Characterization of interface state density of three-dimensional Si nanostructure by charge pumping measurement

•Interface state density (Dit) on Si fins is studied by charge-pumping method.•The optimal forming gas annealing temperature for lowering Dit is about 420°C.•A method for evaluating the spatial distribution of Dit on Si fins is introduced.•Non-uniform Dit distribution of the surface of Si fins is re...

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Bibliographic Details
Published in:Microelectronics and reliability 2014-04, Vol.54 (4), p.725-729
Main Authors: Dou, Chunmeng, Shoji, Tomoya, Nakajima, Kazuhiro, Kakushima, Kuniyuki, Ahmet, Parhat, Kataoka, Yoshinori, Nishiyama, Akira, Sugii, Nobuyuki, Wakabayashi, Hitoshi, Tsutsui, Kazuo, Natori, Kenji, Iwai, Hiroshi
Format: Article
Language:English
Subjects:
Applied sciences
Charge
Charge density
Corners
Density
Diodes
Electronics
Exact sciences and technology
Interfaces
Nanostructure
Pumping
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Silicon
Three dimensional
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Summary:•Interface state density (Dit) on Si fins is studied by charge-pumping method.•The optimal forming gas annealing temperature for lowering Dit is about 420°C.•A method for evaluating the spatial distribution of Dit on Si fins is introduced.•Non-uniform Dit distribution of the surface of Si fins is revealed. Adopting the gated p–i–n diode configuration, the interface state density (Dit) at the Si/SiO2 interface of Si fin structures on Silicon-on-Insulator (SOI) wafers has been systematically studied using charge pumping method. The optimal forming gas annealing temperature for the three-dimensional (3D) surface is extracted. A new methodology for separately quantifying the local Dit at different regions of the 3D surfaces (i.e., the top/side walls and the corners) is also derived by characterizing the fins with various widths and the planar counterparts. The results validate the necessity to independently consider the corner regions, at which substantially high local Dit situates, and thus further clarify the origin of high Dit at 3D surfaces.
ISSN:0026-2714
1872-941X
DOI:10.1016/j.microrel.2013.11.016