicon to form nanosize pores (∼1-3 nm) by residual water/oxygen as a result of changes to surface polarity from the grafting. Furthermore in the radical-free thermal environment, a mix in equimolar of these two short alkynes can achieve a high contact angle of ∼102°, comparable to long alkyl chains grafting reported in literature although surface roughness was relatively mild (rms = ∼1 nm). On the other hand, UV initiation on silicon totally reversed the chemical linkages to predominantly Si-C without further compromising the surface roughness, highlighting the importance of surface radicals determining the reactivity of the silicon surface to the selected alkynes.

Published
2015

44. Engineered Coalescence by Annealing 3D Ge Microstructures into High-Quality Suspended Layers on Si

Author

Salvalaglio, M, Bergamaschini, R, Isa, F, Scaccabarozzi, A, Isella, G, Backofen, R, Voigt, A, Montalenti, F, Capellini, G, Schroeder, T, Von Känel, H, Miglio, L, SALVALAGLIO, MARCO, BERGAMASCHINI, ROBERTO, SCACCABAROZZI, ANDREA, MONTALENTI, FRANCESCO CIMBRO MATTIA, MIGLIO, LEONIDA, Salvalaglio, M, Bergamaschini, R, Isa, F, Scaccabarozzi, A, Isella, G, Backofen, R, Voigt, A, Montalenti, F, Capellini, G, Schroeder, T, Von Känel, H, Miglio, L, SALVALAGLIO, MARCO, BERGAMASCHINI, ROBERTO, SCACCABAROZZI, ANDREA, MONTALENTI, FRANCESCO CIMBRO MATTIA, and MIGLIO, LEONIDA

Abstract

The move from dimensional to functional scaling in microelectronics has led to renewed interest toward integration of Ge on Si. In this work, simulation-driven experiments leading to high-quality suspended Ge films on Si pillars are reported. Starting from an array of micrometric Ge crystals, the film is obtained by exploiting their temperature-driven coalescence across nanometric gaps. The merging process is simulated by means of a suitable surface-diffusion model within a phase-field approach. The successful comparison between experimental and simulated data demonstrates that the morphological evolution is driven purely by the lowering of surface-curvature gradients. This allows for fine control over the final morphology to be attained. At fixed annealing time and temperature, perfectly merged films are obtained from Ge crystals grown at low temperature (450 °C), whereas some void regions still persist for crystals grown at higher temperature (500 °C) due to their different initial morphology. The latter condition, however, looks very promising for possible applications. Indeed, scanning tunneling electron microscopy and high-resolution transmission electron microscopy analyses show that, at least during the first stages of merging, the developing film is free from threading dislocations. The present findings, thus, introduce a promising path to integrate Ge layers on Si with a low dislocation density.

Published
2015

45. Formation of stable Si-O-C submonolayers on hydrogenterminated silicon(111) under low-temperature conditions

Author

Khung, Y, Ngalim, S, Scaccabarozzi, A, Narducci, D, KHUNG, YIT LUNG, SCACCABAROZZI, ANDREA, NARDUCCI, DARIO, Ngalim, SH, Khung, Y, Ngalim, S, Scaccabarozzi, A, Narducci, D, KHUNG, YIT LUNG, SCACCABAROZZI, ANDREA, NARDUCCI, DARIO, and Ngalim, SH

Abstract

In this letter, we report results of a hydrosilylation carried out on bifunctional molecules by using two different approaches, namely through thermal treatment and photochemical treatment through UV irradiation. Previously, our group also demonstrated that in a mixed alkyne/alcohol solution, surface coupling is biased towards the formation of Si-O-C linkages instead of Si-C linkages, thus indirectly supporting the kinetic model of hydrogen abstraction from the Si-H surface (Khung, Y. L. et al. Chem. - Eur. J. 2014, 20, 15151-15158). To further examine the probability of this kinetic model we compare the results from reactions with bifunctional alkynes carried out under thermal treatment (<130°C) and under UV irradiation, respectively. X-ray photoelectron spectroscopy and contact angle measurements showed that under thermal conditions, the Si-H surface predominately reacts to form Si-O-C bonds from ethynylbenzyl alcohol solution while the UV photochemical route ensures that the alcohol-based alkyne may also form Si-C bonds, thus producing a monolayer of mixed linkages. The results suggested the importance of surface radicals as well as the type of terminal group as being essential towards directing the nature of surface linkage.

