Black silicon solar cell: analysis optimization and evolution towards a thinner and flexible future

Roy, Arijit Bardhan; Dhar, Arup; Choudhuri, Mrinmoyee; Das, Sonali; Hossain, Syed Minhaz; Kundu, Atreyee

doi:10.1088/0957-4484/27/30/305302

Cited by 36 publications

(20 citation statements)

References 30 publications

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“…The name ‘black silicon’ originates from its deep black colour, resulting from the absorption of >99% of the visible light falling onto its surface. Black Si has now found applications in photovoltaics 5,6 and in biomedical sensing 7,8 .…”

Section: Introductionmentioning

confidence: 99%

Studies of Black Diamond as an antibacterial surface for Gram Negative bacteria: the interplay between chemical and mechanical bactericidal activity

Dunseath

Smith

Al-Jeda

et al. 2019

Sci Rep

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‘Black silicon’ (bSi) samples with surfaces covered in nanoneedles of length ~5 µm were fabricated using a plasma etching process and then coated with a conformal uniform layer of diamond using hot filament chemical vapour deposition to produce ‘black diamond’ (bD) nanostructures. The diamond needles were then chemically terminated with H, O, NH 2 or F using plasma treatment, and the hydrophilicity of the resulting surfaces were assessed using water droplet contact-angle measurements, and scaled in the order O > H ≈NH 2 >F, with the F-terminated surface being superhydrophobic. The effectiveness of these differently terminated bD needles in killing the Gram-negative bacterium E. coli was semi-quantified by Live/Dead staining and fluorescence microscopy, and visualised by environmental scanning electron microscopy. The total number of adhered bacteria was consistent for all the nanostructured bD surfaces at around 50% of the value for the flat diamond control. This, combined with a chemical bactericidal effect of 20–30%, shows that the nanostructured bD surfaces supported significantly fewer viable E. coli than flat surfaces. Moreover, the bD surfaces were particularly effective at preventing the establishment of bacterial aggregates – a precursor to biofilm formation. The percentage of dead bacteria also decreased as a function of hydrophilicity. These results are consistent with a predominantly mechanical mechanism for bacteria death based on the stretching and disruption of the cell membrane, combined with an additional effect from the chemical nature of the surface.

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Section: Introductionmentioning

confidence: 99%

Studies of Black Diamond as an antibacterial surface for Gram Negative bacteria: the interplay between chemical and mechanical bactericidal activity

Dunseath

Smith

Al-Jeda

et al. 2019

Sci Rep

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“…The name 'black silicon' originates from its deep black colour, resulting from the absorption of >99% of the visible light falling onto its surface. Originally something to be avoided, bSi has now found applications in photovoltaics [12,13] and has recently been used for biomedical sensing applications [14,15].…”

Section: Introductionmentioning

confidence: 99%

Studies of black silicon and black diamond as materials for antibacterial surfaces

et al. 2018

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'Black silicon' (bSi) samples with surfaces covered in nanoneedles of varying length, areal density and sharpness, have been fabricated using a plasma etching process. These nanostructures were then coated with a conformal uniform layer of diamond using hot filament chemical vapour deposition to produce 'black diamond' (bD) surfaces. The effectiveness of these bSi and bD surfaces in killing Gram-negative (E. coli) and Gram-positive (S. gordonii) bacteria was investigated by culturing the bacteria on the surfaces for a set time and then measuring the live-to-dead ratio. All the nanostructured surfaces killed E. coli at a significantly higher rate than the respective flat Si or diamond control samples. The length of the needles was found to be less important than their separation, i.e. areal density. This is consistent with a model for mechanical bacteria death based on the stretching and disruption of the cell membrane, enhanced by the cells motility on the surfaces. In contrast, S. gordonii were unaffected by the nanostructured surfaces, possibly due to their smaller size, thicker cell membrane and/or their lack of motility.

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“…2 Black Si nanotextured surfaces, which are textured using mask-less RIE, may be a replacement for wet-chemical texturing in silicon solar cell fabrication. [3][4][5][6][7] Black Si yields extraordinary low reflectance in an extremely broad spectral range. Thus, an additional AR coating is not required to reduce reflectance.…”

Section: Introductionmentioning

confidence: 99%

“…Black Si RIE technology also enables reduction of the Si wafer thickness to below 100 lm, 7 which avoids use of toxic materials, 13 provides easy RIE process optimization through adjustment of plasma parameters, and offers the possibility to texture any Si-based film or wafer, such as multicrystalline, 14 cast-mono, kerfless, and diamond-wire sawn Si substrates.…”

Section: Introductionmentioning

confidence: 99%

Low surface damage dry etched black silicon

Plakhotnyuk

Gaudig

Davidsen

et al. 2017

Journal of Applied Physics

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Black silicon solar cell: analysis optimization and evolution towards a thinner and flexible future

Cited by 36 publications

References 30 publications

Studies of Black Diamond as an antibacterial surface for Gram Negative bacteria: the interplay between chemical and mechanical bactericidal activity

Studies of Black Diamond as an antibacterial surface for Gram Negative bacteria: the interplay between chemical and mechanical bactericidal activity

Studies of black silicon and black diamond as materials for antibacterial surfaces

Low surface damage dry etched black silicon

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