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Biogas digestate as a renewable fertilizer: effects of digestate application on crop growth and nutrient composition

Published online by Cambridge University Press:  29 June 2020

Maxwell E. Lee ,
Matthew W. Steiman  and
Sarah K. St. Angelo Open the ORCID record for Sarah K. St. Angelo [Opens in a new window]
Maxwell E. Lee
Affiliation:
Department of Chemistry, Dickinson College, CarlislePA17013, USA Department of Environmental Science, Dickinson College, CarlislePA17013, USA Dickinson College Farm, Boiling SpringsPA17007, USA
Matthew W. Steiman
Affiliation:
Dickinson College Farm, Boiling SpringsPA17007, USA
Sarah K. St. Angelo*
Affiliation:
Department of Chemistry, Dickinson College, CarlislePA17013, USA
*
Author for correspondence: Sarah K. St. Angelo, E-mail: stangels@dickinson.edu
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Abstract

Biogas digesters convert waste matter into a natural gas-like fuel and a nutrient-rich digestate by-product. This digestate has the potential to be used as a soil amendment to benefit crop production with or without biochar, a purported nutrient sponge. In a greenhouse study of several crop species, the effects of digestate fertilization on crop growth, photosynthetic efficiency, vegetable production and chemical nutrient levels were tested. Results indicate that increasing potency of the applied digestate fosters higher growth and fruit production rates of several studied plants but to a lesser degree than a conventional fertilizer. More potent digestate application increases antioxidant capacity, total phenolics content and ascorbic acid levels in kale compared to the control chemical fertilizer test groups but has confounding results on legume nutrient levels. Additionally, the combined application of biochar and biogas digestate added to compost and used as potting media positively impacts crop germination. This work has relevance to agrarian communities that could benefit from recycling livestock and food waste into fuel and a renewable fertilizer.

Keywords

Anaerobic digestionanalytical chemistryantioxidantsbiocharbiogas digestatecomposteffluentrenewable agricultureslurry
Type
Research Paper
Information
Renewable Agriculture and Food Systems , Volume 36 , Issue 2 , April 2021 , pp. 173 - 181
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Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

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