Net annual global warming potential and greenhouse gas intensity in Chinese double rice-cropping systems: a 3-year field measurement in long-term fertilizer experiments

Shang, Qi; Yang, X. B.; Gao, Cuimin; Wu, Pingping; JinJian, Liu; Xu, Yangchun; Shen, Qirong; Zou, Jianwen; Guo, Shiwei

doi:10.1111/j.1365-2486.2010.02374.x

Cited by 465 publications

(296 citation statements)

References 73 publications

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“…Averaged across sampling location, aboveground dry matter was greater from XL753 (2862 g m -2 ) than from CLXL729 and Roy J, which did not differ and averaged 2488 g m -2 , while aboveground dry matter measured from CLXL745 (2649 g m -2 ) did not differ from any of the other cultivars. Although previous studies have observed a positive correlation between CH 4 emissions and aboveground dry matter [52,62,70,71], data from this study did not support that relationship, where in this case the cultivar exhibiting greater CH 4 fluxes (Roy J) was one of the lowest accumulators of aboveground dry matter. Huang et al [71] suggested that the relationship between biomass accumulation and CH 4 emissions, although correlated when examining the relationship for a single cultivar, was not strong when evaluating the relationship among different cultivars.…”

Section: Aboveground Dry Matter and Grain Yieldcontrasting

confidence: 99%

“…Gas sampling throughout the study occurred between 0800 and 1000 hours, similar to previous studies [30,32,48,49,51,52,53], in order to prevent excessive heating within the chambers during sampling. Gas samples for flux measurements occurred on approximately weekly intervals at 7,14,21,28,35,43,49,56,63,71, and 77 days after flooding (DAF) for the flooded duration of the study.…”

Section: Gas Sampling and Analysismentioning

confidence: 99%

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Methane Emissions among Hybrid Rice Cultivars in the MidSouthern United States

A.D.¹,

K.R.²,

R.J.³

2018

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Abstract. Rice (Oryza sativa L.) production systems have a greater global warming potential than upland row crops due to methane (CH4) emissions resulting from anaerobic conditions associated with flood-irrigated soils. Based on recent research indicating the potential for hybrid cultivars to mitigate CH4 emissions from rice, the objective of this study was to determine the influence of several commonly grown hybrid rice cultivars on CH4 fluxes and emissions from a silt-loam soil. Four cultivars were evaluated: the three hybrids CLXL729, CLXL745, and XL753 and the pure-line cultivar Roy J. Methane fluxes were determined by measuring changes in headspace CH4 concentrations over a period of 1 hour using 30-cm-inner-diameter polyvinyl chloride chambers. Only minor differences in CH4 fluxes occurred among the three hybrid cultivars, while the pure-line cultivar (Roy J) generally had greater (P < 0.05) fluxes. Peak CH4 fluxes occurred just after heading and were greater (P < 0.05) from Roy J (7.9 mg CH4-C m -2 h -1) than from the three hybrid cultivars, which did not differ and averaged 5.1 mg CH4-C m -2 h -1. Seasonal CH4 emissions were greater (P < 0.05) from Roy J (74.8 kg CH4-C ha -1 season -1 ) than from CLXL729, XL753, and CLXL745, which did not differ, and averaged 55.3, 53.0, and 48.9 kg CH4-C ha -1 season -1, respectively. Results of this study indicate the use of common hybrid cultivars may have potential for mitigation of CH4 emissions from rice production on silt-loam soils in the mid-southern United States.Keywords: Methane emissions, rice cultivar, hybrid rice, methane mitigation IntroductionRice (Oryza sativa L.) is the world's only major row crop that substantially contributes to global methane (CH 4 ) emissions. While most crops are grown under aerated soil conditions and act as net sinks for atmospheric CH 4 , the majority of rice throughout the globe is produced in flooded fields [1] and acts as a net source of CH 4 into the atmosphere. The anoxic conditions resulting from flooded soils lead to the production and release of CH 4 , a greenhouse gas with a global warming potential (GWP) 25 times stronger than carbon dioxide (CO 2 ) [2]. Due to the production of CH 4 , rice cultivation has been estimated to have a GWP 2.7 and 5.7 times stronger than the production of maize (Zea mays L.) and wheat (Triticum aestivum L.), respectively, with 90% of the GWP of rice systems attributed to CH 4 [3,4]. It has been estimated, on a global scale, that approximately half of all anthropogenic CH 4 emissions to the atmosphere are a direct result of agricultural activities [5,6] and that 22% of those agricultural CH 4 emissions occur due to rice cultivation [7]. Arkansas is the leading rice-producing state in the US, representing over 49% of harvested area in 2014 and resulting in an estimated 39% of total CH 4 emissions from rice cultivation in the US in 2014 [8].Methane emissions from a rice cultivation system are governed by the magnitude and balance between the two microbial processes of methanogenesis, the prod...

