Carrier trapping study on a Ge nanocrystal by two-pass lift mode electrostatic force microscopy

Z. Lin; P. Brunkov; F. Bassani; A. Descamps; C. O'Dwyer; G. Bremond

doi:10.1088/2053-1591/2/3/035001

Carrier trapping study on a Ge nanocrystal by two-pass lift mode electrostatic force microscopy

Z. Lin
, P. Brunkov
, F. Bassani
, A. Descamps
, C. O'Dwyer
, G. Bremond

School of Chemistry

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

Abstract

Trapped charges inside an isolated germanium nanocrystal (Ge NC) have been studied by two-pass lift mode electrostatic force microscopy (EFM) measurements at room temperature. From visualized EFM images, electrons and holes were proven to be successfully injected and trapped in the GeNC and distributed homogenously at the edge of its truncated spherical morphology. The GeNC is found to have iso-potential surface and behave as a conductive material after being charged. It is also shown that the dominant charge decay mechanism during discharging of Ge NCs is related to the leakage of these trapped charges. A truncated capacitor model is used to approximate the real capacitance between the tip and Ge NC surface and to quantitatively study these trapped charges. These investigations demonstrate the potential for Ge nanocrystal memory applications.

Original language	English
Article number	035001
Journal	Materials Research Express
Volume	2
Issue number	3
DOIs	https://doi.org/10.1088/2053-1591/2/3/035001
Publication status	Published - Mar 2015

Keywords

Electrostatic force microscopy
Germanium nanocrystal
Memory device
Nanostructure

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10.1088/2053-1591/2/3/035001

https://hdl.handle.net/10468/6200Licence: CC BY-NC-ND

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title = "Carrier trapping study on a Ge nanocrystal by two-pass lift mode electrostatic force microscopy",

abstract = "Trapped charges inside an isolated germanium nanocrystal (Ge NC) have been studied by two-pass lift mode electrostatic force microscopy (EFM) measurements at room temperature. From visualized EFM images, electrons and holes were proven to be successfully injected and trapped in the GeNC and distributed homogenously at the edge of its truncated spherical morphology. The GeNC is found to have iso-potential surface and behave as a conductive material after being charged. It is also shown that the dominant charge decay mechanism during discharging of Ge NCs is related to the leakage of these trapped charges. A truncated capacitor model is used to approximate the real capacitance between the tip and Ge NC surface and to quantitatively study these trapped charges. These investigations demonstrate the potential for Ge nanocrystal memory applications.",

keywords = "Electrostatic force microscopy, Germanium nanocrystal, Memory device, Nanostructure",

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doi = "10.1088/2053-1591/2/3/035001",

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T1 - Carrier trapping study on a Ge nanocrystal by two-pass lift mode electrostatic force microscopy

AU - Lin, Z.

AU - Brunkov, P.

AU - Bassani, F.

AU - Descamps, A.

AU - O'Dwyer, C.

AU - Bremond, G.

PY - 2015/3

Y1 - 2015/3

N2 - Trapped charges inside an isolated germanium nanocrystal (Ge NC) have been studied by two-pass lift mode electrostatic force microscopy (EFM) measurements at room temperature. From visualized EFM images, electrons and holes were proven to be successfully injected and trapped in the GeNC and distributed homogenously at the edge of its truncated spherical morphology. The GeNC is found to have iso-potential surface and behave as a conductive material after being charged. It is also shown that the dominant charge decay mechanism during discharging of Ge NCs is related to the leakage of these trapped charges. A truncated capacitor model is used to approximate the real capacitance between the tip and Ge NC surface and to quantitatively study these trapped charges. These investigations demonstrate the potential for Ge nanocrystal memory applications.

AB - Trapped charges inside an isolated germanium nanocrystal (Ge NC) have been studied by two-pass lift mode electrostatic force microscopy (EFM) measurements at room temperature. From visualized EFM images, electrons and holes were proven to be successfully injected and trapped in the GeNC and distributed homogenously at the edge of its truncated spherical morphology. The GeNC is found to have iso-potential surface and behave as a conductive material after being charged. It is also shown that the dominant charge decay mechanism during discharging of Ge NCs is related to the leakage of these trapped charges. A truncated capacitor model is used to approximate the real capacitance between the tip and Ge NC surface and to quantitatively study these trapped charges. These investigations demonstrate the potential for Ge nanocrystal memory applications.

KW - Electrostatic force microscopy

KW - Germanium nanocrystal

KW - Memory device

KW - Nanostructure

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DO - 10.1088/2053-1591/2/3/035001

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JO - Materials Research Express

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ER -

Carrier trapping study on a Ge nanocrystal by two-pass lift mode electrostatic force microscopy

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Keywords

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