Black silicon significantly enhances phosphorus diffusion gettering

Pasanen, Toni P.; Laine, Hannu S.; Vähänissi, Ville; Schön, Jonas; Savin, Hele

doi:10.1038/s41598-018-20494-y

Cited by 24 publications

(21 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Chakraborty et al presented similar results and reported that phosphorus diffusion gettering reduced the concentration of light‐induced defects, which were suspected to be Cu, Ni, and Ti, by nearly one order of magnitude . Interestingly, our previous study demonstrated that heavy phosphorus‐doping in the b‐Si spikes after an industry‐typical POCl 3 diffusion process enhances iron segregation to the emitter, which substantially improves minority carrier lifetime in iron‐contaminated substrates . Consistent with earlier reports, sheet resistance is indeed substantially lower in the b‐Si than in the acidic‐textured cells (~50 Ω/□ vs ~80 Ω/□).…”

Section: Resultssupporting

confidence: 84%

“…Furthermore, the large surface area of b‐Si is no longer a hindrance for high‐efficiency b‐Si solar cells due to the advancements in novel surface passivation methods . In fact, it has been recently shown that the large surface area can provide also an advantage, since it significantly enhances gettering of deleterious metal impurities during phosphorus diffusion …”

Section: Introductionmentioning

confidence: 99%

“…1,[3][4][5] In fact, it has been recently shown that the large surface area can provide also an advantage, since it significantly enhances gettering of deleterious metal impurities during phosphorus diffusion. 6 The evidence for enhanced gettering implies that b-Si could also influence light-and elevated temperature-induced degradation (LeTID), which is the main culprit for efficiency deterioration in today's multicrystalline silicon (mc-Si) solar cells. 7,8 LeTID may result in over 10% relative efficiency loss in cells with dielectrically-passivated rear side, 7,9,10 which is a significant issue for the PV industry that is shifting towards passivated emitter and rear cells (PERC).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Impact of black silicon on light‐ and elevated temperature‐induced degradation in industrial passivated emitter and rear cells

Pasanen

Modanese

Vähänissi

et al. 2018

Progress in Photovoltaics

Self Cite

View full text Add to dashboard Cite

Light and elevated‐temperature induced degradation (LeTID) is currently a severe issue in passivated emitter and rear cells (PERC). In this work, we study the impact of surface texture, especially a black silicon (b‐Si) nanostructure, on LeTID in industrial p‐type mc‐Si PERC. Our results show that during standard LeTID conditions the b‐Si cells with atomic‐layer‐deposited aluminum oxide (AlOx) front surface passivation show no degradation despite the presence of a hydrogen‐rich AlOx/SiNx passivation stack on the rear. Furthermore, b‐Si solar cells passivated with silicon nitride (SiNx) on the front lose only 1.5%rel of their initial power conversion efficiency, while the acidic‐textured equivalents degrade by nearly 4%rel under the same conditions. Correspondingly, clear degradation is visible in the internal quantum efficiency (IQE) of the acidic‐textured cells, especially in the ~850 to 1100‐nm wavelength range confirming that the degradation occurs in the bulk, while the IQE remains nearly unaffected in the b‐Si cells. The observations are supported by spatially resolved photoluminescence (PL) maps, which show a clear contrast in the degradation behavior of b‐Si and acidic‐textured cells, especially in the case of SiNx front surface passivation. The PL maps also suggest that the magnitude of LeTID scales with surface area of the texture, rather than wafer thickness that was recently reported, although the b‐Si cells are slightly thinner (140 vs 165 μm). The results indicate that b‐Si has a positive impact on LeTID, and hence, benefits provided by b‐Si are not limited only to the excellent optical properties, as commonly understood.

show abstract

Section: Resultssupporting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Impact of black silicon on light‐ and elevated temperature‐induced degradation in industrial passivated emitter and rear cells

