Mimicking the texture found on the highly antireflective surfaces of the compound eyes of moths, scientists from Center for Functional Nanomaterials at Brookhaven National Laboratory have utilized block copolymer self-assembly to produce precise and tunable nanotextured designs in the range of ~20 nm across macroscopic silicon-based solar cells. The nanoscale texturing that was fabricated from the topmost silicon surface imparted broadband antireflection properties, which significantly enhanced the light-harvesting and, hence, overall performance of the solar cell compared to those with typical antireflection coatings.
A block-copolymer-based approach to surface texturing has yielded highly reproducible, well-organized surfaces that reduce reflections from silicon solar cell surfaces, down to less than 1% across entire visible and near infrared spectrum, and across a wide range of incident light angles. Further, block-copolymer based approaches are wholly scalable for the manufacture of large-area photovoltaic devices, with great potential for facile implementation into silicon-based, silicon nitride-based, and glass-based architectures, among other materials.
Proper design of an antireflection coating involves managing the refractive index mismatch at an abrupt optical interface. The most straightforward approach introduces a single layer of an intermediate optical index atop of a surface to create a system that engenders destructive interference in reflected light. This usually provides full antireflection at only a single wavelength. Increasingly, broadband coverage, for transparent window coatings, military camouflage or solar cells, among other applications, is possible using multilayered thin-film schemes.
As an alternative approach, nanoscale patterns imposed to the surface of a material, can create an effective graded index-of-refraction medium between the surface and air. Such patterns provide broadband antireflection over a wide range of incident light angles when nanoscale, sub-wavelength textures are sufficiently tall and closely spaced. In the CFN work, the broadband antireflection properties of a nanofabricated moth eye structure are enhanced through simultaneous control of both the geometry and optical properties, using block copolymer self-assembly to design nanotextures that are sufficiently small to take advantage of a beneficial material surface layer that is only a few nanometers thick. http://science.energy.gov/bes/highlights/2016/bes-2016-03-a/
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