Effects of alternating wetting and drying versus continuous flooding on fertilizer nitrogen fate in rice fields in the Mekong Delta, Vietnam

Minh Dong Nguyen; Kristian Koefoed Brandt; Jan Sørensen; Ngo Ngoc Hung; Chu Van Hach; Pham Sy Tan; Tage Dalsgaard

doi:10.1016/j.soilbio.2011.12.028

Effects of alternating wetting and drying versus continuous flooding on fertilizer nitrogen fate in rice fields in the Mekong Delta, Vietnam

Minh Dong Nguyen, Kristian Koefoed Brandt, Jan Sørensen, Ngo Ngoc Hung, Chu Van Hach, Pham Sy Tan, Tage Dalsgaard

99 Citations (Scopus)

Abstract

Alternate wetting and drying (AWD) irrigation is projected to replace continuous flooding (CF) irrigation for rice production in parts of the Mekong delta area during the dry season. A dry season field experiment was conducted in Mekong delta alluvial soil to compare N cycle processes and agronomic parameters under AWD and CF water management schemes. ¹⁵N-labeled urea was applied in microplots to follow the fate of fertilizer N. The major loss of fertilizer N occurred through ammonia volatilization amounting to 21% and 13% of the applied N in the AWD and CF treatments, respectively. Ammonia volatilization was largely controlled by soil and floodwater pH which determined the NH3/NH4+ ratio.Irrespective of water management, 10-12% of the fertilizer N could be recovered from the top soil (0-15cm) after harvest, whereas 10% of fertilizer N accumulated in deeper soil horizons (15-50cm). Even though the loss of fertilizer N through nitrification-denitrification was 6 fold higher under AWD than CF (0.22 versus 0.04gNm ^-2) it only removed 2.5% of the applied fertilizer and was thus quantitatively insignificant. Overall, net N mineralization and potential nitrification in the top soil were stimulated by the AWD treatment, whereas the difference in water management practice did not affect N uptake by the plants, aboveground biomass, or grain yield. Fertilizer N contributed only around 20% of the N uptake by the plants probably because the soil was rich in N, which was deposited during the preceding flooding season. Although based on data from one dry season crop only, our study indicates that future implementation of AWD irrigation is unlikely to adversely affect crop yields by loss of fertilizer N in intensive rice production systems in the Mekong delta.

Original language	English
Journal	Soil Biology & Biochemistry
Volume	47
Pages (from-to)	166-174
Number of pages	9
ISSN	0038-0717
DOIs	https://doi.org/10.1016/j.soilbio.2011.12.028
Publication status	Published - Apr 2012

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10.1016/j.soilbio.2011.12.028

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@article{a202eaa01dcb4a9c9ed03f508bb95e71,

title = "Effects of alternating wetting and drying versus continuous flooding on fertilizer nitrogen fate in rice fields in the Mekong Delta, Vietnam",

abstract = "Alternate wetting and drying (AWD) irrigation is projected to replace continuous flooding (CF) irrigation for rice production in parts of the Mekong delta area during the dry season. A dry season field experiment was conducted in Mekong delta alluvial soil to compare N cycle processes and agronomic parameters under AWD and CF water management schemes. 15N-labeled urea was applied in microplots to follow the fate of fertilizer N. The major loss of fertilizer N occurred through ammonia volatilization amounting to 21% and 13% of the applied N in the AWD and CF treatments, respectively. Ammonia volatilization was largely controlled by soil and floodwater pH which determined the NH3/NH4+ ratio.Irrespective of water management, 10-12% of the fertilizer N could be recovered from the top soil (0-15cm) after harvest, whereas 10% of fertilizer N accumulated in deeper soil horizons (15-50cm). Even though the loss of fertilizer N through nitrification-denitrification was 6 fold higher under AWD than CF (0.22 versus 0.04gNm -2) it only removed 2.5% of the applied fertilizer and was thus quantitatively insignificant. Overall, net N mineralization and potential nitrification in the top soil were stimulated by the AWD treatment, whereas the difference in water management practice did not affect N uptake by the plants, aboveground biomass, or grain yield. Fertilizer N contributed only around 20% of the N uptake by the plants probably because the soil was rich in N, which was deposited during the preceding flooding season. Although based on data from one dry season crop only, our study indicates that future implementation of AWD irrigation is unlikely to adversely affect crop yields by loss of fertilizer N in intensive rice production systems in the Mekong delta.",

author = "Nguyen, {Minh Dong} and Brandt, {Kristian Koefoed} and Jan S{\o}rensen and Hung, {Ngo Ngoc} and Hach, {Chu Van} and Tan, {Pham Sy} and Tage Dalsgaard",

year = "2012",

month = apr,

doi = "10.1016/j.soilbio.2011.12.028",

language = "English",

volume = "47",

pages = "166--174",

journal = "Soil Biology & Biochemistry",

issn = "0038-0717",

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TY - JOUR

T1 - Effects of alternating wetting and drying versus continuous flooding on fertilizer nitrogen fate in rice fields in the Mekong Delta, Vietnam

