Speciation of iron, nickel and cobalt in the anaerobic biodegradation of rice straw

Aimeé González-Suárez; Ileana Pereda-Reyes; Deny Oliva-Merencio; Silvio Jacinto Montalvo-Martínez

doi:10.17533/udea.redin.20200366

Authors

Aimeé González-Suárez Technological University of Havana "José Antonio Echeverría" (CUJAE)
Ileana Pereda-Reyes Technological University of Havana "José Antonio Echeverría" (CUJAE) https://orcid.org/0000-0001-6517-4202
Deny Oliva-Merencio Technological University of Havana "José Antonio Echeverría" (CUJAE)
Silvio Jacinto Montalvo-Martínez University of Santiago of Chile

DOI:

https://doi.org/10.17533/udea.redin.20200366

Keywords:

biogas, metals, mineral, productivity, waste treatment

Abstract

The bioavailability of Fe, Ni and Co and its impact on the mono-digestion of rice straw with addition of a natural nutrient source were assessed. The chemical forms and the degree of bioavailability of Fe, Ni and Co were investigated in two reactors during 311 days of experimentation at 37°C. The reactor (R2) was supplemented with 1 g/L of mineral once a week. The control reactor R1 was limited in mineral during the study. The greatest methane yield of 238 mL/g VS was obtained with mineral supply with an increment of 45% respect to reactor without metals (164 mL/g VS). The sequential extraction confirmed that 70, 88 and 75% of Fe, Ni and Co were mainly in bioavailable forms (interchangeable and carbonate), respectively, with mineral supply in R2. Fe and Co were mainly associated to the carbonate and oxidizable fractions (43% and 41% respectively), while the Ni concentrations were not detected during the experimentation. As a result, the methane yield in R2 increased by 45%, with a potential bioavailability (Ni > Co > Fe) higher compared to control reactor (Co > Fe). Trace elements deficit in R1 result in the reduction of metal-binding forms until the end of experiment, with a negative impact on methanogenic community.

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Author Biographies

Aimeé González-Suárez, Technological University of Havana "José Antonio Echeverría" (CUJAE)

Professor, Center for Process Engineering Studies (CIPRO).

Ileana Pereda-Reyes, Technological University of Havana "José Antonio Echeverría" (CUJAE)

Professor at the Engineering Process Centre, Research Director of CUJAE.

Deny Oliva-Merencio, Technological University of Havana "José Antonio Echeverría" (CUJAE)

Full-time Professor at the Renewable Energy Center, Vicerrector CUJAE.

Silvio Jacinto Montalvo-Martínez, University of Santiago of Chile

Chemical Engineering Professor, Environmental Biotechnology Laboratory.

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