Pasanen

Modanese

Vähänissi

et al. 2018

Progress in Photovoltaics

Self Cite

View full text Add to dashboard Cite

show abstract

“…Black silicon surfaces can be achieved using different techniques that can be easily incorporated in the PV industry such as metal‐assisted wet‐chemical etching (MACE), dry reactive ion etching (RIE), inductive couple plasma–reactive ion etching (ICP‐RIE), laser structuring, and electrochemical etching . Additionally, collateral benefits of b‐Si have arisen recently improving low‐cost substrates by removing saw surface damage in diamond‐wire‐sawn (DWS) wafers or increasing the gettering effect during doping diffusion on Czochralski (CZ) c‐Si solar cells . All these advantages make black silicon etching a very attractive candidate to replace conventional acidic and alkaline texturizing approaches in the PV fabrication chain.…”

Section: Introductionmentioning

confidence: 99%

“…4 Additionally, collateral benefits of b-Si have arisen recently improving low-cost substrates by removing saw surface damage in diamond-wire-sawn (DWS) wafers 5 or increasing the gettering effect during doping diffusion on Czochralski (CZ) c-Si solar cells. 6 All these advantages make black silicon etching a very attractive candidate to replace conventional acidic and alkaline texturizing approaches in the PV fabrication chain. For instance, Modanese et al 7 demonstrated the economic viability of replacing acidic texturing by ICP-RIE b-Si nanostructures using a convectional industrial process on the basis of mc-Si substrates.…”

Section: Introductionmentioning

confidence: 99%

Black silicon back‐contact module with wide light acceptance angle

Ortega

Garín

Gastrow

et al. 2019

Progress in Photovoltaics

Self Cite

View full text Add to dashboard Cite

In this work, a photovoltaic mini‐module combining interdigitated back‐contacted solar cells with black silicon in the front was implemented as a proof of concept. The module consists of nine solar cells connected in series with an active area of 86.5 cm2. Both the assembly and panel encapsulation were made using industrial back‐contact module technology. Noticeable photovoltaic efficiencies of 18.1% and 19.9% of the whole module and the best individual cell of the module, respectively, demonstrate that fragile nanostructures can withstand standard module fabrication stages. Open‐circuit voltage and fill factor values of 5.76 V and 81.6%, respectively, reveal that series interconnection between cells works as expected, confirming a good ohmic contact between cell busbars and the conductive backsheet. Additionally, the excellent quasi‐omnidirectional antireflection properties of black silicon surfaces prevail at module level, as it is corroborated by light incidence angle dependence measurements of the short‐circuit current parameter.

show abstract

Surface Defect Passivation of Silicon Micropillars

Mikulik

Meng

Berrazouane

et al. 2018

Adv Materials Inter

View full text Add to dashboard Cite

Reactive ion etching (RIE) used to fabricate high‐aspect‐ratio (HAR) nano/microstructures is known to damage semiconductor surfaces which enhances surface recombination and limits the conversion efficiency of nanostructured solar cells. Here, defect passivation of ultrathin Al2O3‐coated Si micropillars (MPs) using different surface pretreatment steps is reported. Effects on interface state density are quantified by means of electrochemical impedance spectroscopy which is used to extract quantitative capacitance–voltage and conductance–voltage characteristics from HAR dielectric–semiconductor structures which would otherwise suffer from high gate leakage currents if tested using solid‐state metal–insulator–semiconductor structures. High‐temperature thermal oxidation to form a sacrificial oxide on RIE‐fabricated Si MPs, followed by atomic layer deposition of 4 nm thick Al2O3 after removal of the sacrificial layer produces an interface trap density (D it) as low as 1.5 × 1011 cm−2 eV−1 at the mid‐gap energy of silicon. However, a greatly reduced mid‐gap D it (2 × 1011 cm−2 eV−1) is possible even with a simple air annealing procedure having a maximum temperature of 400 °C.

show abstract

Black silicon significantly enhances phosphorus diffusion gettering

Cited by 24 publications

References 40 publications

Impact of black silicon on light‐ and elevated temperature‐induced degradation in industrial passivated emitter and rear cells

Impact of black silicon on light‐ and elevated temperature‐induced degradation in industrial passivated emitter and rear cells

Black silicon back‐contact module with wide light acceptance angle

Surface Defect Passivation of Silicon Micropillars

Contact Info

Product

Resources

About