All-metallic three-dimensional photonic crystals with a large infrared bandgap

Abstract

Three-dimensional (3D) metallic crystals are promising photonic bandgap^1,2,3 structures: they can possess a large bandgap^4,5,6, new electromagnetic phenomena can be explored^7,8,9, and high-temperature (above 1,000 °C) applications may be possible. However, investigation of their photonic bandgap properties is challenging, especially in the infrared and visible spectrum, as metals are dispersive and absorbing in these regions¹⁰. Studies of metallic photonic crystals have therefore mainly concentrated on microwave and millimetre wavelengths^8,11,12. Difficulties in fabricating 3D metallic crystals present another challenge, although emerging techniques such as self-assembly^13,14 may help to resolve these problems. Here we report measurements and simulations of a 3D tungsten crystal that has a large photonic bandgap at infrared wavelengths (from about 8 to 20 µm). A very strong attenuation exists in the bandgap, ∼ 30 dB per unit cell at 12 µm. These structures also possess other interesting optical properties; a sharp absorption peak is present at the photonic band edge, and a surprisingly large transmission is observed in the allowed band, below 6 µm. We propose that these 3D metallic photonic crystals can be used to integrate various photonic transport phenomena, allowing applications in thermophotovoltaics and blackbody emission.