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Section: Aboveground Dry Matter and Grain Yieldcontrasting

confidence: 99%

Section: Gas Sampling and Analysismentioning

confidence: 99%

Methane Emissions among Hybrid Rice Cultivars in the MidSouthern United States

A.D.¹,

K.R.²,

R.J.³

2018

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“…According to Ding and Cai (2003), if the soil organic carbon is less than 20 g kg , N application can stimulate soil CH4 production, the soil organic carbon were all less than 20 g kg -1 in Shenyang and Jinxian (Table 1), thus, CK treatment could enhance CH4 production and thereby CH4 emissions compared to the DR treatments. In addition, there are many early rice residues incorporated into late rice fields at Jinxian, the higher basal N application may stimulate the decomposition of rice residues that enhance CH4 production (Shang et al, 2011). At Danyang for Y Liangyou-302, DR treatments tend to reduce CH4 emissions (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Increasing nitrogen (N) fertilizer input has contributed significantly to the improvement of rice yield (Cassman et al, 2003), but simultaneously resulted in serious environmental pollution due to low N use efficiency (NUE) by improper N fertilization (Chien et al, 2009). Meanwhile, rice crop represent an important source of global methane (CH4) and nitrous oxide (N2O) emissions (Zou et al, 2009;IPCC, 2013); greenhouse gas (GHG) emissions reduction from paddy field has gained increasing concerns throughout the world Shang et al, 2011;Pittelkow et al, 2014). Thus, it is a great challenge for rice cropping to obtain high yield and NUE with low GHG emissions (Foley et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Effects of Dense Planting with Less Basal N Fertilization on Rice Yield, N Use Efficiency and Greenhouse Gas Emissions

Zhu¹,

Wang²,

Li³

et al. 2015

IJAB

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Rice cropping innovations for high yield with high N use efficiency (NUE) and low greenhouse gas (GHG) emissions are significant in ensuring food security and coping with climate change. The objective of this study was to investigate the comprehensive effects of dense planting with less basal N application (DR) on rice yield, NUE and GHG emissions. Field experiments were conducted at three sites in China: Shenyang, Danyang and Jinxian representing annual single rice cropping system, wheat-rice cropping system and double rice cropping system, respectively. Four planting densities with 25, 50, 75 and 100% higher each time correspondingly with about 25, 50, 75 and 100% less in basal N rate (i.e., DR1, DR2, DR3 and DR4 correspondingly) relative to traditional cropping for high yield (CK). Across three tested sites, the DR1 mode showed a large potential of NUE enhancement by 19.6% and GHG emissions mitigation by 12.2% at area-and yield-scaled with similar rice yield compared to the CK. However, further increase in planting density and decrease in basal N application caused a significant reduction in rice yield with a large increase in GHG emissions. Our results will provide important reference to rice cropping innovations for the integrated goals of food security, environmental health and climate change mitigation in China.

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“…Consequently, seasonal variation of methane emissions obeyed similar regularity with TASM and PMET under the influence of rice growth stage. In addition, the different patterns of methane emissions before and after mid-season drainage suggested that MSD is regarded potentially as a promising option for the mitigation of methane emissions from double-rice paddy fields as documented in the study of Shang et al (2011).…”

Section: Temporal Patterns Of Methane Emissions and Tasm And Pmetmentioning

confidence: 98%