A manganese-oxidizing bacterium-Enterobacter hormaechei strain DS02Eh01: Capabilities of Mn(II) immobilization, plant growth promotion and biofilm formation

“…The identification of MnOB is intended to confirm their oxidation capacity or taxonomic status. After the Mn 2+ is oxidized, the insoluble bioMnO x , which appears as black-brown, is often coated on the surface of MnOB [15,49]. As a result, the most direct method of determining oxidation ability is morphological observation.…”

“…The particle size range of bioMnO x is at the nanoscale [49], but it aggregates to a larger micrometer scale as aging time increases. According to Zhou and Fu [69], the surface area of bioMnO x , which ranges from 98 to 224 m 2 /g, is frequently greater than that of chemically synthesized MnO 2 .…”

“…Because of the cation vacancies in the crystal structure, bioMnO x is negatively charged [49]. These negative charges can be compensated for through cation intercalation and sorption, indicating the possibility of heavy metal removal (Figure 4).…”

A Review of Manganese-Oxidizing Bacteria (MnOB): Applications, Future Concerns, and Challenges

“…The identification of MnOB is intended to confirm their oxidation capacity or taxonomic status. After the Mn 2+ is oxidized, the insoluble bioMnO x , which appears as black-brown, is often coated on the surface of MnOB [15,49]. As a result, the most direct method of determining oxidation ability is morphological observation.…”

“…The particle size range of bioMnO x is at the nanoscale [49], but it aggregates to a larger micrometer scale as aging time increases. According to Zhou and Fu [69], the surface area of bioMnO x , which ranges from 98 to 224 m 2 /g, is frequently greater than that of chemically synthesized MnO 2 .…”

“…Because of the cation vacancies in the crystal structure, bioMnO x is negatively charged [49]. These negative charges can be compensated for through cation intercalation and sorption, indicating the possibility of heavy metal removal (Figure 4).…”

A Review of Manganese-Oxidizing Bacteria (MnOB): Applications, Future Concerns, and Challenges

Characteristics of biological manganese oxides produced by manganese-oxidizing bacteria H38 and its removal mechanism of oxytetracycline

In situ phytoextraction of Mn and NH4+-N from aqueous electrolytic manganese residue solution by Pistia stratiotes: Effects of Fe/Co presence and rhizospheric microbe synergistic involvement