Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia
Proper fertilizer management and applications could effectively reduce global warming potential (GWP) and improving soil fertility under cereal production. However, the effect of soil fertilizer management practices on GWP and soil fertility is less understood in the agricultural soils of Ethiopia....
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2022-02-01
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author | Gebeyanesh Worku Zerssa Philipp Koal Bettina Eichler-Löbermann |
author_facet | Gebeyanesh Worku Zerssa Philipp Koal Bettina Eichler-Löbermann |
author_sort | Gebeyanesh Worku Zerssa |
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description | Proper fertilizer management and applications could effectively reduce global warming potential (GWP) and improving soil fertility under cereal production. However, the effect of soil fertilizer management practices on GWP and soil fertility is less understood in the agricultural soils of Ethiopia. The present study evaluated the effects of fertilizer application strategy on GWP, and soil fertility in a Nitisol. Both field and laboratory incubation experiments were conducted with the same treatments. Seven treatments (Cont: no input; 100 min: 100% mineral fertilizer, 80 min: 80% mineral fertilizer + 1.4 t ha<sup>−1</sup> compost; 60 min: 60% mineral fertilizer + 2.8 t ha<sup>−1</sup> compost; 50 min: 50% mineral fertilizer + 3.5 t ha<sup>−1</sup> compost; 30 min: 30% mineral fertilizer + 4.9 t ha<sup>−1</sup> compost, and 100 comp: 100% compost) with four replications were applied on maize crop (<i>Zea mays</i> L. Bako hybrid 661) for two consecutive growing seasons. The laboratory incubation experiment was also carried out with two moisture levels (40% and 75% of water-filled pore space) to simulate the seasonal rainfall pattern. GWP was calculated by summing up the quantified gas emissions of nitrous oxide (N<sub>2</sub>O), carbon dioxide (CO<sub>2</sub>), and methane (CH<sub>4</sub>). The laboratory result for GWP shown that soil fertilized with mineral fertilizer alone was significantly (<i>p</i> < 0.05) increased by 27–34% of the average GWP compared to combined fertilizer treatments in the soil at a moisture level of 75%. From the field experiment, most plant nutrients were significantly increased in combined fertilizer treatments compared to sole mineral fertilizer application. For example, carbon, calcium, magnesium and potassium were increased by 26.2–39.8%, 73.2–168.8%, 146.6–251.5% and 47–99% respectively in combined fertilizer compared to 100 min treatment. The study revealed that combining 30 or 50 kg N ha<sup>−1</sup> of mineral fertilizer with biowaste compost (4.9 or 3.5 t ha<sup>−1</sup>) would be a suitable combination to mitigate the GWP and improve soil quality in smallholder farming systems, due to a slow release of N during decomposition into the soil compared to mineral fertilizer alone. However, to evaluate GWP under the field conditions, future investigations are recommended. |
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spelling | doaj.art-a0f820a55f534f02aafc41711c6ef65f2023-11-17T10:17:23ZengMDPI AGChemistry Proceedings2673-45832022-02-011015110.3390/IOCAG2022-12180Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern EthiopiaGebeyanesh Worku Zerssa0Philipp Koal1Bettina Eichler-Löbermann2Department of Agronomy and Crop Science, Faculty of Agricultural and Environmental Sciences, University of Rostock, J. von Liebig Weg 6, 18059 Rostock, GermanyForestry Research and Competence Center, Thüringen Forst, Jägerstr. 1, 99876 Gotha, GermanyDepartment of Agronomy and Crop Science, Faculty of Agricultural and Environmental Sciences, University of Rostock, J. von Liebig Weg 6, 18059 Rostock, GermanyProper fertilizer management and applications could effectively reduce global warming potential (GWP) and improving soil fertility under cereal production. However, the effect of soil fertilizer management practices on GWP and soil fertility is less understood in the agricultural soils of Ethiopia. The present study evaluated the effects of fertilizer application strategy on GWP, and soil fertility in a Nitisol. Both field and laboratory incubation experiments were conducted with the same treatments. Seven treatments (Cont: no input; 100 min: 100% mineral fertilizer, 80 min: 80% mineral fertilizer + 1.4 t ha<sup>−1</sup> compost; 60 min: 60% mineral fertilizer + 2.8 t ha<sup>−1</sup> compost; 50 min: 50% mineral fertilizer + 3.5 t ha<sup>−1</sup> compost; 30 min: 30% mineral fertilizer + 4.9 t ha<sup>−1</sup> compost, and 100 comp: 100% compost) with four replications were applied on maize crop (<i>Zea mays</i> L. Bako hybrid 661) for two consecutive growing seasons. The laboratory incubation experiment was also carried out with two moisture levels (40% and 75% of water-filled pore space) to simulate the seasonal rainfall pattern. GWP was calculated by summing up the quantified gas emissions of nitrous oxide (N<sub>2</sub>O), carbon dioxide (CO<sub>2</sub>), and methane (CH<sub>4</sub>). The laboratory result for GWP shown that soil fertilized with mineral fertilizer alone was significantly (<i>p</i> < 0.05) increased by 27–34% of the average GWP compared to combined fertilizer treatments in the soil at a moisture level of 75%. From the field experiment, most plant nutrients were significantly increased in combined fertilizer treatments compared to sole mineral fertilizer application. For example, carbon, calcium, magnesium and potassium were increased by 26.2–39.8%, 73.2–168.8%, 146.6–251.5% and 47–99% respectively in combined fertilizer compared to 100 min treatment. The study revealed that combining 30 or 50 kg N ha<sup>−1</sup> of mineral fertilizer with biowaste compost (4.9 or 3.5 t ha<sup>−1</sup>) would be a suitable combination to mitigate the GWP and improve soil quality in smallholder farming systems, due to a slow release of N during decomposition into the soil compared to mineral fertilizer alone. However, to evaluate GWP under the field conditions, future investigations are recommended.https://www.mdpi.com/2673-4583/10/1/51organic fertilizersoil qualitygreenhouse gasNitisol |
spellingShingle | Gebeyanesh Worku Zerssa Philipp Koal Bettina Eichler-Löbermann Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia Chemistry Proceedings organic fertilizer soil quality greenhouse gas Nitisol |
title | Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia |
title_full | Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia |
title_fullStr | Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia |
title_full_unstemmed | Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia |
title_short | Fertilizer Management Strategy to Reduce Global Warming Potential and Improve Soil Fertility in a Nitisol in Southwestern Ethiopia |
title_sort | fertilizer management strategy to reduce global warming potential and improve soil fertility in a nitisol in southwestern ethiopia |
topic | organic fertilizer soil quality greenhouse gas Nitisol |
url | https://www.mdpi.com/2673-4583/10/1/51 |
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