Analysis of Fine-Line Screen and Stencil-Printed Metal Contacts for Silicon Wafer Solar Cells

Shanmugam, Vinodh; Wong, Johnson; Peters, Ian Marius; Cunnusamy, Jessen; Zahn, Michael; Zhou, Andrew F.; Yang, Rado; Chen, Xiao; Aberle, Armin G.; Mueller, Thomas

doi:10.1109/jphotov.2014.2388073

Cited by 32 publications

(23 citation statements)

References 9 publications

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“…Typical Ag front grid metallisation of a Si solar cell covers about 6-10% of the total area using an Hpattern with busbars and perpendicular fingers. One approach to reduce the metallisation induced recombination losses is to use a dual print approach for the front side metallisation, wherein the busbars are printed using a less aggressive paste (which causes minimum damage to the SiN x coating) and also by printing finer fingers using stencils [8] or using advanced printing methods.…”

Section: Introductionmentioning

confidence: 99%

Impact of the phosphorus emitter doping profile on metal contact recombination of silicon wafer solar cells

Shanmugam

Khanna

Basu

et al. 2016

Solar Energy Materials and Solar Cells

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Section: Introductionmentioning

confidence: 99%

Impact of the phosphorus emitter doping profile on metal contact recombination of silicon wafer solar cells

Shanmugam

Khanna

Basu

et al. 2016

Solar Energy Materials and Solar Cells

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“…At each node, the current density is given by J = J sc ( x , y ) − J R ( V ( x , y )), with J R ( V ( x , y )) = J 01 [exp( qV ( x , y )/ kT ) − 1] + J 02 [exp( qV ( x , y )/2 kT ) − 1], where J 01 and J 02 are the saturation current densities in the two‐diode model. Following Reference , J sc = 40.2 mA/cm 2 in the regions not covered by the front grid, and J 01 = 730 fA/cm 2 , and J 02 = 30 nA/cm 2 throughout the cell plane. The nodes are interconnected by resistors with values as appropriate for the sheet resistance of the region that the triangular element resides.…”

Section: Modelmentioning

confidence: 95%

“…The Pareto distribution and the fitted parameters constitute the most detailed description of non‐uniform metal line conductance to date. To recapitulate from Reference , the Pareto distribution is given by

\begin{matrix} left \\ P (σ_{short, i}) = {((), \frac{σ_{short, i}}{σ_{short, italicio}})}^{- α}; where σ_{short, i} \geq σ_{short, io} \\ = {((), \frac{2 σ_{short, io} - σ_{short, i}}{σ_{short, italicio}})}^{- α}; where σ_{short, i} < σ_{short, io} \end{matrix}

where σ short, i is the line conductance (in S‐cm) of the short unit segments of 250 µm segment length, with σ short, io being the mean and α a power law scaling factor. The smaller the scaling factor, the larger is the spread in the data.…”

Section: Modelmentioning

confidence: 99%

“…These imperfections add resistance to the metal front grid, causing the voltage to swell locally, rerouting completely or changing the division of current between finger segments where they occur. A recent study based on the surveying of screen printed 3D microscope line profiles, line segment resistance measurements, electroluminescence (EL) imaging checks for line breaks, and current–voltage (I‐V) measurements, revealed that even when the screen wire diameter and pitch are in accordance with design rules for the finger opening width in the screen, the printed lines (single print) are nevertheless severely non‐uniform when the opening width becomes less than 45 µm, to the extent of causing line breaks to be prevalent throughout the front grid with an accompanying fill factor of 71.1% at an opening width of 30 µm . This finding explains the trend that the industry is adopting double printing as a solution for using screen printing technology to print fine lines, where additional silver paste is printed on top of a first finger print to increase the overall line aspect ratio and uniformity in conductance .…”

Section: Introductionmentioning

confidence: 99%

“…Unlike screens with wire mesh, a stencil is designed to have cleanly opened apertures, which leads to an excellent paste transfer and printed line height uniformity. The same study has found that stencils with finger opening width of 30 µm results in sufficiently uniform lines to yield cells with average fill factor of 78.8% and front grid metal area fraction of 6.2% . In evaluating different printing technologies and accounting for print quality effects, it would be useful to develop a simulation tool that can capture the difference between front grids of varying degrees of uniformity, in their ability to distribute current and influence the cell I‐V curve.…”

Section: Introductionmentioning

confidence: 99%

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Influence of non‐uniform fine lines in silicon solar cell front metal grid design

Wong

Shanmugam

Cunnusamy³

et al. 2015

Progress in Photovoltaics

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While it is well known that the typical printed silver fingers on a silicon solar cell have profile striations, bottle-necks, and line breaks, the impact of these imperfections have not been assessed in calculations of front grid related power losses. This study uses detailed finite element modeling to show that when the realistic effects of non-uniform line conductance is accounted for; the simulated cell efficiency can be significantly lower than under the assumption of uniform lines, becoming closer to measured trends. The study also explores the incorporation of additional interconnecting fingers to the parallel grid finger in the H pattern, concluding that they are typically of no benefit to improving the cell efficiency. As an auxiliary observation, it was found that the efficiency calculated by simple ohmic power loss formulae is typically underestimated by 0.1-0.2% absolute, a margin that should be accounted for in cell optimization and analysis.

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Screen pattern simulation for an improved front‐side Ag‐electrode metallization of Si‐solar cells

Tepner

Ney

Linse

et al. 2020

Progress in Photovoltaics

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Flatbed screen printing proves to be the dominant metallization approach for mass production of silicon (Si)‐solar cells because of its robust and cost‐effective production capability. However, the ongoing demand of the PV industry to further decrease the width of printed Ag‐electrodes (contact fingers) requires new optimizations. This study presents the latest results on Si‐solar cell metallization using fine‐line screens down to screen opening widths of wn = 15 μm. The best experimental group achieved a record finger geometry with a mean finger width of wf = 19 μm and a mean finger height of hf = 18 μm. Furthermore, solar cell performance using a front‐side grid with a screen opening width of wn = 24 μm is investigated, reporting cell efficiencies up to 22.1% for Passivated Emitter and Rear Contact (PERC) solar cells. Finally, a novel screen pattern simulation is presented, revealing a correlation between the measured lateral finger resistance and the novel dimensionless parameter screen utility index (SUI). It describes the ratio between the average size of individual openings defined by the screen mesh angle and the chosen underlying mesh type. For SUI < 1, the printing result will strongly depend on the screen configuration, whereas for values of SUI > 1, the impact of the screen on the overall printability diminishes.

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Analysis of Fine-Line Screen and Stencil-Printed Metal Contacts for Silicon Wafer Solar Cells

Cited by 32 publications

References 9 publications

Impact of the phosphorus emitter doping profile on metal contact recombination of silicon wafer solar cells

Impact of the phosphorus emitter doping profile on metal contact recombination of silicon wafer solar cells

Influence of non‐uniform fine lines in silicon solar cell front metal grid design

Screen pattern simulation for an improved front‐side Ag‐electrode metallization of Si‐solar cells

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