Dynamics of microbial biomass nitrogen in relation to plant nitrogen uptake during the crop growth period in a dry tropical cropland in Tanzania

Sugihara, Soh; Funakawa, Shinya; Kilasara, Method; Kosaki, Takashi

doi:10.1111/j.1747-0765.2009.00428.x

Cited by 45 publications

(28 citation statements)

References 37 publications

(86 reference statements)

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“…Meanwhile, it can be said that critical N deficiency did not occur after the application of maize residues either through incorporation or mulching. Sugihara et al (2010a) showed that microorganism behaved as a sink of N through the decomposition of incorporated crop residue without a severe N deficiency in Tanzanian maize cropland.…”

Section: Effects Of Application Methods Of Crop Residues On the Dynamimentioning

confidence: 99%

Soil nitrogen dynamics under different quality and application methods of crop residues in maize croplands with contrasting soil textures in Tanzania

Nishigaki

Sugihara

Kilasara

et al. 2017

Soil Science and Plant Nutrition

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Soil nitrogen (N) dynamics in croplands need to be improved for the increase of food production in sub-Saharan Africa. Our objective was to investigate the crop residue management in terms of quality and application method to improve soil N dynamics during the period of crop growth in maize croplands with special reference to soil textures in dry tropical agroecosystems. Field experiments were conducted during the rainy seasons of 2012 and 2013 at clayey and sandy sites in Tanzania. Five treatment plots were established: plots with no residue applied (Ctrl plot), chemical fertilizer applied (F plot), maize residue (high C:N ratio = 60) incorporated (M-In plot) or mulched (M-On plot), and cowpea residue (low C:N ratio = 21) incorporated (P-In plot). In each plot, we regularly collected surface soil and crop samples and measured inorganic N (NO 3 −-N and NH 4 +-N), the soil respiration rate, and crop N uptake. Rainfall and soil moisture content were also continuously monitored. Our results showed that cowpea residue with high biodegradability caused prompt increases in the soil respiration rate and soil inorganic N because decomposition of the applied residue occurred within ca. 2 weeks after the application at both the clayey and sandy sites. It resulted in high N use efficiency in the early growing period and 18-73% higher total crop N uptake than that in the maize residue plots at both sites. The application methods (incorporation and mulching) showed no significant difference in soil N dynamics and crop yield, although higher soil respiration was observed in the M-In plot than the M-On plot at the clayey site. However, at the sandy site, mulching of maize residue resulted in the increased soil inorganic N content in the M-On plot by 18-26% compared with that in the M-In plot during the cropping season because of the higher soil moisture content. Consequently, crop N uptake in the mulching plot resulted in 26-59% higher than that in the incorporation plot.

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Section: Effects Of Application Methods Of Crop Residues On the Dynamimentioning

confidence: 99%

Soil nitrogen dynamics under different quality and application methods of crop residues in maize croplands with contrasting soil textures in Tanzania

Nishigaki

Sugihara

Kilasara

et al. 2017

Soil Science and Plant Nutrition

Self Cite

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“…Increasing microbial N uptake rates under sludge treatment leads to the possibility of improving nitrogen use efficiency in both soils. These results indicated that organic amendments with high C content as shown in sludge (Table 1) may increase the N immobilization by soil microbes, resulting in a lower rate and longer period of N uptake by plants [28]. Positive correlations were found between N uptake and both of the microbial N uptake and P fix in both clay soil (R = 0.96 and R = 0.98, resp.)…”

Section: Effect Of Different Nitrogen Sources On Microbial Biomass Nimentioning

confidence: 81%

“…Nitrogen uptake in rice shoot was determined by multiplying the N concentration by shoot dry weight. The total amount of microbial N absorbed by rice plant was determined by N difference method at maximum tillering stage [8,[25][26][27][28]. Amount of microbial N was calculated from the difference between the extractable N from fresh soil and autoclaved soil samples under the same treatment as shown in the following equation.…”

Section: Rice Plant Analysesmentioning

confidence: 99%

Effect of Nitrogen Sources on Microbial Biomass Nitrogen under Different Soil Types

