Your search keyword '"Moskalenko, Evgenii"' showing total 15 results

1. Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field

Author

Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots (QDs) in the presence of an applied external magnetic field is presented. Attention is focused on the redistribution between the spectral lines of a single QD observed at increasing magnetic field parallel to the growth direction (Faraday geometry). The redistribution effect is explained by considering the electron drift velocity in the QD plane that affects the probability for capture into the QD. In contrast, no redistribution is observed when applying the magnetic field perpendicular to the growth direction (Voigt geometry)., Original Publication: Evgenii Moskalenko, Andréas Larsson, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field, 2008, Physical Review B Condensed Matter, (78), 075306. http://dx.doi.org/10.1103/PhysRevB.78.075306 Copyright: American Physical Society http://www.aps.org

Published

2008

2. Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field

Author

Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots (QDs) in the presence of an applied external magnetic field is presented. Attention is focused on the redistribution between the spectral lines of a single QD observed at increasing magnetic field parallel to the growth direction (Faraday geometry). The redistribution effect is explained by considering the electron drift velocity in the QD plane that affects the probability for capture into the QD. In contrast, no redistribution is observed when applying the magnetic field perpendicular to the growth direction (Voigt geometry)., Original Publication: Evgenii Moskalenko, Andréas Larsson, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field, 2008, Physical Review B Condensed Matter, (78), 075306. http://dx.doi.org/10.1103/PhysRevB.78.075306 Copyright: American Physical Society http://www.aps.org

Published

2008

3. Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field

Author

Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots (QDs) in the presence of an applied external magnetic field is presented. Attention is focused on the redistribution between the spectral lines of a single QD observed at increasing magnetic field parallel to the growth direction (Faraday geometry). The redistribution effect is explained by considering the electron drift velocity in the QD plane that affects the probability for capture into the QD. In contrast, no redistribution is observed when applying the magnetic field perpendicular to the growth direction (Voigt geometry)., Original Publication: Evgenii Moskalenko, Andréas Larsson, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field, 2008, Physical Review B Condensed Matter, (78), 075306. http://dx.doi.org/10.1103/PhysRevB.78.075306 Copyright: American Physical Society http://www.aps.org

Published

2008

4. Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field

Author

Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots (QDs) in the presence of an applied external magnetic field is presented. Attention is focused on the redistribution between the spectral lines of a single QD observed at increasing magnetic field parallel to the growth direction (Faraday geometry). The redistribution effect is explained by considering the electron drift velocity in the QD plane that affects the probability for capture into the QD. In contrast, no redistribution is observed when applying the magnetic field perpendicular to the growth direction (Voigt geometry)., Original Publication: Evgenii Moskalenko, Andréas Larsson, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field, 2008, Physical Review B Condensed Matter, (78), 075306. http://dx.doi.org/10.1103/PhysRevB.78.075306 Copyright: American Physical Society http://www.aps.org

Published

2008

5. Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field

Author

Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Arvid, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots (QDs) in the presence of an applied external magnetic field is presented. Attention is focused on the redistribution between the spectral lines of a single QD observed at increasing magnetic field parallel to the growth direction (Faraday geometry). The redistribution effect is explained by considering the electron drift velocity in the QD plane that affects the probability for capture into the QD. In contrast, no redistribution is observed when applying the magnetic field perpendicular to the growth direction (Voigt geometry)., Original Publication: Evgenii Moskalenko, Andréas Larsson, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Effective tuning of the charge state of a single InAs/GaAs quantum dot by an external magnetic field, 2008, Physical Review B Condensed Matter, (78), 075306. http://dx.doi.org/10.1103/PhysRevB.78.075306 Copyright: American Physical Society http://www.aps.org

Published

2008

6. Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots

Author

Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., Petroff, P. M., Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., and Petroff, P. M.

Abstract

A photoluminescence study of self-assembled InAs/GaAs quantum dots under the influence of magnetic fields perpendicular and parallel to the dot layer is presented. At low temperatures, the magnetic field perpendicular to the dot layer alters the in-plane transport properties due to localization of carriers in wetting layer (WL) potential fluctuations. Decreased transport in the WL results in a reduced capture into the quantum dots and consequently a weakened dot-related emission. The effect of the magnetic field exhibits a considerable dot density dependence, which confirms the correlation to the in-plane transport properties. An interesting effect is observed at temperatures above approximately 100 K, for which magnetic fields, both perpendicular and parallel to the dot layer, induced an increment of the quantum dot photoluminescence. This effect is ascribed to the magnetic confinement of the exciton wave function, which increases the probability for carrier capture and localization in the dot, but affects also the radiative recombination with a reduced radiative lifetime in the dots under magnetic compression., Original Publication:Mats Larsson, Evgenii Moskalenko, Andréas Larsson, Per-Olof Holtz, C. Verdozzi, C.-O. Almbladh, W. V. Schoenfeld and P. M. Petroff, Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots, 2006, Physical Review B, (74), 245312.http://dx.doi.org/10.1103/PhysRevB.74.245312Copyright: American Physical Societyhttp://www.aps.org