AU - Nguyen, Minh Dong

AU - Brandt, Kristian Koefoed

AU - Sørensen, Jan

AU - Hung, Ngo Ngoc

AU - Hach, Chu Van

AU - Tan, Pham Sy

AU - Dalsgaard, Tage

PY - 2012/4

Y1 - 2012/4

N2 - Alternate wetting and drying (AWD) irrigation is projected to replace continuous flooding (CF) irrigation for rice production in parts of the Mekong delta area during the dry season. A dry season field experiment was conducted in Mekong delta alluvial soil to compare N cycle processes and agronomic parameters under AWD and CF water management schemes. 15N-labeled urea was applied in microplots to follow the fate of fertilizer N. The major loss of fertilizer N occurred through ammonia volatilization amounting to 21% and 13% of the applied N in the AWD and CF treatments, respectively. Ammonia volatilization was largely controlled by soil and floodwater pH which determined the NH3/NH4+ ratio.Irrespective of water management, 10-12% of the fertilizer N could be recovered from the top soil (0-15cm) after harvest, whereas 10% of fertilizer N accumulated in deeper soil horizons (15-50cm). Even though the loss of fertilizer N through nitrification-denitrification was 6 fold higher under AWD than CF (0.22 versus 0.04gNm -2) it only removed 2.5% of the applied fertilizer and was thus quantitatively insignificant. Overall, net N mineralization and potential nitrification in the top soil were stimulated by the AWD treatment, whereas the difference in water management practice did not affect N uptake by the plants, aboveground biomass, or grain yield. Fertilizer N contributed only around 20% of the N uptake by the plants probably because the soil was rich in N, which was deposited during the preceding flooding season. Although based on data from one dry season crop only, our study indicates that future implementation of AWD irrigation is unlikely to adversely affect crop yields by loss of fertilizer N in intensive rice production systems in the Mekong delta.

AB - Alternate wetting and drying (AWD) irrigation is projected to replace continuous flooding (CF) irrigation for rice production in parts of the Mekong delta area during the dry season. A dry season field experiment was conducted in Mekong delta alluvial soil to compare N cycle processes and agronomic parameters under AWD and CF water management schemes. 15N-labeled urea was applied in microplots to follow the fate of fertilizer N. The major loss of fertilizer N occurred through ammonia volatilization amounting to 21% and 13% of the applied N in the AWD and CF treatments, respectively. Ammonia volatilization was largely controlled by soil and floodwater pH which determined the NH3/NH4+ ratio.Irrespective of water management, 10-12% of the fertilizer N could be recovered from the top soil (0-15cm) after harvest, whereas 10% of fertilizer N accumulated in deeper soil horizons (15-50cm). Even though the loss of fertilizer N through nitrification-denitrification was 6 fold higher under AWD than CF (0.22 versus 0.04gNm -2) it only removed 2.5% of the applied fertilizer and was thus quantitatively insignificant. Overall, net N mineralization and potential nitrification in the top soil were stimulated by the AWD treatment, whereas the difference in water management practice did not affect N uptake by the plants, aboveground biomass, or grain yield. Fertilizer N contributed only around 20% of the N uptake by the plants probably because the soil was rich in N, which was deposited during the preceding flooding season. Although based on data from one dry season crop only, our study indicates that future implementation of AWD irrigation is unlikely to adversely affect crop yields by loss of fertilizer N in intensive rice production systems in the Mekong delta.

U2 - 10.1016/j.soilbio.2011.12.028

DO - 10.1016/j.soilbio.2011.12.028

M3 - Journal article

SN - 0038-0717

VL - 47

SP - 166

EP - 174

JO - Soil Biology & Biochemistry

JF - Soil Biology & Biochemistry

ER -

Effects of alternating wetting and drying versus continuous flooding on fertilizer nitrogen fate in rice fields in the Mekong Delta, Vietnam

Abstract

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