Quantum Dots. Optical and Photoelectrical properties of QD of III-V Compounds.

1. Saint-Petersburg State University Quantum Dots. Optical and Photoelectrical properties of QD of III-V Compounds. Alexander Senichev Physics Faculty Department of Solid State Physics senichev_spb@mail.ru 8-921-5769793

2. Contents • Introduction • Technology of Quantum Dots Formation • Dependence of quantum-dots morphology from growth conditions • Optical and photoelectrical properties of QDs • Conclusion

3. Introduction • If the size of semiconductor crystal is reduced to tens or hundreds of inter-atomic spacing, all major properties of material change because of size quantization effects.

4. Introduction Quantum Well Quantum Dots • The extreme case of size quantization is realized in semiconductor structures with confinement of carriers in three directions – they are Quantum Dots.

5. а) E b ) E с) E d ) E Introduction • Generally, electronic spectrum of the ideal quantum dots is a set of discrete levels. Qualitative behavior of Density of States in: a) Bulk semiconductor b) Quantum Wells c) Quantum Wires d) Quantum Dots

6. Device application of QDs • Lasers with active area based on QDs • Light-Emitting Device (LED) based on QDs • Quantum Dots Solar Cells

7. Technology of QDs Formation • The base of technologies of QDs formation is self-organizing phenomenon. • There are three types of initial stage of epitaxial growth: • 2D growth of material A on surface of substrate B ; (Frank-van der Merve) • 3D growth of material A on surface of substrate B ( Volmer-Weber method); • Intermediate mode of growth – the Stranski-Krastanow mode. 2D growth 3D growth Stranski-Krastanow

8. Technology of QDs Formation • Molecular Beam Epitaxy (MBE) • MBE may be defined as the deposition of epitaxial films onto single crystal substrates using atomic or molecular beams. • MBE involves elementary processes: • Adsorption of atoms and molecules; • Thermal desorption; • 3) Diffusion of adatoms on surface • of substrate; • 4) Nucleation; 1 2 4 3 Solid substrate

9. Technology of QDs Formation • Molecular Beam Epitaxy (MBE) • MBE system consist of: • a growth chamber • a vacuum pump • a effusion (Knudsen) cells • a manipulator and substrate heater • an in-situ characterization tool – RHEED (reflection high energy electron diffraction) The typical rate of MBE growth is about 1 ML/s.

10. Technology of QDs Formation • Molecular Beam Epitaxy (MBE) • The oscillation of the RHEED signal exactly corresponds to the time needed to grown a monolayer. The diffraction pattern on the RHEED windows gives direct indication of the state of the surface.

11. Technology of QDs Formation • Metal organic chemical vapor deposition (MOCVD) • Metal organic chemical vapor deposition is a technique used to deposit layers of materials by vapor deposition process. • MOCVD system contains: • the gas handling system to meter and mix reagents • the reactor • the pressure control system • the exhaust facilities

12. Technology of QDs Formation • Metal organic chemical vapor deposition (MOCVD) • The basic chemistry equation of this reaction is as follows: • Group III sources are trimetilgallium (TMGa), TMAl, TMIn. • Group V sources are typically hydride gases such as arsine, phosphine. • Growth rate and composition is controlled by partial pressures of the species and by substrate temperature

13. Dependence of QDs morphology on growth conditions • The basic control parameters in the case of MBE growth: • the substrate temperature; • the growth rate; • the quantity InAs, ratios of III/V materials; • Exposure time in As stream; • As research shows, morphology of QDs ensembles strongly depends on temperature of substrate and growth rate.

14. Dependence of QDs morphology on growth conditions

15. Optical properties of QDs • Photoluminescence spectra of various ensembles of QDs:

16. Optical properties of QDs • The major processes which explain the temperature behavior of QDs PL-spectra: • Thermal quenching of photoluminescence Thermal quenching is explained by thermal escape of carriers from QD into the barrier (or wetting layer) • “Red shifting” As experiment shows, at the temperature, when thermal quenching begins, we can see a following change: the maximum of PL line is shifting in the “red region”.Such behavior of PL spectrum is explained by thermal quenching of carriers and their redistribution between small and large QDs.

17. Optical properties of QDs • Thermal broadening of PL-spectrum. The one of the major factors which defines PL-line width is size dispersion of QDs, i.e. statistic disregistry in ensembles of QDs.Other process which affects on PL-line width is the electron-phonon interaction. • Tunnel processes Tunneling of carriers between QDs competes with escape of carriers from QDs in all temperature range. Probability of tunneling increases with temperature growth. Tunneling processes can affect on high-temperature component of photoluminescence spectrum.

18. Photoelectrical properties of QDs Photoluminescence spectra at 10 K as a function of bias excited at (a) 1.959 eV above the GaAs band gap, (b) 1.445 eV resonant with the wetting layer, and (c) 1.303 eV resonant with the second dot excited state. Schematic excitation, carrier loss, and recombination processes are indicated for the three cases. Photocurrent spectra as a function of bias at 10 K. Quantum-dot features are observed for biases between -3 and -6 V. The inset shows photocurrent from two-dimensional wetting-layer transition, observed to its full intensity at biases of only ~ -0.5 V.

19. Quantum Dots. Optical and Photoelectrical properties of QD of III-V Compounds. Alexander Senichev Physics Faculty Department of Solid State Physics senichev_spb@mail.ru Thank you for your attention!