Published
2015

46. Engineered coalescence of three-dimensional Ge microcrystals into high-quality suspended layers on Si pillars

Author

Bergamaschini, R, Salvalaglio, M, Isa, F, Scaccabarozzi, A, Isella, G, Backofen, A, Voigt, A, Marzegalli, A, Capellini, G, Skibitzki, O, Yamamoto, Y, Schroeder, T, von Känel, H, Montalenti, F, Miglio, L, BERGAMASCHINI, ROBERTO, SALVALAGLIO, MARCO, SCACCABAROZZI, ANDREA, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, MIGLIO, LEONIDA, Bergamaschini, R, Salvalaglio, M, Isa, F, Scaccabarozzi, A, Isella, G, Backofen, A, Voigt, A, Marzegalli, A, Capellini, G, Skibitzki, O, Yamamoto, Y, Schroeder, T, von Känel, H, Montalenti, F, Miglio, L, BERGAMASCHINI, ROBERTO, SALVALAGLIO, MARCO, SCACCABAROZZI, ANDREA, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, and MIGLIO, LEONIDA

Abstract

The move from dimensional to functional scaling in microelectronics has recently revamped the interest towards integration of high-quality Ge on Si [1]. However, due to the 4% lattice misfit, this is quite a technological challenge. In ref. [2] we showed the possibility to grow vertically-aligned micrometric Ge crystals, separated by nanometric gaps, on top of Si pillar patterned substrates, without dislocations at the top region. Herein we show by simulation-driven experiments, how these structures can evolve into a suspended Ge film by simply exploiting their temperature-driven coalescence. By closely comparing experimental data and simulation results based on a phase-field model of surface diffusion [3], we demonstrate that the massive morphological evolution is essentially driven by the lowering of surface-curvature gradients. Scanning Tunneling Electron Microscopy (STEM) and High Resolution - Transmission Electron Microscopy (HR-TEM) measurements indicate that the resulting film has very high crystal quality. In particular, dislocations are not observed to nucleate when the crystals start to coalesce, as confirmed by etch-pit analysis. Our approach thus provides a viable path for the integration on Si of Ge layers with very low defect density. [1] R. Pillarisetty, Nature 479, 324 (2011); [2] C.V. Falub et al., Science 335, 1330 (2012); [3] M. Salvalaglio, R. Backofen, R. Bergamaschini, F. Montalenti, A. Voigt, Cryst. Growth Des, in press (doi: 10.1021/acs.cgd.5b00165)

Published
2015

47. Engineered Coalescence by Annealing 3D Ge Microstructures into High-Quality Suspended Layers on Si

Author

Salvalaglio, Marco, primary, Bergamaschini, Roberto, additional, Isa, Fabio, additional, Scaccabarozzi, Andrea, additional, Isella, Giovanni, additional, Backofen, Rainer, additional, Voigt, Axel, additional, Montalenti, Francesco, additional, Capellini, Giovanni, additional, Schroeder, Thomas, additional, von Känel, Hans, additional, and Miglio, Leo, additional

Published
2015
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50. A Structural Characterization of GaAs MBE Grown on Si Pillars

Author

Frigeri, C, Bietti, S, Scaccabarozzi, A, Bergamaschini, R, Falub, C, Grillo, V, Bollani, M, Bonera, E, Niedermann, P, von Känel, H, Sanguinetti, S, Miglio, L, BIETTI, SERGIO, SCACCABAROZZI, ANDREA, BERGAMASCHINI, ROBERTO, BONERA, EMILIANO, SANGUINETTI, STEFANO, MIGLIO, LEONIDA, Frigeri, C, Bietti, S, Scaccabarozzi, A, Bergamaschini, R, Falub, C, Grillo, V, Bollani, M, Bonera, E, Niedermann, P, von Känel, H, Sanguinetti, S, Miglio, L, BIETTI, SERGIO, SCACCABAROZZI, ANDREA, BERGAMASCHINI, ROBERTO, BONERA, EMILIANO, SANGUINETTI, STEFANO, and MIGLIO, LEONIDA

Published
2014

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