Abstract
The usage of biomineralization processes performed by living microalgae to create 3D nanostructured materials are advantageous compared to conventional synthesis routes. Exploitation of in vivo shaping using living cells leads to inorganic intricate biominerals, produced with low environmental impact. Since biomineralization processes are genetically controlled, the formation of nanostructured materials is highly reproducible. The shells of microalgae, like coccoliths, are particularly of great interest. This study shows the generation of mesoporous highly structured functional materials with induced optoelectronical properties using in vivo processes of the microalga species Emiliania huxleyi. It demonstrates the metabolically driven incorporation of the lanthanide terbium into the coccoliths of E. huxleyi as a route for the synthesis of finely patterned photoluminescent particles by feeding the microalgae with this luminescent element. The resulting green luminescent particles have hierarchical ordered pores on the nano- and microscale and may act as powerful tools for many applications; they may serve as imaging probes for biomedical applications, or in microoptics. The luminescent coccoliths combine a unique hierarchical structure with a characteristic luminescence pattern, which make them superior to conventional produced Tb doted material. With this study, the possibility of the further exploitation of coccoliths as advanced functional materials for nanotechnological applications is given.
Highlights
The usage of biomineralization processes performed by living microalgae to control, their formation and their create 3D nanostructured materials are advantageous compared to conventional synthesis routes
The aim was that the microalgae take up the Tb3+ out of the medium into the cell and subsequently incorporate them into their coccoliths via biomineralization processes
Since the biomineralization of the coccoliths is intracellular and only takes place in living cells, it is crucial that the Tb3+ concentration is not toxic for the microalgae
Summary
According to our successful incorporation of Zn2+ into E. huxleyi coccoliths,[15] we applied Tb3+ via the nutrition medium. The cv and in the coccolith underlies two different mechanisms: Ca2+ is pumped into the cv to keep its level always close to saturation for precipitation of calcite, in contrast, Sr2+ is transported into the cv according to its value at the cell surface and in the medium.[10,11] Metal ions principally enter microalgae cells by first binding onto the cell surface, afterward they are actively transported into the cell.[36] Since lanthanides have the same ionic radii as calcium ions, and it was shown that they can replace Ca2+ in its functions in microalgae,[30] we suggest that the Tb3+ used in our studies are transported to the coccolith vesicle and incorporated into the coccoliths via the Ca2+ pathway This Tb-transport mechanism seems to be independent from the Sr transport; the Sr2+ in the coccoliths are not replaced by Tb3+, resulting in constant Sr/ Ca ratios (independent of the Tb3+ content). This nanoporosity allows their further use as functional devices for example, nanotechnological applications or for labeling documents to make them fraud-resistant
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
