1D photonic band gap PbTe doped silica quantum dot optical device

E. Rodríguez; E. Jimenez; C. L. Cesar; L. C. Barbosa; C. B. De Araújo

1D photonic band gap PbTe doped silica quantum dot optical device

E. Rodríguez, E. Jimenez, C. L. Cesar, L. C. Barbosa, C. B. De Araújo

Research output: Contribution to journal › Article › peer-review

Abstract

Thin films of glass doped with PbTe quantum dots (QDs) were successfully fabricated. The semiconducting nanocrystallites were grown by laser ablation of a PbTe target (99-99%) using the second harmonic of a Q-Switched Quantel Nd: YAG laser under a high purity argon atmosphere. The glass matrix was fabricated by a plasma chemical vapour deposition method using tetramethoxysilane (TMOS) vapour as precursor. The QDs and the glass matrix were alternately deposited onto a Si (100) wafer for 60 cycles. A cross sectional TEM image clearly showed the QD layers well separated from each other by glass matrix layers. The influence of the ablation time and the laser fluence on the density and size distribution of the quantum dots was studied. HRTEM revealed anisotropy in the size of the QDs: they were about 9 nm in height and 3-5 nm in diameter. Furthermore HRTEM studies revealed that the QDs basically grew in the (200) and (220) directions. The thickness of the glass matrix layer was about 20 nm. Absorption, photoluminescence and nonlinear optical properties of the device are currently being measured.

Original language	English
Pages (from-to)	47-49
Number of pages	3
Journal	Glass Technology
Volume	46
Issue number	2
State	Published - Apr 2005
Externally published	Yes

Cite this

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title = "1D photonic band gap PbTe doped silica quantum dot optical device",

abstract = "Thin films of glass doped with PbTe quantum dots (QDs) were successfully fabricated. The semiconducting nanocrystallites were grown by laser ablation of a PbTe target (99-99%) using the second harmonic of a Q-Switched Quantel Nd: YAG laser under a high purity argon atmosphere. The glass matrix was fabricated by a plasma chemical vapour deposition method using tetramethoxysilane (TMOS) vapour as precursor. The QDs and the glass matrix were alternately deposited onto a Si (100) wafer for 60 cycles. A cross sectional TEM image clearly showed the QD layers well separated from each other by glass matrix layers. The influence of the ablation time and the laser fluence on the density and size distribution of the quantum dots was studied. HRTEM revealed anisotropy in the size of the QDs: they were about 9 nm in height and 3-5 nm in diameter. Furthermore HRTEM studies revealed that the QDs basically grew in the (200) and (220) directions. The thickness of the glass matrix layer was about 20 nm. Absorption, photoluminescence and nonlinear optical properties of the device are currently being measured.",

author = "E. Rodr{\'i}guez and E. Jimenez and Cesar, {C. L.} and Barbosa, {L. C.} and {De Ara{\'u}jo}, {C. B.}",

year = "2005",

month = apr,

language = "Ingl{\'e}s",

volume = "46",

pages = "47--49",

journal = "Glass Technology",

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publisher = "Society of Glass Technology",

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TY - JOUR

T1 - 1D photonic band gap PbTe doped silica quantum dot optical device

AU - Rodríguez, E.

AU - Jimenez, E.

AU - Cesar, C. L.

AU - Barbosa, L. C.

AU - De Araújo, C. B.

PY - 2005/4

Y1 - 2005/4

N2 - Thin films of glass doped with PbTe quantum dots (QDs) were successfully fabricated. The semiconducting nanocrystallites were grown by laser ablation of a PbTe target (99-99%) using the second harmonic of a Q-Switched Quantel Nd: YAG laser under a high purity argon atmosphere. The glass matrix was fabricated by a plasma chemical vapour deposition method using tetramethoxysilane (TMOS) vapour as precursor. The QDs and the glass matrix were alternately deposited onto a Si (100) wafer for 60 cycles. A cross sectional TEM image clearly showed the QD layers well separated from each other by glass matrix layers. The influence of the ablation time and the laser fluence on the density and size distribution of the quantum dots was studied. HRTEM revealed anisotropy in the size of the QDs: they were about 9 nm in height and 3-5 nm in diameter. Furthermore HRTEM studies revealed that the QDs basically grew in the (200) and (220) directions. The thickness of the glass matrix layer was about 20 nm. Absorption, photoluminescence and nonlinear optical properties of the device are currently being measured.

AB - Thin films of glass doped with PbTe quantum dots (QDs) were successfully fabricated. The semiconducting nanocrystallites were grown by laser ablation of a PbTe target (99-99%) using the second harmonic of a Q-Switched Quantel Nd: YAG laser under a high purity argon atmosphere. The glass matrix was fabricated by a plasma chemical vapour deposition method using tetramethoxysilane (TMOS) vapour as precursor. The QDs and the glass matrix were alternately deposited onto a Si (100) wafer for 60 cycles. A cross sectional TEM image clearly showed the QD layers well separated from each other by glass matrix layers. The influence of the ablation time and the laser fluence on the density and size distribution of the quantum dots was studied. HRTEM revealed anisotropy in the size of the QDs: they were about 9 nm in height and 3-5 nm in diameter. Furthermore HRTEM studies revealed that the QDs basically grew in the (200) and (220) directions. The thickness of the glass matrix layer was about 20 nm. Absorption, photoluminescence and nonlinear optical properties of the device are currently being measured.

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M3 - Artículo

AN - SCOPUS:23144450997

SN - 0017-1050

VL - 46

SP - 47

EP - 49

JO - Glass Technology

JF - Glass Technology

IS - 2

ER -

1D photonic band gap PbTe doped silica quantum dot optical device

Abstract

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