Photoinduced hole trapping in single semiconductor quantum dots at specific sites at silicon oxide interfaces

Krasselt, Cornelius, Schuster, Jörg, von Borczyskowski, Christian

23 September 2013

Blinking dynamics of CdSe/ZnS semiconductor quantum dots (QD) are characterized by (truncated) power law distributions exhibiting a wide dynamic range in probability densities and time scales both for off- and on-times. QDs were immobilized on silicon oxide surfaces with varying grades of hydroxylation and silanol group densities, respectively. While the off-time distributions remain unaffected by changing the surface properties of the silicon oxide, a deviation from the power law dependence is observed in the case of on-times. This deviation can be described by a superimposed single exponential function and depends critically on the local silanol group density. Furthermore, QDs in close proximity to silanol groups exhibit both high average photoluminescence intensities and large on-time fractions. The effect is attributed to an interaction between the QDs and the silanol groups which creates new or deepens already existing hole trap states within the ZnS shell. This interpretation is consistent with the trapping model introduced by Verberk et al. (R. Verberk, A. M. van Oijen and M. Orrit, Phys. Rev. B, 2002, 66, 233202).

Lumineszenz-Unterbrechung

Blinking

Halbleiter

Quantenpunkt

Nanopartikel

CdSe/ZnS

Einzelteilchen-Detektion

Siliziumoxid

trap Zustände

Loch trapping

Photoluminescence intermittency

semiconductor quantum dots

CdSe/ZnS

single particle detection

silicon oxide

trap states

hole trapping

ddc:539

Halbleiter

Quantenpunkt

Nanopartikel

Photoinduced hole trapping in single semiconductor quantum dots at specific sites at silicon oxide interfaces

Krasselt, Cornelius, Schuster, Jörg, von Borczyskowski, Christian

23 September 2013

Blinking dynamics of CdSe/ZnS semiconductor quantum dots (QD) are characterized by (truncated) power law distributions exhibiting a wide dynamic range in probability densities and time scales both for off- and on-times. QDs were immobilized on silicon oxide surfaces with varying grades of hydroxylation and silanol group densities, respectively. While the off-time distributions remain unaffected by changing the surface properties of the silicon oxide, a deviation from the power law dependence is observed in the case of on-times. This deviation can be described by a superimposed single exponential function and depends critically on the local silanol group density. Furthermore, QDs in close proximity to silanol groups exhibit both high average photoluminescence intensities and large on-time fractions. The effect is attributed to an interaction between the QDs and the silanol groups which creates new or deepens already existing hole trap states within the ZnS shell. This interpretation is consistent with the trapping model introduced by Verberk et al. (R. Verberk, A. M. van Oijen and M. Orrit, Phys. Rev. B, 2002, 66, 233202).

info:eu-repo/classification/ddc/539

ddc:539

Halbleiter; Quantenpunkt; Nanopartikel