Nature Communications (Dec 2023)

Wood-based superblack

  • Bin Zhao,
  • Xuetong Shi,
  • Sergei Khakalo,
  • Yang Meng,
  • Arttu Miettinen,
  • Tuomas Turpeinen,
  • Shuyi Mi,
  • Zhipei Sun,
  • Alexey Khakalo,
  • Orlando J. Rojas,
  • Bruno D. Mattos

DOI
https://doi.org/10.1038/s41467-023-43594-4
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 12

Abstract

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Abstract Light is a powerful and sustainable resource, but it can be detrimental to the performance and longevity of optical devices. Materials with near-zero light reflectance, i.e. superblack materials, are sought to improve the performance of several light-centered technologies. Here we report a simple top-down strategy, guided by computational methods, to develop robust superblack materials following metal-free wood delignification and carbonization (1500 °C). Subwavelength severed cells evolve under shrinkage stresses, yielding vertically aligned carbon microfiber arrays with a thickness of ~100 µm and light reflectance as low as 0.36% and independent of the incidence angle. The formation of such structures is rationalized based on delignification method, lignin content, carbonization temperature and wood density. Moreover, our measurements indicate a laser beam reflectivity lower than commercial light stoppers in current use. Overall, the wood-based superblack material is introduced as a mechanically robust surrogate for microfabricated carbon nanotube arrays.