Published

2006

7. Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy

Author

Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots subjected to a lateral external electric field gives insight into carrier transport and capture processes into Stranski-Krastanov-grown quantum dots. The results obtained on the excitons in a single dot demonstrate a considerable luminescence intensity enhancement of the dot as well as a charge redistribution when an electric field is applied. The charge reconfiguration is evidenced by the transition from a predominantly negatively charged to a neutral charge state of the exciton. The model proposed to explain the charge redistribution is based on an effective hole localization at the potential fluctuations of the wetting layer., Original Publication:Evgenii Moskalenko, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy, 2006, Physical Review B, (73), 155336.http://dx.doi.org/10.1103/PhysRevB.73.155336Copyright: American Physical Societyhttp://www.aps.org

Published

2006

8. Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots

Author

Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., Petroff, P. M., Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., and Petroff, P. M.

Abstract

A photoluminescence study of self-assembled InAs/GaAs quantum dots under the influence of magnetic fields perpendicular and parallel to the dot layer is presented. At low temperatures, the magnetic field perpendicular to the dot layer alters the in-plane transport properties due to localization of carriers in wetting layer (WL) potential fluctuations. Decreased transport in the WL results in a reduced capture into the quantum dots and consequently a weakened dot-related emission. The effect of the magnetic field exhibits a considerable dot density dependence, which confirms the correlation to the in-plane transport properties. An interesting effect is observed at temperatures above approximately 100 K, for which magnetic fields, both perpendicular and parallel to the dot layer, induced an increment of the quantum dot photoluminescence. This effect is ascribed to the magnetic confinement of the exciton wave function, which increases the probability for carrier capture and localization in the dot, but affects also the radiative recombination with a reduced radiative lifetime in the dots under magnetic compression., Original Publication:Mats Larsson, Evgenii Moskalenko, Andréas Larsson, Per-Olof Holtz, C. Verdozzi, C.-O. Almbladh, W. V. Schoenfeld and P. M. Petroff, Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots, 2006, Physical Review B, (74), 245312.http://dx.doi.org/10.1103/PhysRevB.74.245312Copyright: American Physical Societyhttp://www.aps.org

Published

2006

9. Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy

Author

Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots subjected to a lateral external electric field gives insight into carrier transport and capture processes into Stranski-Krastanov-grown quantum dots. The results obtained on the excitons in a single dot demonstrate a considerable luminescence intensity enhancement of the dot as well as a charge redistribution when an electric field is applied. The charge reconfiguration is evidenced by the transition from a predominantly negatively charged to a neutral charge state of the exciton. The model proposed to explain the charge redistribution is based on an effective hole localization at the potential fluctuations of the wetting layer., Original Publication:Evgenii Moskalenko, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy, 2006, Physical Review B, (73), 155336.http://dx.doi.org/10.1103/PhysRevB.73.155336Copyright: American Physical Societyhttp://www.aps.org

Published

2006

10. Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots

Author

Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., Petroff, P. M., Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., and Petroff, P. M.

Abstract

A photoluminescence study of self-assembled InAs/GaAs quantum dots under the influence of magnetic fields perpendicular and parallel to the dot layer is presented. At low temperatures, the magnetic field perpendicular to the dot layer alters the in-plane transport properties due to localization of carriers in wetting layer (WL) potential fluctuations. Decreased transport in the WL results in a reduced capture into the quantum dots and consequently a weakened dot-related emission. The effect of the magnetic field exhibits a considerable dot density dependence, which confirms the correlation to the in-plane transport properties. An interesting effect is observed at temperatures above approximately 100 K, for which magnetic fields, both perpendicular and parallel to the dot layer, induced an increment of the quantum dot photoluminescence. This effect is ascribed to the magnetic confinement of the exciton wave function, which increases the probability for carrier capture and localization in the dot, but affects also the radiative recombination with a reduced radiative lifetime in the dots under magnetic compression., Original Publication:Mats Larsson, Evgenii Moskalenko, Andréas Larsson, Per-Olof Holtz, C. Verdozzi, C.-O. Almbladh, W. V. Schoenfeld and P. M. Petroff, Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots, 2006, Physical Review B, (74), 245312.http://dx.doi.org/10.1103/PhysRevB.74.245312Copyright: American Physical Societyhttp://www.aps.org

Published

2006

11. Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy

Author

Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots subjected to a lateral external electric field gives insight into carrier transport and capture processes into Stranski-Krastanov-grown quantum dots. The results obtained on the excitons in a single dot demonstrate a considerable luminescence intensity enhancement of the dot as well as a charge redistribution when an electric field is applied. The charge reconfiguration is evidenced by the transition from a predominantly negatively charged to a neutral charge state of the exciton. The model proposed to explain the charge redistribution is based on an effective hole localization at the potential fluctuations of the wetting layer., Original Publication:Evgenii Moskalenko, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy, 2006, Physical Review B, (73), 155336.http://dx.doi.org/10.1103/PhysRevB.73.155336Copyright: American Physical Societyhttp://www.aps.org

Published

2006

12. Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots

Author

Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., Petroff, P. M., Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., and Petroff, P. M.

