Screen‐printed Emitter‐Wrap‐Through solar cell with single step side selective emitter with 18.8% efficiency

Mingirulli, Nicola; Stüwe, D.; Specht, J.; Fallisch, A.; Biro, Daniel

doi:10.1002/pip.1022

Cited by 12 publications

(4 citation statements)

References 19 publications

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“…Another possibility is to use a doped silicon oxide layer as a diffusion source as shown in [13]. Such a layer can be used, as already demonstrated earlier in [14][15][16], in a co-diffusion process or to replace phosphorus oxychloride (POCl 3 ) as in [17]. Doped silicon nitride layers may also be used as a replacement for POCl 3 as shown in [18].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Phosphorus-Doped Silicon Oxide Layers Deposited by Means of PECVD as a Dopant Source in Diffusion Processes

Fallisch

Wagenmann

Keding

et al. 2012

IEEE J. Photovoltaics

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In order to increase the conversion efficiencies of silicon solar cells, advanced cell structures with selectively doped areas receive an increasing interest. There is a strong need to separate the contacted diffusion profiles from the non-contacted. On the one hand, a high dopant concentration in the contact regime reduces the series resistance losses mainly due to lowered contact resistance. Additionally recombination is reduced by shielding the minority charge carriers from surface at the contact. On the other hand a low dopant concentration in the non-contact regime reduces the recombination losses and optimizes the spectral response of the cell.In this work phosphorus doped silicon oxide layers are used as a diffusion source for tube furnace diffusion processes. It is shown that the sheet resistance of the diffused area is controlled by the silane gas flow during the deposition of phosphorus doped silicon oxide. In order to analyze the influence of the diffused areas on the saturation current densities, symmetrical carrier lifetime samples are prepared. Therefore a stack system consisting of a thermally grown silicon dioxide and silicon nitride is used for passivation purposes on textured samples.

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Section: Introductionmentioning

confidence: 99%

Analysis of Phosphorus-Doped Silicon Oxide Layers Deposited by Means of PECVD as a Dopant Source in Diffusion Processes

Fallisch

Wagenmann

Keding

et al. 2012

IEEE J. Photovoltaics

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“…The printed polymer can then be crosslinked either thermally or by exposure to UV light thereby enabling it to 'resist' exposure to etchants such a hydrofluoric acid (HF) or buffered oxide etch (BOE) 64 which are routinely used to selectively etch the underlying dielectric or silicon. Screen-printed resist has been used as a mask to form contact areas for metal contacts to silicon solar cells, [65][66][67] structure a dielectric layer on the rear surface to achieve selective etching or diffusion of the rear silicon surface for BC solar cells 68 and emitter wrap-through cells, 69 structure metal layers for contact separation for BC cells 65 and as plating mask. 70 Mulligan et al 70 described the use of an acid-resistant polymer, which is printed over a thin seed metal layer sputtered on the rear surface of a BC solar cell, to expose isolated metal regions each in contact with either the ntype and p-type regions of the cell.…”

Section: Screen-printing Of Polymer Resistsmentioning

confidence: 99%

Patterned masking using polymers: insights and developments from silicon photovoltaics

Lennon

2016

International Materials Reviews

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Patterning is fundamental to advancing most technologies. Although the challenge for electronic integrated circuits continues to be reduced feature size other applications have different requirements and challenges. This review contributes insights from silicon photovoltaics where patterning is required for selective doping etching and metallisation. Earlier silicon solar cell devices extensively used optical lithography to fabricate devices in the laboratory with high device efficiencies being achieved. However industrial cell fabrication has largely relied on uniformly doped silicon layers and lower resolution screen-printing for metal electrode formation because optical lithography is considered too expensive and slow. This has resulted in the average energy conversion efficiencies of industrially produced cells remaining on average 5% lower than the value of 25% reported in 1999 for cells patterned with optical lithography. Motivated by the goal of bridging this efficiency gap many new polymer patterning methods which do not require the formation of a qualified mask have been developed for different silicon solar cell designs. These polymer patterning methods fall into two general classes; (i) where the polymer mask is directly printed on the cell surface; and (ii) where a pattern is formed in a polymer layer using printers or lasers to effect the patterning. Many of the methods which are reviewed in this paper although developed with specific photovoltaic requirements in mind may also find applications in other fields of research and technology.

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“…Recently, alternative technologies have been examined to optimize the conversion efficiencies (CEs) of the high-efficiencies silicon-based solar cells (SBSCs), including the passivated emitter and rear cell (PERC) devices [1][2], passivated emitter and rear locally diffused (PERL) cells [3][4], passivated emitter and rear totally diffused (PERT) cells [5][6], interdigitated back-contacted (IBC) solar cells [7][8], emitter-wrap-through (EWT) solar cells [9][10] and heterojunction with intrinsic thin-layer (HIT) solar cells [11][12]. The up-and downconversion materials (DCMs) are one of the other effective methods to improve the solar cell performances [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal synthesis of Eu<sup>3+</sup>-doped NaYF<inf>4</inf> downconversion materials for silicon-based solar cells applications

Liu

Cheng

Yang

2015

2015 22nd International Workshop on Active-Matrix Flatpanel Displays and Devices (AM-FPD)

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A Eu 3+ -doped NaYF 4 downconversion materials (DCM) spin-cast on the front surface of the silicon-based solar cells (SBSCs) has been fabricated to improve the photovoltaic characteristics of SBSCs. Organic solvent dispersible Eu 3+ -doped NaYF 4 DCMs were hydrothermally synthesized according to the modified liquid-solid-solution synthetic strategy. Intense and well-resolved photoluminescent lines in the range of 580-700 nm are observed from the Eu 3+ -doped NaYF 4 DCM. The achievement of an CE improvement of more than 0.6% absolute from 15.5% to 16.1% in SBSCs with Eu 3+ -doped NaYF 4 DCM was explored.

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Screen‐printed Emitter‐Wrap‐Through solar cell with single step side selective emitter with 18.8% efficiency

Cited by 12 publications

References 19 publications

Analysis of Phosphorus-Doped Silicon Oxide Layers Deposited by Means of PECVD as a Dopant Source in Diffusion Processes

Analysis of Phosphorus-Doped Silicon Oxide Layers Deposited by Means of PECVD as a Dopant Source in Diffusion Processes

Patterned masking using polymers: insights and developments from silicon photovoltaics

Hydrothermal synthesis of Eu<sup>3+</sup>-doped NaYF<inf>4</inf> downconversion materials for silicon-based solar cells applications

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