Structural Properties and Energy Spectrum of Novel GaSb/AlP Self-Assembled Quantum Dots

In this work, the formation, structural properties, and energy spectrum of novel self-assembled GaSb/AlP quantum dots (SAQDs) were studied by experimental methods. The growth conditions for the SAQDs’ formation by molecular beam epitaxy on both matched GaP and artificial GaP/Si substrates were determined. An almost complete plastic relaxation of the elastic strain in SAQDs was reached. The strain relaxation in the SAQDs on the GaP/Si substrates does not lead to a reduction in the SAQDs luminescence efficiency, while the introduction of dislocations into SAQDs on the GaP substrates induced a strong quenching of SAQDs luminescence. Probably, this difference is caused by the introduction of Lomer 90°-dislocations without uncompensated atomic bonds in GaP/Si-based SAQDs, while threading 60°-dislocations are introduced into GaP-based SAQDs. It was shown that GaP/Si-based SAQDs have an energy spectrum of type II with an indirect bandgap and the ground electronic state belonging to the X-valley of the AlP conduction band. The hole localization energy in these SAQDs was estimated equal to 1.65–1.70 eV. This fact allows us to predict the charge storage time in the SAQDs to be as long as >>10 years, and it makes GaSb/AlP SAQDs promising objects for creating universal memory cells.

[1]  L. Guo,et al.  Monolithically Integrating III‐Nitride Quantum Structure for Full‐Spectrum White LED via Bandgap Engineering Heteroepitaxial Growth , 2023, Laser & Photonics Reviews.

[2]  V. Atuchin,et al.  Dislocation Filter Based on LT-GaAs Layers for Monolithic GaAs/Si Integration , 2022, Nanomaterials.

[3]  T. Walther Role of Interdiffusion and Segregation during the Life of Indium Gallium Arsenide Quantum Dots, from Cradle to Grave , 2022, Nanomaterials.

[4]  V. Atuchin,et al.  Novel InGaSb/AlP Quantum Dots for Non-Volatile Memories , 2022, Nanomaterials.

[5]  Lianshan Wang,et al.  Anisotropic Strain Relaxation in Semipolar (112¯2) InGaN/GaN Superlattice Relaxed Templates , 2022, Nanomaterials.

[6]  A. Dvurechenskii,et al.  Light-Trapping-Enhanced Photodetection in Ge/Si Quantum Dot Photodiodes Containing Microhole Arrays with Different Hole Depths , 2022, Nanomaterials.

[7]  Tianchun Ye,et al.  Monolithic Integration of O-Band InAs Quantum Dot Lasers with Engineered GaAs Virtual Substrate Based on Silicon , 2022, Nanomaterials.

[8]  D. Mitin,et al.  Light-Emitting Diodes Based on InGaN/GaN Nanowires on Microsphere-Lithography-Patterned Si Substrates , 2022, Nanomaterials.

[9]  S. Reitzenstein,et al.  Triggered Single‐Photon Emission of Resonantly Excited Quantum Dots Grown on (111)B GaAs Substrate , 2022, physica status solidi (RRL) – Rapid Research Letters.

[10]  Zehong Wan,et al.  InGaN quantum well with gradually varying indium content for high-efficiency GaN-based green light-emitting diodes. , 2022, Optics letters.

[11]  Guilei Wang,et al.  Review of Highly Mismatched III-V Heteroepitaxy Growth on (001) Silicon , 2022, Nanomaterials.

[12]  T. Malin,et al.  Modification of the surface energy and morphology of GaN monolayers on the AlN surface in an ammonia flow , 2022, Applied Physics Letters.

[13]  Shengjun Zhou,et al.  Rational construction of staggered InGaN quantum wells for efficient yellow light-emitting diodes , 2021 .

[14]  Siyuan Yu,et al.  Wafer-Scale Epitaxial Low Density InAs/GaAs Quantum Dot for Single Photon Emitter in Three-Inch Substrate , 2021, Nanomaterials.

[15]  K. Jeong,et al.  Optical characteristics of type-II hexagonal-shaped GaSb quantum dots on GaAs synthesized using nanowire self-growth mechanism from Ga metal droplet , 2021, Scientific Reports.

[16]  Y. Okada,et al.  Temperature Dependence of Carrier Extraction Processes in GaSb/AlGaAs Quantum Nanostructure Intermediate-Band Solar Cells , 2021, Nanomaterials.

