Valorization of nitrogen-rich melamine as a nitrogen source in the production of maize (Zea mays L.)

Maize is important for the biofuel and bio-based products. Building a clean maize production system could minimize the environment pollution from the N loss from the sloping land and achieve the industrial sustainable development. As a nitrogen-rich source, melamine could be used as a slow-release n...

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Published inIndustrial crops and products Vol. 199; p. 116770
Main Authors Shi, Dan, Shrestha, Ram Kumar, Obaid, Hikmatullah, Elsayed, Nader Saad, Zhong, Shouqin, Hashimi, Mohammad Hanif, Cheng, Yongyi, Xie, Deti, Ni, Chengsheng, Ni, Jiupai
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.09.2023
Subjects
agricultural soils
biofuels
corn
enzyme-linked immunosorbent assay
grain yield
irrigation
Maize
Maize production system
melamine
Melamine waste
N leaching
N use efficiency
nitrogen
nitrogen fertilizers
pollution
sulfur
sustainable development
total nitrogen
urea
wastes
Zea mays
Melamine waste
Maize
N use efficiency
N leaching
Maize production system
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Abstract Maize is important for the biofuel and bio-based products. Building a clean maize production system could minimize the environment pollution from the N loss from the sloping land and achieve the industrial sustainable development. As a nitrogen-rich source, melamine could be used as a slow-release nitrogen (N) fertilizer, which provides a route for the recycling of melamine waste and the combatting of N loss from fertilizers. Model N release of melamine was compared with urea, sulfur(S)-coated urea via N loss in leaching column under intermittent leaching and under the ploughing fertilizer in the farmland soil. Only 7.12 % of the total nitrogen (TN) was lost from the 21 irrigation events, while the loss of TN from urea reached 77.28 %. TN from urea would be release totally in soil within 14 days in the ploughing fertilizer experiment, but 62 % of melamine was remained after 144 days. In order to evaluate the efficacy of melamine as an N fertilizer, plot experiments with an N rate of 180 kg ha-1 were carried out using pure melamine, urea and S-coated urea as well as mixed melamine/urea at 2:8, 1:1 and 7:3 by the N ratio. Melamine fertilization alone was unable to satisfy the N demand of maize, but the melamine/urea mixture (1:1) was comparable to the commercial S-coated urea in both years in terms of the grain yield (2217 kg ha-1 in 2019, 2368 kg ha-1 in 2020), total aboveground dry matter (5076 kg ha-1 in 2019, 4815 kg ha-1 in 2020), aboveground N uptake (36 kg ha-1 in 2019, 48 kg ha-1 in 2020), partial factor productivity of nitrogen (12.32 kg kg-1 in 2019 and 13.16 kg kg-1 in 2020) and net return (1474 USD in 2019, 1606 USD in 2020). Melamine accumulation in the maize grain measured from ELISA (enzyme-linked immunosorbent assay) ranged from 0.24 to 1.8 mg kg-1. The valorization of the melamine waste into N fertilizer by blending with urea was a possible way of reducing melamine pollution, alleviating N loss in hilly area and building a recyclable agriculture system. [Display omitted] •Valorization of melamine as a slow release was studied in lab and field experiment.•Melamine and urea at one to one ratio suffice the N need of maize.•Melamine for N fertilizer would decrease the N loss in the maize production system.•Melamine and urea at one to one ratio acquired high nitrogen uptake and grain yield in maize production system.
