Cyanobacterial promoted enrichment of rare earth elements europium, samarium and neodymium and intracellular europium particle formation

Christian B Fischer; Susanne Körsten; Liz M Rösken; Felix Cappel; Christian Beresko; Georg Ankerhold; Andreas Schönleber; Stefan Geimer; Dennis Ecker; Stefan Wehner

doi:10.1039/c9ra06570a

Cyanobacterial promoted enrichment of rare earth elements europium, samarium and neodymium and intracellular europium particle formation

RSC Adv. 2019 Oct 11;9(56):32581-32593. doi: 10.1039/c9ra06570a. eCollection 2019 Oct 10.

Authors

Affiliations

¹ University of Koblenz-Landau, Campus Koblenz, Department of Physics, Universitätsstraße 1 56070 Koblenz Germany chrbfischer@uni-koblenz.de.
² Mohammed VI Polytechnic University, Materials Science and Nano-Engineering Department Lot 660, Hay Moulay Rachid 43150 Benguerir Morocco.
³ University of Applied Sciences Koblenz, RheinAhrCampus, Department of Laser Spectroscopy Joseph-Rovan-Allee 2 53424 Remagen Germany.
⁴ University of Bayreuth, Laboratory of Crystallography 95447 Bayreuth Germany.
⁵ University of Bayreuth, Cell Biology and Electron Microscopy 95447 Bayreuth Germany.
⁶ Federal Institute of Hydrology, Department G2-Aquatic Chemistry Am Mainzer Tor 1 56068 Koblenz Germany.

Abstract

In the recovery of rare earth elements (REE) microbial biosorption has shown its theoretical ability as an extremely economically and environmentally friendly production method in the last few years. To evaluate the ability of two cyanobacterial strains, namely Anabaena spec. and Anabaena cylindrica to enrich dissolved trivalent REE, a simple protocol was followed. The REE tested in this study include some of the most prominent representatives, such as europium (Eu), samarium (Sm) and neodymium (Nd). Within the experiments, a fast decrease of the REE³⁺ concentration in solution was tracked by inductively coupled plasma mass spectrometry (ICP-MS). It revealed an almost complete (>99%) biosorption of REE³⁺ within the first hour after the addition of metal salts. REE³⁺ uptake by biomass was checked using laser-induced breakdown spectroscopy (LIBS) and showed that all three selected REE³⁺ species were enriched in the cyanobacterial biomass and the process is assigned to a biosorption process. Although the biomass stayed alive during the experiments, up to that, a distinction whether the REE³⁺ was intra- or extracellularly sorbed was not possible, since biosorption is a metabolism independent process which occurs on living as well as non-living biomass. For europium it was shown by TEM that electron dense particles, presumably europium particles with particle sizes of about 15 nm, are located inside the vegetative cyanobacterial cells. This gave clear evidence that Eu³⁺ was actively sorbed by living cyanobacteria. Eu³⁺ biosorption by cell wall precipitation due to interaction with extracellular polysaccharides (EPS) could therefore be excluded. Finally, with XRD analysis it was shown that the detected europium particles had an amorphous instead of a crystalline structure. Herein, we present a fast biosorptive enrichment of the rare earth elements europium, samarium and neodymium by Anabaena spec. and Anabaena cylindrica and for the first time the subsequent formation of intracellular europium particles by Anabaena spec.