[17]  L. Guo,et al.  Boosted ultraviolet electroluminescence of InGaN/AlGaN quantum structures grown on high-index contrast patterned sapphire with silica array , 2020 .

[18]  D. Bimberg,et al.  Novel Quantum Dot Based Memories with Many Days of Storage Time : Last Steps towards the Holy Grail? , 2019, 2019 19th Non-Volatile Memory Technology Symposium (NVMTS).

[19]  Shengjun Zhou,et al.  High-power and reliable GaN-based vertical light-emitting diodes on 4-inch silicon substrate. , 2019, Optics express.

[20]  V. Preobrazhenskii,et al.  GaAs/GaP Quantum-Well Heterostructures Grown on Si Substrates , 2019, Semiconductors.

[21]  A. Marshall,et al.  Room-temperature Operation of Low-voltage, Non-volatile, Compound-semiconductor Memory Cells , 2019, Scientific Reports.

[22]  A. Strittmatter,et al.  MOVPE‐Growth of InGaSb/AlP/GaP(001) Quantum Dots for Nanoscale Memory Applications , 2018, physica status solidi (b).

[23]  D. Bimberg,et al.  Transparency Engineering in Quantum Dot‐Based Memories , 2018 .

[24]  W. Masselink,et al.  Transport properties of doped AlP for the development of conductive AlP/GaP distributed Bragg reflectors and their integration into light-emitting diodes , 2018 .

[25]  A. Gutakovskii,et al.  Heterostructures with diffused interfaces: Luminescent technique for ascertainment of band alignment type , 2018 .

[26]  D. Ritchie,et al.  Quantum Engineering of InAs/GaAs Quantum Dot Based Intermediate Band Solar Cells , 2017 .

[27]  Zhiming M. Wang,et al.  InGaAs and GaAs quantum dot solar cells grown by droplet epitaxy , 2017 .

[28]  R. Bergamaschini,et al.  Modeling the competition between elastic and plastic relaxation in semiconductor heteroepitaxy: From cyclic growth to flat films , 2016 .

[29]  M. Lehmann,et al.  Growth and structure of In0.5Ga0.5Sb quantum dots on GaP(001) , 2016 .

[30]  P. Ruterana,et al.  Hole localization energy of 1.18 eV in GaSb quantum dots embedded in GaP , 2016 .

[31]  A. Bakarov,et al.  Quantum dots formed in InSb/AlAs and AlSb/AlAs heterostructures , 2016 .

[32]  F. Ponce,et al.  Improved optical properties of InAs quantum dots for intermediate band solar cells by suppression of misfit strain relaxation , 2016 .

[33]  P. Jin,et al.  Self-assembly of InAs quantum dots on GaAs(001) by molecular beam epitaxy , 2015 .

[34]  A. Strittmatter,et al.  230 s room-temperature storage time and 1.14 eV hole localization energy in In0.5Ga0.5As quantum dots on a GaAs interlayer in GaP with an AlP barrier , 2015 .

[35]  I. S. Han,et al.  Optical and electrical properties of InAs/GaAs quantum-dot solar cells , 2014 .

[36]  A. Gutakovskii,et al.  Coexistence of type-I and type-II band alignment in Ga(Sb, P)/GaP heterostructures with pseudomorphic self-assembled quantum dots , 2014 .

[37]  A. Schliwa,et al.  The structural, electronic and optical properties of GaSb/GaAs nanostructures for charge-based memory , 2013 .

[38]  Yong-Hoon Cho,et al.  Simple analysis method for determining internal quantum efficiency and relative recombination ratios in light emitting diodes , 2013 .

[39]  D. Huffaker,et al.  800 meV localization energy in GaSb/GaAs/Al0.3Ga0.7As quantum dots , 2013 .

[40]  D. Bimberg,et al.  Materials for future quantum dot-based memories , 2013 .

[41]  M. A. Putyato,et al.  New system of self-assembled GaSb/GaP quantum dots , 2012 .

[42]  H. Eisele,et al.  Growth of In0.25Ga0.75As quantum dots on GaP utilizing a GaAs interlayer , 2012 .

[43]  V. Strelchuk,et al.  Atomic structure and energy spectrum of Ga(As,P)/GaP heterostructures , 2012 .

