Data for publication: Carbonization of selected biological materials, trends, and perspectives

The collection includes files related to the review publication: Martyna Kotula, Anita Kubiak, Bartosz Leśniewski, Martyna Pajewska-Szmyt, Carbonization of Selected Biological Materials, Trends, and Perspectives, Letters in Applied NanoBioScience August 2023, Volume 12, 68.The collection includes figures used in the publication: Figure_1 Selected biological materials and their source.Figure _2 Scheme showing the transformation of cellulose nanocrystals into percolated conductive carbon by carbonization.Figure _3 Scheme for obtaining nanofibrous carbon microspheres.Figure _4 Applications of keratin-derived carbon materials.Figure _5 Schematic view of the structure of sponges. The SEM images on the right show the sponge-based skeleton structure. Reprinted from Jesionowski, T.; Norman, M.; Zółtowska-Aksamitowska, S.; Petrenko, I.; Joseph, Y.; Ehrlich, H. Marine spongin: Naturally prefabricated 3D scaffold-based biomaterial. Mar. Drugs 2018, 16, https://doi.org/10.3390/md16030088 (licensed under CC BY 4.0)Figure _6 Turbostratic graphite-based 3D scaffold obtained after carbonization of microfibrous spongin at 1200ˇC.Figure _7 (a) Natural sources of silk; (b) The different hierarchical structures of fibers from the spider Araneus diadematus and the silkworm B. mori; (c) Schematics of the secondary structures of silk. Adapted from Strassburg, S.; Zainuddin, S.; Scheibel, T. The Power of Silk Technology for Energy Applications. Adv. Energy Mater. 2021, 11, https://doi.org/10.1002/aenm.202100519 (licensed under CC BY-NC 4.0, modification of section a) from original).Figure _8 SEM image of spider's web.The collection also included a file (References) with the list of literature used in the review paper:References - Literature cited in the publication.