AbstractList Maize is important for the biofuel and bio-based products. Building a clean maize production system could minimize the environment pollution from the N loss from the sloping land and achieve the industrial sustainable development. As a nitrogen-rich source, melamine could be used as a slow-release nitrogen (N) fertilizer, which provides a route for the recycling of melamine waste and the combatting of N loss from fertilizers. Model N release of melamine was compared with urea, sulfur(S)-coated urea via N loss in leaching column under intermittent leaching and under the ploughing fertilizer in the farmland soil. Only 7.12 % of the total nitrogen (TN) was lost from the 21 irrigation events, while the loss of TN from urea reached 77.28 %. TN from urea would be release totally in soil within 14 days in the ploughing fertilizer experiment, but 62 % of melamine was remained after 144 days. In order to evaluate the efficacy of melamine as an N fertilizer, plot experiments with an N rate of 180 kg ha-1 were carried out using pure melamine, urea and S-coated urea as well as mixed melamine/urea at 2:8, 1:1 and 7:3 by the N ratio. Melamine fertilization alone was unable to satisfy the N demand of maize, but the melamine/urea mixture (1:1) was comparable to the commercial S-coated urea in both years in terms of the grain yield (2217 kg ha-1 in 2019, 2368 kg ha-1 in 2020), total aboveground dry matter (5076 kg ha-1 in 2019, 4815 kg ha-1 in 2020), aboveground N uptake (36 kg ha-1 in 2019, 48 kg ha-1 in 2020), partial factor productivity of nitrogen (12.32 kg kg-1 in 2019 and 13.16 kg kg-1 in 2020) and net return (1474 USD in 2019, 1606 USD in 2020). Melamine accumulation in the maize grain measured from ELISA (enzyme-linked immunosorbent assay) ranged from 0.24 to 1.8 mg kg-1. The valorization of the melamine waste into N fertilizer by blending with urea was a possible way of reducing melamine pollution, alleviating N loss in hilly area and building a recyclable agriculture system. [Display omitted] •Valorization of melamine as a slow release was studied in lab and field experiment.•Melamine and urea at one to one ratio suffice the N need of maize.•Melamine for N fertilizer would decrease the N loss in the maize production system.•Melamine and urea at one to one ratio acquired high nitrogen uptake and grain yield in maize production system.
Maize is important for the biofuel and bio-based products. Building a clean maize production system could minimize the environment pollution from the N loss from the sloping land and achieve the industrial sustainable development. As a nitrogen-rich source, melamine could be used as a slow-release nitrogen (N) fertilizer, which provides a route for the recycling of melamine waste and the combatting of N loss from fertilizers. Model N release of melamine was compared with urea, sulfur(S)-coated urea via N loss in leaching column under intermittent leaching and under the ploughing fertilizer in the farmland soil. Only 7.12% of the total nitrogen (TN) was lost from the 21 irrigation events, while the loss of TN from urea reached 77.28%. TN from urea would be release totally in soil within 14 days in the ploughing fertilizer experiment, but 62% of melamine was remained after 144 days. In order to evaluate the efficacy of melamine as an N fertilizer, plot experiments with an N rate of 180kgha⁻¹ were carried out using pure melamine, urea and S-coated urea as well as mixed melamine/urea at 2:8, 1:1 and 7:3 by the N ratio. Melamine fertilization alone was unable to satisfy the N demand of maize, but the melamine/urea mixture (1:1) was comparable to the commercial S-coated urea in both years in terms of the grain yield (2217kgha⁻¹ in 2019, 2368kgha⁻¹ in 2020), total aboveground dry matter (5076kgha⁻¹ in 2019, 4815kgha⁻¹ in 2020), aboveground N uptake (36kgha⁻¹ in 2019, 48kgha⁻¹ in 2020), partial factor productivity of nitrogen (12.32kgkg⁻¹ in 2019 and 13.16kgkg⁻¹ in 2020) and net return (1474 USD in 2019, 1606 USD in 2020). Melamine accumulation in the maize grain measured from ELISA (enzyme-linked immunosorbent assay) ranged from 0.24 to 1.8mgkg⁻¹. The valorization of the melamine waste into N fertilizer by blending with urea was a possible way of reducing melamine pollution, alleviating N loss in hilly area and building a recyclable agriculture system.
ArticleNumber 116770
Author Elsayed, Nader Saad
Xie, Deti
Obaid, Hikmatullah
Ni, Jiupai
Zhong, Shouqin
Shi, Dan
Hashimi, Mohammad Hanif
Shrestha, Ram Kumar
Cheng, Yongyi
Ni, Chengsheng
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crossref_primary_10_1016_j_powtec_2024_120297
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Keywords Melamine waste
Maize
N use efficiency
N leaching
Maize production system
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Snippet Maize is important for the biofuel and bio-based products. Building a clean maize production system could minimize the environment pollution from the N loss...
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SubjectTerms agricultural soils
biofuels
corn
enzyme-linked immunosorbent assay
grain yield
irrigation
Maize
Maize production system
melamine
Melamine waste
N leaching
N use efficiency
nitrogen
nitrogen fertilizers
pollution
sulfur
sustainable development
total nitrogen
urea
wastes
Zea mays
Title Valorization of nitrogen-rich melamine as a nitrogen source in the production of maize (Zea mays L.)
URI https://dx.doi.org/10.1016/j.indcrop.2023.116770
https://www.proquest.com/docview/2834248958
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