[44]  M. Putyato,et al.  Novel self-assembled quantum dots in the GaSb/AlAs heterosystem , 2012 .

[45]  A. Schliwa,et al.  Linking structural and electronic properties of high-purity self-assembled GaSb/GaAs quantum dots , 2012 .

[46]  I. Kamiya,et al.  RHEED transients during InAs quantum dot growth by MBE , 2012 .

[47]  O. Madelung Semiconductors - Basic Data , 2012 .

[48]  Yu. B. Bolkhovityanov,et al.  Mechanisms of edge-dislocation formation in strained films of zinc blende and diamond cubic semiconductors epitaxially grown on (001)-oriented substrates , 2011 .

[49]  A. Gutakovskii,et al.  Specific features of formation and propagation of 60° and 90° misfit dislocations in GexSi1−x/Si films with x>0.4 , 2010 .

[50]  M. Pessa,et al.  Dislocation-induced electron and hole levels in InAs quantum-dot Schottky diodes , 2010 .

[51]  A. Gutakovskii,et al.  High quality relaxed GaAs quantum dots in GaP matrix , 2010 .

[52]  V. Consonni,et al.  In situ analysis of strain relaxation during catalyst-free nucleation and growth of GaN nanowires , 2010, Nanotechnology.

[53]  A. Gutakovskii,et al.  Heteroepitaxy of GexSi1 − x (x ∼ 0.4–0.5) films on Si(001) substrates misoriented to (111): Formation of short edge misfit dislocations alone in the misorientation direction , 2010 .

[54]  D. Bimberg,et al.  The QD-Flash: a quantum dot-based memory device , 2010 .

[55]  D. Bimberg,et al.  Hole-based memory operation in an InAs/GaAs quantum dot heterostructure , 2009 .

[56]  V. Preobrazhenskii,et al.  A valved cracking phosphorus beam source using InP thermal decomposition and its application to MBE growth , 2009 .

[57]  A. Gutakovskii,et al.  Formation of edge misfit dislocations in Gexsi1-x (x∼0.4-0.5) films grown on misoriented (001 ) -> (111) Si substrates , 2008 .

[58]  P. Vogl,et al.  nextnano: General Purpose 3-D Simulations , 2007, IEEE Transactions on Electron Devices.

[59]  A. Feltrin,et al.  RHEED metrology of Stranski–Krastanov quantum dots , 2007 .

[60]  A. Marent,et al.  Hole capture into self-organized InGaAs quantum dots , 2006 .

[61]  R. Chau,et al.  Opportunities and challenges of III-V nanoelectronics for future high-speed, low-power logic applications , 2005, IEEE Compound Semiconductor Integrated Circuit Symposium, 2005. CSIC '05..

[62]  Jeffrey N. Stirman,et al.  Atomic-scale imaging of asymmetric Lomer dislocation cores at the Ge/Si(001) heterointerface , 2004 .

[63]  V. Preobrazhenskii,et al.  Measurements of parameters of the low-temperature molecular-beam epitaxy of GaAs , 2002 .

[64]  Y. Oishi,et al.  Epitaxial growth and structural characterization of AlAs/AlP superlattices , 2001 .

[65]  Jerry R. Meyer,et al.  Band parameters for III–V compound semiconductors and their alloys , 2001 .

[66]  O. Pchelyakov,et al.  Surface structure transitions on (0 0 1) GaAs during MBE , 1999 .

[67]  Huajian Gao,et al.  Strain relaxation and defect formation in heteroepitaxial Si1−xGex films via surface roughening induced by controlled annealing experiments , 1997 .

[68]  Ivanov,et al.  Radiative states in type-II GaSb/GaAs quantum wells. , 1995, Physical review. B, Condensed matter.

[69]  Mattias Hammar,et al.  Relaxation mechanism of Ge islands/Si(001) at low temperature , 1995 .

[70]  N. Ledentsov,et al.  RADIATIVE RECOMBINATION IN TYPE-II GASB/GAAS QUANTUM DOTS , 1995 .

[71]  Sander,et al.  Effect of strain on surface morphology in highly strained InGaAs films. , 1991, Physical review letters.

[72]  Van de Walle CG Band lineups and deformation potentials in the model-solid theory. , 1989, Physical review. B, Condensed matter.