A Simple Model Describing the Symmetric &lt;formula formulatype="inline"&gt;&lt;tex Notation="TeX"&gt;$I\hbox{--}V$&lt;/tex&gt;&lt;/formula&gt; Characteristics of &lt;formula formulatype="inline"&gt;&lt;tex Notation="TeX"&gt;$\hbox{p}$&lt;/tex&gt;&lt;/formula&gt; Polycrystalline Si/ &lt;formula formulatype="inline"&gt;&lt;tex Notation="TeX"&gt;$\hbox{n}$&lt;/tex&gt;&lt;/formula&gt; Monocrystalline Si, and &lt;formula formulatype="inline"&gt; &lt;tex Notation="TeX"&gt;$\hbox{n}$&lt;/tex&gt;&lt;/formula&gt;

Peibst, Robby; Römer, Udo; Hofmann, K.R.; Lim, Bianca; Wietler, Tobias; Krügener, Jan; Harder, Nils‐Peter; Brendel, Rolf

doi:10.1109/jphotov.2014.2310740

Cited by 94 publications

(11 citation statements)

References 31 publications

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“…14 Since already the BJT community reports on an inconsistency of the tunnel model with respect to the description of electron collecting/emitting or hole collecting/emitting POLO junctions, 13 Peibst et al proposed an alternative picture, assuming that conduction through the interfacial oxide happens at places where the oxide is broken up locally (Pinholes). 15,16 This model symmetrically explains the recombination and contact resistance of n + /p and p + /n POLO junctions. It was suggested that both mechanisms possibly superimpose in real junctions, in particular for the case of interfacial oxides with thicknesses d ox < 1.5 nm formed by wet-chemical or ozone oxidation.…”

Section: Introductionmentioning

confidence: 98%

“…thus depends only on these two quantities. 1 For values of S > 10 15 , the solar cell efficiency is rather limited by the intrinsic recombination of crystalline Si (c-Si) than by the carrier selective contact. Such high contact selectivities were realized by a layer stack of doped, mostly poly-silicon (poly-Si) on a thin silicon oxide (SiO x ).…”

Section: Introductionmentioning

confidence: 99%

“…The pinhole model of Peibst et al 15,16 completely disregards tunneling through the regions where the interfacial oxide is still intact, while the tunneling model of Steinkemper et al 14 vice versa disregards pinhole transport. An analytical simplification of this tunneling model that describes the junction as a metal/SiO x /c-Si stack was proposed by Feldmann et al 23 and later applied to multiscale modelling of solar cells.…”

Section: Introductionmentioning

confidence: 99%

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Modeling recombination and contact resistance of poly‐Si junctions

Folchert

Peibst

Brendel

2020

Progress in Photovoltaics

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We present a semi-analytical model for the calculation of the current through and the recombination in carrier-selective junctions consisting of a poly-Si/SiO x /c-Si layer stack. We calculate the recombination parameter J 0 and the contact resistance ρ C after solving the band-bending-problem on both sides of the interfacial oxide. Comparisons with finite-element simulations show that the current calculation is reliable at all bias conditions except for inversion and that current through pinholes is resolved adequately in the model. The model allows a coherent description of lifetime-, current-voltage-and capacitance-voltage measurements performed on a sample with dominant tunneling. We use our model to investigate the influence of oxide thickness and pinhole density on J 0 and ρ C of our state-of-the-art poly-siliconon-oxide (POLO) junctions and demonstrate its usefulness for the optimization of poly-Si based junctions.

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modeling recombination and contact resistance of poly‐Si junctions

Folchert

Peibst

Brendel

2020

Progress in Photovoltaics

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“…The principle of any carrier-selective contact is to maximize the blocking effect for minority carriers whilst minimizing the barrier of majority carriers. 1,2 One type of carrier selective junction is realized by a layer of highly doped poly-Si that is deposited on a thin interfacial oxide [3][4][5] called poly-Si on oxide (POLO) junction. This type of junction is utilized in a p-type Si solar cell with a record energy conversion efficiency of 26.1%.…”

Section: Introductionmentioning

confidence: 99%

Contacting a single nanometer‐sized pinhole in the interfacial oxide of a poly‐silicon on oxide (POLO) solar cell junction

Bayerl

Folchert

Bayer

et al. 2021

Progress in Photovoltaics

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The electrical current through poly-Si on oxide (POLO) solar cells is mediated by tunneling and by nanometer-sized pinholes in the interfacial oxide. To distinguish the two processes, a POLO junction with a measured pinhole density of 1 × 10 7 cm −2 is contacted by different contact areas ranging from 1 μm 2 to 2.5 × 10 5 μm 2 , and the temperature-dependent current-voltage curves are measured for the different devices. Model regressions to the measured curves, their temperature dependence, and the quantized value of contact resistances indicate average numbers of pinholes per device corresponding to the expected pinhole density. For the small contacts, the different transport processes can be studied separately, which facilitates further improvements in respect to the present-day POLO junctions. Single-pinhole transport is found for one of the contacts with an area of 1 μm 2 . Random telegraph noise observed for this device in the current-voltage characteristics shows a high sensitivity to single charges.

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“…By the use of an interdigitated back contact structure Kaneka achieved an efficiency of 26.6% . The tunnel oxide passivating contact (TOPCon) and POLO structures represent another approach which is based on a thin intermediate oxide layer and a heavily doped nano/polycrystalline silicon layer above and leads to efficiencies of >25%. For some years now “silicon‐free” alternative thin films as metal oxide layers like WO x , MoO x have proved a very high potential .…”

Section: Introductionmentioning

confidence: 99%

Inline PECVD Deposition of Poly‐Si‐Based Tunnel Oxide Passivating Contacts

Temmler

Polzin

Feldmann

et al. 2018

Physica Status Solidi (a)

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In this publication, the deposition of a-Si(n) layers using an industrially relevant inline plasma-enhanced chemical vapor deposition (PECVD) tool for the successful realization of passivating contacts is reported. Dynamic inline deposition has the potential to increase production throughput and yield compared to the conventional cluster-like PECVD tools which is the current standard for deposition of a-Si:H layers. Besides structural investigations concerning absorbance and band gap energy of these layers, the dependence of layer thickness and PH 3 gas phase doping on implied open circuit voltage iV OC , sheet resistance, and the corresponding diffusion profile is investigated. A significant influence of PH 3 gas phase doping is demonstrated whereas no significant dependence of the layer thickness is elaborated. Excellent values of iV OC ¼ 740 mV and iFF ¼ 85% on planar and iV OC ¼ 720 mV and iFF ¼ 84% on textured surfaces can be reached implementing the developed n-doped layers in the tunnel oxide passivating contact (TOPCon) structure.

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Cited by 94 publications

References 31 publications

Modeling recombination and contact resistance of poly‐Si junctions

Modeling recombination and contact resistance of poly‐Si junctions

Contacting a single nanometer‐sized pinhole in the interfacial oxide of a poly‐silicon on oxide (POLO) solar cell junction

Inline PECVD Deposition of Poly‐Si‐Based Tunnel Oxide Passivating Contacts

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