Application of High Carbon:Nitrogen  Material Enhanced the Formation of the Soil A Horizon and Nitrogen Fixation in a Tropical Agricultural Field

Masato Oda; Kenji Tamura; Hiroko Nakatsuka; Miki Nakata; Yukimi Hayashi

doi:10.4236/as.2014.512127

Agricultural Sciences > Vol.5 No.12, October 2014

Application of High Carbon:Nitrogen Material Enhanced the Formation of the Soil A Horizon and Nitrogen Fixation in a Tropical Agricultural Field

Masato Oda^1*, Kenji Tamura², Hiroko Nakatsuka³, Miki Nakata⁴, Yukimi Hayashi⁵
¹Livestock & Environment, Japan International Research Center for Agricultural Sciences, Tsukuba, Japan.
²Faculty of Life and Environmental Sciences, University of Tsukuba, Tsukuba, Japan.
³Graduate School of Life and Environmental Sciences, University of Tsukuba, Tsukuba, Japan.
⁴Faculty of Life and Environmental Sciences, University of Yamanashi, Yamanashi, Japan.
⁵Sitio TKM, Sao Paulo, Brazil.
DOI: 10.4236/as.2014.512127 PDF HTML XML 5,331 Downloads 7,249 Views Citations

Abstract

It is known that cropping causes soil carbon loss, which is a critical issue, especially in tropical agriculture. Nitrogen input generally increases net primary production but does not increase soil carbon content because nitrogen input enhances soil organic carbon mineralization by microorganisms. A farmer conducted a trial in which he applied material with a high carbon:nitrogen (C:N) ratio without additional nitrogen fertilizer, and achieved a higher productivity than that of conventional farms. Based on his results, we conducted a survey to evaluate the effects of high C:N ratio organic material on the productivity, soil profile, microbial activity, and carbon and nitrogen balance of soil. Results demonstrate that high C:N ratio organic material enhanced the formation of the soil A horizon and increased soil carbon and nitrogen content. Approximately, 15 - 20 t·ha^-1·crop^-1 of fresh waste mushroom bed was applied to 15 crops over 4.5 years, and the total input of carbon and nitrogen were 5014 and 129 g·m^-2, respectively. The soil nitrate nitrogen concentration was the same as that of the neighboring forest soil, which was lower than the standard limit for conventional agriculture; however, the average productivity of crops was approximately four times that of the national average. The soil Ap horizon increased in thickness by 7 cm, and aggregates reached a thickness of 29 cm in 4.5 years. The output/input ratios of total soil nitrogen and carbon were approximately 2.68 - 6.00 and 1.30 - 2.35, respectively, indicating that this method will maintain the carbon and nitrogen balance of the system. The observed soil microbial activity was one order of magnitude higher than that of a fallow field. The results indicate that this agricultural method remediates soil degradation, and improves food production.

Keywords

Carbon, Food Security, Microorganisms, Nitrogen, Soil Degradation

Share and Cite:

Oda, M. , Tamura, K. , Nakatsuka, H. , Nakata, M. and Hayashi, Y. (2014) Application of High Carbon:Nitrogen Material Enhanced the Formation of the Soil A Horizon and Nitrogen Fixation in a Tropical Agricultural Field. Agricultural Sciences, 5, 1172-1181. doi: 10.4236/as.2014.512127.

Conflicts of Interest

The authors declare no conflicts of interest.

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