2018
DOI: 10.1038/s41560-018-0239-4
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A passivating contact for silicon solar cells formed during a single firing thermal annealing

Abstract: As highlighted by recent conversion efficiency records, passivating contacts are keys to fully exploit the potential of crystalline silicon as a light absorbing semiconductor. Prime passivating contact technologies include a-Si/c-Si silicon heterojunctions and high temperature tunnel oxide/polysilicon-based contacts. The first has the advantage of a simple fabrication process, but it is incompatible with standard metallization processes and bulk semiconductor defect treatments which take place at temperature >… Show more

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Cited by 122 publications
(86 citation statements)
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“…A second observation is that all iVOC values are ~10 mV higher than in the previous experiments, thus exceeding 700 mV even for the samples processed with a chemical oxide (as previously published in [17]). The J0 value decreases from 22 to 8.3 fA/cm 2 for the samples featuring a chemical oxide on a DSP and SE wafer, respectively, and increases from 1.4 to 2.3 fA/cm 2 for the DSP and SE samples with a thermal oxide.…”
Section: Effect Of the Interfacial Oxide's Nature On The Passivation supporting
confidence: 69%
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“…A second observation is that all iVOC values are ~10 mV higher than in the previous experiments, thus exceeding 700 mV even for the samples processed with a chemical oxide (as previously published in [17]). The J0 value decreases from 22 to 8.3 fA/cm 2 for the samples featuring a chemical oxide on a DSP and SE wafer, respectively, and increases from 1.4 to 2.3 fA/cm 2 for the DSP and SE samples with a thermal oxide.…”
Section: Effect Of the Interfacial Oxide's Nature On The Passivation supporting
confidence: 69%
“…The first processing step consisted of a wet chemical cleaning, ending with a hot HNO3 treatment (69 %, 80 °C, 10 min) growing a ~1.3 nm thin wet chemical SiOx layer on the wafer surfaces [22,23]. Next, a ~25 nm thick hydrogenated amorphous a-SiCx(p):H (~2.5 at.% of carbon [17]) layer was deposited by Plasma Enhanced Chemical Vapor Deposition (PECVD) at 200 °C. Subsequently, the samples were fired for 3 s at ~800 °C.…”
Section: Fabricationmentioning
confidence: 99%
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“…A comparison of both passivation concepts shows that record cells with a‐Si:H(i) passivation developed for the silicon heterojunction (SHJ) technology currently give rise to higher open‐circuit voltages ( V oc ) than using SiO 2 passivation from polycrystalline silicon on oxide (POLO) technology or tunnel oxide passivating contact (TOPCon) technology. Further, for a‐Si:H(i), the excellent interface passivation is directly achieved after the deposition of the a‐Si:H(i) film, whereas for SiO 2 , it requires several additional process steps to provide excellent interface passivation . Reducing the number of process steps is under current investigation within several research groups in the field of c‐Si solar cells.…”
Section: Introductionmentioning
confidence: 99%
“…Further, for a-Si:H(i), the excellent interface passivation is directly achieved after the deposition of the a-Si:H(i) film, whereas for SiO 2 , it requires several additional process steps to provide excellent interface passivation. 4 Reducing the number of process steps is under current investigation within several research groups in the field of c-Si solar cells. Although a-Si: H(i) is an excellent passivation material, it possesses an optical bandgap 5 of approximately 1.7 eV that leads to significant parasitic absorption of the incident sunlight.…”
Section: Introductionmentioning
confidence: 99%