Recent Progress in Understanding the Properties of the Amorphous Silicon/Crystalline Silicon Interface

Kleider, Jean‐Paul; Alvarez, José; Brüggemann, R.; Gueunier‐Farret, Marie‐Estelle

doi:10.1002/pssa.201800877

Cited by 4 publications

(3 citation statements)

References 75 publications

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“…Data from Ref. [30]. Figure 2 illustrates the topography and the local resistance mapping on the cross-section after a HF dip and for an applied voltage of 1 Volt.…”

Section: C-afm Investigation Of A-si:h/c-si Interfacementioning

confidence: 99%

Electrical scanning probe microscopy approaches to investigate solar cell junctions and devices

Alvarez

Marchat

Morisset

et al. 2020

Quantum Sensing and Nano Electronics and Photonics XVII

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C-AFM and KPFM techniques have been applied to investigate advanced junctions that are currently involved in highly efficient silicon solar cells. Our first study focuses on silicon heterojunctions and notably hydrogenated amorphous silicon (a-Si:H)/crystalline silicon (c-Si) P/n or N/p heterostructures which band bending at the interface forms a 2D channel. This conductive channel was indeed evidenced for the first time by cross-sectional investigations by C-AFM confirming the analysis of macroscopic planar conductance measurements. A second example of nanoscale characterization concerns the passivating selective contacts consisting in a thin silicon oxide (SiOx) layer between the c-Si and a highly doped polysilicon (poly-Si) layer. The electrical carrier transport is here not limited by the oxide layer and it is assumed that tunnelling through the oxide and/or the presence of pinholes are the main competitive mechanisms. For this specific heterostructure KPFM reveals local surface potential drops of 15-30 mV, which do not exist on samples without SiOx. These potential drops suggest the presence of pinholes that are formed during the poly-Si annealing process performed in the range of 700-900 °C. Finally, in a third study, we concentrate on p-in radial junction (RJ) silicon nanowire (SiNW) devices that are investigated under illumination by KPFM, in the so-called surface photovoltage (SPV) technique. This work focuses on the possibility of extracting the open-circuit voltage (VOC) on single isolated SiNW RJ by local SPV measurements using different AFM tip shapes and illumination directions in order to minimize shadowing effects.

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“…Data from Ref. [30]. Figure 2 illustrates the topography and the local resistance mapping on the cross-section after a HF dip and for an applied voltage of 1 Volt.…”

Section: C-afm Investigation Of A-si:h/c-si Interfacementioning

confidence: 99%

Electrical scanning probe microscopy approaches to investigate solar cell junctions and devices

Alvarez

Marchat

Morisset

et al. 2020

Quantum Sensing and Nano Electronics and Photonics XVII

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“…www.advancedsciencenews.com www.pss-rapid.com decreases below 10 nm was also suggested from the modeling of the effective lifetime in these structures, assuming that interface defects responsible for recombination of carriers photogenerated in c-Si can be considered as an extension of the DOS in (i) a-Si:H. [36] In conclusion, we have shown that the static planar conductance of (p) a-Si:H/(i) a-Si:H/(n) c-Si structures is very useful as it does not depend on recombination parameters like capture cross-sections, and it allows one to obtain a clear picture of the band bending at the heterojunction. A detailed analysis from both 1D analytical and 2D full numerical calculations was used to determine the evolution of the deep defect density N DB in (i) a-Si:H as a function of the layer thickness.…”

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confidence: 96%

“…Conversely, for the thicker (i) a‐Si:H layer of 50 nm, the value of the valence band tail width cannot be larger than 50 meV, meaning that with such thickness, the deposited material is equivalent to that of the device grade–thick “bulk” material . It is worth mentioning that an increase in the valence band tail width when the (i) a‐Si:H thickness decreases below 10 nm was also suggested from the modeling of the effective lifetime in these structures, assuming that interface defects responsible for recombination of carriers photogenerated in c‐Si can be considered as an extension of the DOS in (i) a‐Si:H …”

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confidence: 99%

Determination of Defect Densities in Thin (i) a‐Si:H Used as the Passivation Layer in a‐Si:H/c‐Si Heterojunction Solar Cells from Static Planar Conductance Measurements

Levtchenko

Gall

Brüggemann

et al. 2019

Physica Rapid Research Ltrs

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A set of (p) a‐Si:H/(i) a‐Si:H/(n) c‐Si heterostructures is investigated by coplanar conductance measurements. The thickness of the (i) a‐Si:H buffer layer is varied between 2 and 50 nm, well beyond the values used in heterojunction solar cells. The change in this thickness plays a role on band bending at the heterointerface and therefore impacts the level of inversion of carrier population at the c‐Si surface. Measurements are compared with 1D analytical calculations and 2D electrical modeling. It is demonstrated that the deep defect density, related to silicon dangling bonds, in the (i) a‐Si:H layer strongly increases from 1 × 1017 to 4 × 1018 cm−3 when the (i) a‐Si:H layer thickness is decreased from 50 to 2 nm. This result is interpreted in terms of defect formation and dependence of the defect density upon the position of the Fermi level with respect to the valence band edge. Quantitative analysis in the framework of the defect‐pool model demonstrates that the strong increase of defect density is also promoted by an increase in the width of the valence band tail in the thin (i) a‐Si:H layer, suggesting that a very thin layer also suffers from increased disorder.

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On resistive switching and dielectric spectroscopy characteristics of topological insulator-based heterojunction for memory applications

Nawar,

Abd-Elkader,

El-Mahalawy

et al. 2024

Appl. Phys. A

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Recent Progress in Understanding the Properties of the Amorphous Silicon/Crystalline Silicon Interface

Cited by 4 publications

References 75 publications

Electrical scanning probe microscopy approaches to investigate solar cell junctions and devices

Electrical scanning probe microscopy approaches to investigate solar cell junctions and devices

Determination of Defect Densities in Thin (i) a‐Si:H Used as the Passivation Layer in a‐Si:H/c‐Si Heterojunction Solar Cells from Static Planar Conductance Measurements

On resistive switching and dielectric spectroscopy characteristics of topological insulator-based heterojunction for memory applications

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