Silver-hydrogen interactions in crystalline silicon

Yarykin, Nikolai; Sachse, J.-U.; Lemke, Heinz U.; Weber, J.

doi:10.1103/physrevb.59.5551

Cited by 52 publications

(48 citation statements)

References 26 publications

(43 reference statements)

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“…On the other hand, this short-range potential may also be responsible for an electricfield dependence that has been reported for electron ͑hole͒ emission from double acceptor ͑donor͒ centers, in the case, for instance, of transition-metal impurities either isolated on substitutional lattice sites 26,27 or complexed with hydrogen. 28 In this case, however, the barrier lowering for emission is much smaller than in the case of the classical Poole-Frenkel effect. The observation of a weak dependence of the emission rate of the SnV1 level on the electric-field strength is thus indicative of this center being a double acceptor.…”

Section: A Deep-level Transient Spectroscopy "Dlts…mentioning

confidence: 93%

Tin-vacancy acceptor levels in electron-irradiated n-type silicon

et al. 2000

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Document VersionPublisher's PDF, also known as Version of record Link back to DTU Orbit Citation (APA): Larsen, A. N., Goubet, J. J., Mejlholm, P., Christensen, J. S., Fanciulli, M., Gunnlaugsson, H. P., ... Dannefaer, S. (2000). Tin-vacancy acceptor levels in electron-irradiated n-type silicon. Physical Review B Condensed Matter, 62(7), 4535-4544. DOI: 10.1103/PhysRevB.62.4535 Tin-vacancy acceptor levels in electron-irradiated n-type silicon 18 Sn/cm 3 were irradiated with 2-MeV electrons to different doses and subsequently studied by deep level transient spectroscopy, Mössbauer spectroscopy, and positron annihilation. Two tin-vacancy ͑Sn-V͒ levels at E c Ϫ0.214 eV and E c Ϫ0.501 eV have been identified ͑E c denotes the conduction band edge͒. Based on investigations of the temperature dependence of the electron-capture cross sections, the electric-field dependence of the electron emissivity, the anneal temperature, and the defect-introduction rate, it is concluded that these levels are the double and single acceptor levels, respectively, of the Sn-V pair. These conclusions are in agreement with electronic structure calculations carried out using a local spin-density functional theory, incorporating pseudopotentials to eliminate the core electrons, and applied to large H-terminated clusters. Thus, the Sn-V pair in Si has five different charge states corresponding to four levels in the band gap.

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Section: A Deep-level Transient Spectroscopy "Dlts…mentioning

confidence: 93%

Tin-vacancy acceptor levels in electron-irradiated n-type silicon

et al. 2000

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“…Infact, several deep recombination centers in low-bandgap semiconductors manifested this behavior since the very beginning of the studies on limiting charge life-time centers (Wertheim, 1959). Particularly, in the last years an extensive thermal spectroscopy study revealed that this behavior is quite common for transition metals in semiconductors (Grillenberger, 2004;Knack et al, 2002;Sachse et al, 2000;Shiraishi et al, 1999;Yarykin et al, 1999). …”

Section: Dynamical Instability In Ionization-recombination Reactionsmentioning

confidence: 99%

“…This seemingly unlikely condition happens to be verified by several transition metal impurities in germanium, silicon, silicon carbide (Grillenberger, 2004;Knack et al, 2002;Sachse et al, 2000;Shiraishi et al, 1999;Wertheim, 1959;Yarykin et al, 1999), both in case of doubly and triply ionized centers. A treatment of photoconduction in semiconductor in which recombination is assured by multiply ionized centers can be found in ref.…”

Section: Bistability By Multiply Ionized Recombination Centersmentioning

confidence: 99%

“…For instance, for native EL2 centers in gallium arsenide, undoubtely one of the most studied (Delaye & Sugg, 1994;Lin et al, 2006;Sudzius et al, 1999;Vincent et al, 1982), R 1 = C 1p /C 1n (see section 5) is known to vary in the range 10 −3 − 1 from the ambient to cryogenic temperatures , the dependence of its recovery rate R 21 (having an activation energy of about 0.3 eV) on temperature is also reported, but the capture rates of the metastable level are only known to be much smaller than those of the ground level (Delaye & Sugg, 1994), without any indication on the value of their ratio. In comparison, the capture rates of muptiply charged recombination centers have been studied in more detail, and several transition metal impurities in silicon, germanium and silicon carbide have exhibited a favourable ratio of the higher level cross section to the lower level one (K 2 /K 1 > 1, see section 6) (Grillenberger, 2004;Knack et al, 2002;Sachse et al, 2000;Shiraishi et al, 1999;Wertheim, 1959;Yarykin et al, 1999). Here we present a study on a center which is likely the most deeply and the longest studied of these, namely Nickel in Germanium.…”

Section: One Example Of Possible Photoconductive Bistable Behavior Inmentioning

confidence: 99%

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Bistable Photoconduction in Semiconductors

Lagomarsino¹

2011

Optoelectronic Devices and Properties

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“…The amount of hydrogen introduced is very low and is confined to the surface region. Much of the hydrogen is bound to P donors or B acceptors present in the material but annealing under a reverse bias (RBA) has the effect of driving the hydrogen deeper into the sample [164,165,166,167,168,169]. This method is particularly useful for a study of hydrogen related defects which dissociate around room temperature.…”

Section: Wet Etchingmentioning

confidence: 99%