Abstract

A photoluminescence study of self-assembled InAs/GaAs quantum dots under the influence of magnetic fields perpendicular and parallel to the dot layer is presented. At low temperatures, the magnetic field perpendicular to the dot layer alters the in-plane transport properties due to localization of carriers in wetting layer (WL) potential fluctuations. Decreased transport in the WL results in a reduced capture into the quantum dots and consequently a weakened dot-related emission. The effect of the magnetic field exhibits a considerable dot density dependence, which confirms the correlation to the in-plane transport properties. An interesting effect is observed at temperatures above approximately 100 K, for which magnetic fields, both perpendicular and parallel to the dot layer, induced an increment of the quantum dot photoluminescence. This effect is ascribed to the magnetic confinement of the exciton wave function, which increases the probability for carrier capture and localization in the dot, but affects also the radiative recombination with a reduced radiative lifetime in the dots under magnetic compression., Original Publication:Mats Larsson, Evgenii Moskalenko, Andréas Larsson, Per-Olof Holtz, C. Verdozzi, C.-O. Almbladh, W. V. Schoenfeld and P. M. Petroff, Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots, 2006, Physical Review B, (74), 245312.http://dx.doi.org/10.1103/PhysRevB.74.245312Copyright: American Physical Societyhttp://www.aps.org

Published

2006

13. Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy

Author

Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots subjected to a lateral external electric field gives insight into carrier transport and capture processes into Stranski-Krastanov-grown quantum dots. The results obtained on the excitons in a single dot demonstrate a considerable luminescence intensity enhancement of the dot as well as a charge redistribution when an electric field is applied. The charge reconfiguration is evidenced by the transition from a predominantly negatively charged to a neutral charge state of the exciton. The model proposed to explain the charge redistribution is based on an effective hole localization at the potential fluctuations of the wetting layer., Original Publication:Evgenii Moskalenko, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy, 2006, Physical Review B, (73), 155336.http://dx.doi.org/10.1103/PhysRevB.73.155336Copyright: American Physical Societyhttp://www.aps.org

Published

2006

14. Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy

Author

Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., Petroff, P. M., Moskalenko, Evgenii, Larsson, Mats, Holtz, Per-Olof, Schoenfeld, W. V., and Petroff, P. M.

Abstract

A microphotoluminescence study of single InAs/GaAs quantum dots subjected to a lateral external electric field gives insight into carrier transport and capture processes into Stranski-Krastanov-grown quantum dots. The results obtained on the excitons in a single dot demonstrate a considerable luminescence intensity enhancement of the dot as well as a charge redistribution when an electric field is applied. The charge reconfiguration is evidenced by the transition from a predominantly negatively charged to a neutral charge state of the exciton. The model proposed to explain the charge redistribution is based on an effective hole localization at the potential fluctuations of the wetting layer., Original Publication:Evgenii Moskalenko, Mats Larsson, Per-Olof Holtz, W. V. Schoenfeld and P. M. Petroff, Carrier transport in self-organized InAs/GaAs quantum-dot structures studied by single-dot spectroscopy, 2006, Physical Review B, (73), 155336.http://dx.doi.org/10.1103/PhysRevB.73.155336Copyright: American Physical Societyhttp://www.aps.org

Published

2006

15. Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots

Author

Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., Petroff, P. M., Larsson, Mats, Moskalenko, Evgenii, Larsson, Arvid, Holtz, Per-Olof, Verdozzi, C., Almbladh, C.-O., Schoenfeld, W. V., and Petroff, P. M.

Abstract

A photoluminescence study of self-assembled InAs/GaAs quantum dots under the influence of magnetic fields perpendicular and parallel to the dot layer is presented. At low temperatures, the magnetic field perpendicular to the dot layer alters the in-plane transport properties due to localization of carriers in wetting layer (WL) potential fluctuations. Decreased transport in the WL results in a reduced capture into the quantum dots and consequently a weakened dot-related emission. The effect of the magnetic field exhibits a considerable dot density dependence, which confirms the correlation to the in-plane transport properties. An interesting effect is observed at temperatures above approximately 100 K, for which magnetic fields, both perpendicular and parallel to the dot layer, induced an increment of the quantum dot photoluminescence. This effect is ascribed to the magnetic confinement of the exciton wave function, which increases the probability for carrier capture and localization in the dot, but affects also the radiative recombination with a reduced radiative lifetime in the dots under magnetic compression., Original Publication:Mats Larsson, Evgenii Moskalenko, Andréas Larsson, Per-Olof Holtz, C. Verdozzi, C.-O. Almbladh, W. V. Schoenfeld and P. M. Petroff, Magnetic field effects on optical and transport properties in InAs/GaAs quantum dots, 2006, Physical Review B, (74), 245312.http://dx.doi.org/10.1103/PhysRevB.74.245312Copyright: American Physical Societyhttp://www.aps.org

Published

2006