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Formation of nano-crystalline todorokite from biogenic Mn oxides |
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| Authors: | Xiong Han Feng Mengqiang Zhu Chaoying Ni Donald L Sparks |
| Institution: | a Environmental Soil Chemistry Research Group, Department of Plant and Soil Sciences and Center for Critical Zone Research, 152 Townsend Hall, University of Delaware, Newark, DE 19716, USA b Delaware Environmental Institute, University of Delaware, Newark, DE 19716, USA c Department of Materials Science and Engineering, 201 Dupont Hall, University of Delaware, Newark, DE 19716, USA |
| Abstract: | Todorokite, as one of three main Mn oxide phases present in oceanic Mn nodules and an active MnO6 octahedral molecular sieve (OMS), has garnered much interest; however, its formation pathway in natural systems is not fully understood. Todorokite is widely considered to form from layer structured Mn oxides with hexagonal symmetry, such as vernadite (δ-MnO2), which are generally of biogenic origin. However, this geochemical process has not been documented in the environment or demonstrated in the laboratory, except for precursor phases with triclinic symmetry. Here we report on the formation of a nanoscale, todorokite-like phase from biogenic Mn oxides produced by the freshwater bacterium Pseudomonas putida strain GB-1. At long- and short-range structural scales biogenic Mn oxides were transformed to a todorokite-like phase at atmospheric pressure through refluxing. Topotactic transformation was observed during the transformation. Furthermore, the todorokite-like phases formed via refluxing had thin layers along the c∗ axis and a lack of c∗ periodicity, making the basal plane undetectable with X-ray diffraction reflection. The proposed pathway of the todorokite-like phase formation is proposed as: hexagonal biogenic Mn oxide → 10-Å triclinic phyllomanganate → todorokite. These observations provide evidence supporting the possible bio-related origin of natural todorokites and provide important clues for understanding the transformation of biogenic Mn oxides to other Mn oxides in the environment. Additionally this method may be a viable biosynthesis route for porous, nano-crystalline OMS materials for use in practical applications. |
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