El‐Sharkawi

2012

ISRN Soil Science

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Knowledge to increase the microbial biomass nitrogen (MBN) as a bulk of free-living microbes in paddy soil is limited. The potential benefit of these microorganisms was evaluated, in this study, under different nitrogen sources and two paddy soils. The results revealed that pots treated with organic matter recorded the maximum value of the total N uptake and MBN, followed by the Urea treated pots. Pots amended with sludge exhibited a higher microbial N forming ability than those amended with straw compost under both soils. But ammonium concentration in soil increased with straw compost application. Under fresh soil treatment, microbial N uptake rate and proportion of plant nitrogen derived from microbial nitrogen sources () were higher than autoclaved soil. A positive correlation was found between the and the total N in rice shoot in both soils. Finally, we can say that MBN was governed not only by the soil nitrogen content but also by the type of the nitrogen source. The addition of sludge to fresh soil increased total MBN and consequently could be indirectly beneficial to rice production especially in poor soils. Thus, soil microbes contribute to plant growth by serving the available nitrogen during the season.

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“…Therefore, it is necessary to reduce the N leaching resulting from heavy rainfall at the early crop growth stage (Shahandeh et al. 2004; Sugihara et al. 2010b).…”

Section: Discussionmentioning

confidence: 99%

“…In this season, the amount of N taken up by the crops is quite important for crop growth in later stages as well as yield. Therefore, it is necessary to reduce the N leaching resulting from heavy rainfall at the early crop growth stage (Shahandeh et al 2004;Sugihara et al 2010b). Judging from the THs-W plot where the level of inorganic N remained relatively steady for the first 100 h, increased In-situ-MB after the rainfall treatment was considered to immobilize the mineralized N after rewetting of the dry soil, and after 110 h, decreasing In-situ-MB in the THs-W plot appeared to supply 0.2 g N m )2 .…”

Section: Relationship Between Nitrogen Dynamics and Microbial Dynamicmentioning

confidence: 99%

In situshort-term carbon and nitrogen dynamics in relation to microbial dynamics after a simulated rainfall in croplands of different soil texture in Thailand

Sugihara

Funakawa

Kosaki

2010

Soil Science and Plant Nutrition

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The wetting–drying cycles of soil primarily drive carbon (C) and nitrogen (N) dynamics in tropical monsoon climates. We evaluated the in situ short‐term C and N dynamics and the effect of soil texture during a wetting–drying cycle in relation to hourly microbial dynamics. Two croplands of differing soil textures (clay [THc] and sand [THs]) in Thailand were used for the experiment. Hourly measurements of soil CO2 efflux and inorganic nitrogen (Inorg‐N) were conducted and we determined fluctuations in the in situ microbial biomass (In‐situ‐MB) and in situ microbial activity (In‐situ‐qCO2) after the application of a simulated rainfall (W plot) and a rainfall/glucose (WG plot) treatment. The rewetting of dry soil led to a C flush, which finished within 50–120 h because of rapid soil drying at both sites. Comparing the microbial dynamics in the THc‐W and THs‐W plots, it is clear that the rainfall treatment predominantly increased In‐situ‐qCO2 in the THc‐W plot, whereas it increased In‐situ‐MB in the THs‐W plot. These different microbial dynamics resulted in different C and N dynamics; that is, the cumulative soil CO2 efflux for the first 100 h after the treatment was effectively greater in the THs‐W plot (3.4 g C m−2) than in the THc‐W plot (2.8 g C m−2). In addition, distinct N‐mineralization associated with a decreasing In‐situ‐MB was observed only in the THs‐W plot, although this was not the case in the THc‐W plot. Hence, we concluded that rainfall events should play a more important role in the C and N dynamics in sandy soils compared with clayey soils because of different microbial dynamics after rewetting of a dry soil.

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Dynamics of microbial biomass nitrogen in relation to plant nitrogen uptake during the crop growth period in a dry tropical cropland in Tanzania

Cited by 45 publications

References 37 publications

Soil nitrogen dynamics under different quality and application methods of crop residues in maize croplands with contrasting soil textures in Tanzania

Soil nitrogen dynamics under different quality and application methods of crop residues in maize croplands with contrasting soil textures in Tanzania

Effect of Nitrogen Sources on Microbial Biomass Nitrogen under Different Soil Types

In situshort-term carbon and nitrogen dynamics in relation to microbial dynamics after a simulated rainfall in croplands of different soil texture in Thailand

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