Investigation of energetic surface state distributions at real surfaces of silicon after treatment with HF and H<sub>2</sub>O using large-signal photovoltage pulses

Heilig, K.; Flietner, H.; Reineke, J.

doi:10.1088/0022-3727/12/6/016

Cited by 40 publications

(11 citation statements)

References 68 publications

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“…78 are generally consistent with other investigations of Flietner et al [717,718,720,721,723], as well as with the earlier analyses of Allen and Gobeli [710], Yamagishi [572], and Lam [716]. All of these show that well-passivated Si surfaces feature a`U-shaped' distribution of surface states, which is typically symmetric about midgap.…”

Section: Energy Distributionsupporting

confidence: 90%

“…In all cases, reasonable agreement with ac conductance data (where that method was applicable) was obtained. Consequently, Flietner, Heilig, et al extended the ®eld modulation approach to the study of free Si surfaces and non-metallized Si/insulator interfaces by employing an`arti®cial' MIS structure (i.e., a contactless gate electrode ± see Section 3.2) in conjunction with SPV-based V 0 s -determining methods discussed in Section 5.2.2 [717]. For example, the analysis based on Eq.…”

Section: Energy Distributionmentioning

confidence: 99%

“…For example, the analysis based on Eq. (5.34) has been applied to the study of HF and H 2 O treated Si(111) surfaces [717,718], Si(111)/lead-boro-alumino-silicate glass [713] and Si/porous Si [719], and mostly chemically [720±725] and electrochemically [714,726,727] Hterminated Si (111) surfaces. The same approach was used by Venger et al to study the surface state distribution at real Ge [568] and GaAs [569] surfaces.…”

Section: Energy Distributionmentioning

confidence: 99%

“…This immediately explains why most successful investigations described so far were limited to unpinned Si surfaces. In addition, possible hysteresis effects due to capture of charge in surface states must be taken into account when performing measurements as a function of gate bias [568,712,717]. If the bulk state density is very high, Q sc (and hence Q ss ) can no longer be calculated from Eq.…”

Section: Energy Distributionmentioning

confidence: 99%

See 3 more Smart Citations

Surface photovoltage phenomena: theory, experiment, and applications

Kronik

Shapira

1999

Surface Science Reports

1,528

804

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Section: Energy Distributionsupporting

confidence: 90%

Section: Energy Distributionmentioning

confidence: 99%

Section: Energy Distributionmentioning

confidence: 99%

Section: Energy Distributionmentioning

confidence: 99%

See 2 more Smart Citations

Surface photovoltage phenomena: theory, experiment, and applications

Kronik

Shapira

1999

Surface Science Reports

1,528

804

View full text Add to dashboard Cite

“…The abrupt change in Qsc near the midgap points at the existence of another group of surface states, maybe of an impurity character [7].…”

Section: Resultsmentioning

confidence: 99%

Analysis of Charge Versus the Surface Fermi Level Position at Silicon Surface

Adamowicz

1992

Acta Phys. Pol. A

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The surface charge Q,. versus tle surface Fermi level position Φ $ for real (111) surfaces of p-and n-type Si has been studied. The values of Qsc have been obtained on the basis of measurements of the surface potential V by means of the surface photo voltage method. The complementary character of Qsc(Φ3) dependences for the surfaces of p-and n-type Si supports the fact that the surface state distribution is not dependent on the type of bułk doping but on tle surface preparation process.

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Diffusion Photovoltage in Porous Semiconductors and Dielectrics

Timoshenko

Duzhko

Dittrich

2000

phys. stat. sol. (a)

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Strong retardation of photovoltage transients has been observed in porous materials (meso-and nanoporous Si, sintered networks of TiO 2 nanoparticles, porous Al oxide) excited by short laser pulse. It has been shown that the photovoltage is mainly determined by the slow carriers diffusion with different diffusion coefficients for electrons and holes. The influence of particle dimension, sign of more mobile charge carriers, and surface conditioning on the diffusion photovoltage has been demonstrated. We propose the diffusion photovoltage method as a universal technique to study carrier diffusion in materials with very low conductivity.Introduction The electronic transport in porous semiconductors and dielectrics depends significantly on the complex network of the nanoporous structure and on the conditioning of the large internal surface. This makes them quite interesting for many applications as in sensors [1] or solar cells [2]. But, porous semiconductors and dielectrics belong to a class of materials whose drift mobilities, concentrations of charge carriers and conditions for electrical carrier injection vary over many orders of magnitude. For these reasons, the application and interpretation of standard methods of mobility measurements is rather complicated or impossible. For example, Hall measurements could be applied for mesoporous silicon (meso-PS), for which the drift mobility and the free carrier concentration are not too small (m e 30 cm/Vs, n % 10 13 cm ±3 [3]). In contrast, time-of-flight (TOF) measurements are applicable for dielectric materials. The electron drift mobilities are, for example, about 10 ±4 ±10 ±1 cm/Vs in nanoporous Si [4] or 10 ±4 ±10 ±6 cm/Vs in nanoporous TiO 2 [5]. However, neither Hall or TOF are applicable for studying systematically the electronic transport properties of porous semiconductors and dielectrics in a wide range of experimental parameters.The photovoltage (PV) is a property of solids which can be easily measured independent of ambience, drift mobilities or concentration of carriers. This makes it universal. In the past, photovoltage methods have been applied successfully to determine parameters of semiconductors as carrier lifetimes [6] or diffusion coefficients [7] and of semiconductor surfaces as surface potential [8] or surface state distribution [9±11]. Especially spectral photovoltage measurements are powerful to investigate states in the forbidden band gap [12]. Electrical charging phenomena in por-Si/c-Si structures were investigated by pulsed PV measurements [13,14].

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Investigation of energetic surface state distributions at real surfaces of silicon after treatment with HF and H₂O using large-signal photovoltage pulses

Cited by 40 publications

References 68 publications

Surface photovoltage phenomena: theory, experiment, and applications

Surface photovoltage phenomena: theory, experiment, and applications

Analysis of Charge Versus the Surface Fermi Level Position at Silicon Surface

Diffusion Photovoltage in Porous Semiconductors and Dielectrics

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Investigation of energetic surface state distributions at real surfaces of silicon after treatment with HF and H2O using large-signal photovoltage pulses

Cited by 40 publications

References 68 publications

Surface photovoltage phenomena: theory, experiment, and applications

Surface photovoltage phenomena: theory, experiment, and applications

Analysis of Charge Versus the Surface Fermi Level Position at Silicon Surface

Diffusion Photovoltage in Porous Semiconductors and Dielectrics

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Product

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About

Investigation of energetic surface state distributions at real surfaces of silicon after treatment with HF and H₂O using large-signal photovoltage pulses