Defect production in strained p-type Si1−xGex by Er implantation

Mamor, M.; Pipeleers, Bert; Auret, F.D.; Vantomme, André

doi:10.1063/1.3531539

Cited by 5 publications

(2 citation statements)

References 41 publications

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“…One of the commonly used electric analyses of defects is deep‐level transient spectroscopy (DLTS) . In DLTS, after compulsive charge trapping to the defects, thermal detrapping of the charges is recorded as the time transition spectrum of capacitance.…”

Section: Defect Analysesmentioning

confidence: 99%

Roles of Electrons and Holes in the Luminescence of Rare‐Earth‐Doped Semiconductors

Ishii

Towlson

Harako

et al. 2013

Elect Comm in Japan

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SUMMARYThe roles of electrons and holes in the photoexcitation of a samarium-doped titanium dioxide (TiO 2 :Sm) thin film were investigated with electrical measurement techniques. To determine these roles, the holes were selectively injected into TiO 2 :Sm by using a distinctive sample structure involving a silicon oxide interface layer between TiO 2 :Sm and a conductive silicon substrate. Since the midgap states of the silicon oxide act as a barrier to the electrons in a positive DC bias V DC , the selective injection of holes can be realized for V DC > 0. The combination of the photoexcited dielectric relaxation technique, that is, the frequency dispersion measurement of complex impedance under excitation light, with the selective injection technique revealed that Sm was excited by electron trapping with a slower response rate of ~12 Hz and the subsequent recombination with holes in TiO 2 hosts with a faster response rate of ~950 Hz.

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Section: Defect Analysesmentioning

confidence: 99%

Roles of Electrons and Holes in the Luminescence of Rare‐Earth‐Doped Semiconductors

Ishii

Towlson

Harako

et al. 2013

Elect Comm in Japan

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show abstract

“…As well-known electrical measurements, capacitance-voltage (C-V) measurements and deep-level transition spectroscopy (DLTS) have been generally used to evaluate the static properties of semiconductors such as the energy levels and density of trap states. [9][10][11] However, we adopt the frequency-response analysis (FRA) to obtain the dynamic properties. In FRA, the response of an AC current, i.e., the behavior of the charge carriers, is analyzed with respect to the frequency x of the applied AC electric field.…”

Section: Introductionmentioning

confidence: 99%

Time-resolved analysis of charge responses determining luminescence properties

Ishii

2014

J. Mater. Res.

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To fabricate practical light-emitting devices, identification and minimization of nonradiative processes are necessary. In this study, an electrical measurement technique for time-resolved analyses of nonradiative processes was proposed. From the comparison between a commercial light-emitting diode (LED) and rare-earth-doped semiconductors, the technique, called electrical frequency-response analysis (FRA), revealed differences in the charge behaviors in the pn junction of bulk semiconductors and impurities. Although the charge response time constant on the order of a nanosecond realized effective recombination of the electron-hole pairs in a LED, the time constant larger than a microsecond still limited the emission intensity of the rare-earth-doped semiconductors such as Er-doped Si nanocrystals and GaAs with Er and O codopants. The energy-loss processes of the Er-doped semiconductors were investigated, and countermeasures to enhance the emission intensity were proposed.

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A Theoretical Simulation of the Radiation Responses of Si, Ge, and Si/Ge Superlattice to Low-Energy Irradiation

et al. 2018

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In this study, the low-energy radiation responses of Si, Ge, and Si/Ge superlattice are investigated by an ab initio molecular dynamics method and the origins of their different radiation behaviors are explored. It is found that the radiation resistance of the Ge atoms that are around the interface of Si/Ge superlattice is comparable to bulk Ge, whereas the Si atoms around the interface are more difficult to be displaced than the bulk Si, showing enhanced radiation tolerance as compared with the bulk Si. The mechanisms for defect generation in the bulk and superlattice structures show somewhat different character, and the associated defects in the superlattice are more complex. Defect formation and migration calculations show that in the superlattice structure, the point defects are more difficult to form and the vacancies are less mobile. The enhanced radiation tolerance of the Si/Ge superlattice will benefit for its applications as electronic and optoelectronic devices under radiation environment.

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Defect production in strained p-type Si1−xGex by Er implantation

Cited by 5 publications

References 41 publications

Roles of Electrons and Holes in the Luminescence of Rare‐Earth‐Doped Semiconductors

Roles of Electrons and Holes in the Luminescence of Rare‐Earth‐Doped Semiconductors

Time-resolved analysis of charge responses determining luminescence properties

A Theoretical Simulation of the Radiation Responses of Si, Ge, and Si/Ge Superlattice to Low-Energy Irradiation

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