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8. Integrated Effects of Straw Incorporation and N Application on Rice Yield and Greenhouse Gas Emissions in Three Rice-Based Cropping Systems.

Author

Bankole, Oluwaseyi Oyewale, Danso, Frederick, Zhang, Nan, Zhang, Jun, Zhang, Kun, Dong, Wenjun, Lu, Changying, Zhang, Xin, Li, Gexing, Raheem, Abdulkareem, Deng, Aixing, Zheng, Chengyan, Song, Zhenwei, and Zhang, Weijian

Subjects
GREENHOUSE gases, CROPPING systems, STRAW, NITROGEN fertilizers, PADDY fields, RICE straw, RICE
Abstract

Crop straw and N fertilizer applications impact paddy rice yield and greenhouse gas (GHG) emissions. However, their interactive effects have not been well documented. This study investigated the effects of straw (S), no straw incorporation (NS), and three levels of N fertilization rates (N0, N1, and N2) on single rice (SR), double rice (DR), and rice-wheat (RW) cropping systems. Straw incorporation significantly increased total CH4 emissions by 118.6%, 8.0%, and 79.0% in the SR, DR, and RW, respectively, compared to the NS. The total GHG emissions in DR are significantly 72.6% and 83.5% higher than those in RW and SR, respectively. Compared to NS, straw incorporation significantly increased yield-scaled emissions by 27.8%, 15.0%, and 89.0% in SR, DR, and RW, respectively. Straw with N application significantly increased average rice yield over N1 and N2 by 39.4%, 50.0%, and 6.7% in SR, DR, and RW, respectively. There was a significant correlation between methyl coenzyme M reductase (mcrA) and CH4 emissions in rSR = 0.87 (p < 0.05) and rRW = 0.85 (p < 0.05), except in rDR = 0.06 (p > 0.05). This study scientifically supports straw incorporation combined with a moderate N application rate in rice-based cropping systems to maintain high rice yields and mitigate GHG emissions. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Plough Tillage Maintains High Rice Yield and Lowers Greenhouse Gas Emissions under Straw Incorporation in Three Rice-Based Cropping Systems.

Author

Danso, Frederick, Bankole, Oluwaseyi Oyewale, Zhang, Nan, Dong, Wenjun, Zhang, Kun, Lu, Changying, Shang, Ziyin, Li, Gexing, Deng, Aixing, Song, Zhenwei, Zheng, Chengyan, Zhang, Jun, and Zhang, Weijian

Subjects
GREENHOUSE gases, PLOWING (Tillage), CROPPING systems, DOUBLE cropping, NO-tillage, STRAW, PLOWS
Abstract

Straw incorporation promotes rice productivity and soil fertility. However, the effects of tillage practice with straw on GHG emissions in paddy fields are not well documented. Under three rice-based cropping systems of China (single rice, double rice and rice-wheat cropping systems), we investigated rice yield, CH4, N2O, area and yield-scaled emissions arising from different straw-incorporated tillage patterns. Tillage with straw affected rice yield by −6.8~3.2%, −9.1~9.0% and −9.8~2.1% in single rice, rice-wheat and double rice cropping systems respectively. Straw impacted CH4 emission but tillage influenced its impact irrespective of the rice cropping system. The highest CH4 emissions occurred in RedT + S, RoT + S and RoT + S under single rice, rice-wheat and double rice cropping systems respectively. Cumulative CH4 emission of PT + S decreased by 46.8% (p < 0.05) compared to RedT + S in the single cropping system, while under rice-wheat and double rice cropping systems, cumulative CH4 emission of PT + S decreased by 19.0% (p < 0.05) and 13.2% (p > 0.05) respectively compared with RoT + S. Lower methanogenic abundance of PT + S translated into the lowest cumulative CH4, area and yield scaled emissions in single rice and double rice cropping systems. To maintain high rice yield and reduce GHG emissions from straw incorporation, PT + S is recommended for a rice-based cropping system. [ABSTRACT FROM AUTHOR]

Published
2023
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18. The Tradeoff between Maintaining Maize (Zea mays L.) Productivity and Improving Soil Quality under Conservation Tillage Practice in Semi-Arid Region of Northeast China.

Author

Chen, Nana, Zhao, Xin, Dou, Shuxian, Deng, Aixing, Zheng, Chengyan, Cao, Tiehua, Song, Zhenwei, and Zhang, Weijian

Subjects
SOIL productivity, CONSERVATION tillage, SOIL quality, ARID regions, CORN, NO-tillage, SOIL compaction, SOILS
Abstract

Conservation tillage has received strong support globally to achieve food security and minimize environmental impacts. However, there are comprehensive debates on whether it can achieve the synergy between maintaining crop yields and improving soil quality. To this end, a field experiment under continuous maize (Zea mays L.) cropping was conducted in northeast China. The treatment included rotary tillage with straw removal (CK, conventional tillage) and rotary tillage, subsoiling tillage, and no tillage with straw retention (CR, CS, and CN, respectively). Maize yield and a set of soil physio-chemical indicators in relation with soil quality were measured during 2017 to 2021. Results showed that CN significantly reduced the maize yield by 24.9%, 23.1%, and 19.5% on average compared to that with CR, CK, and CS treatments, respectively. CN and CS significantly increased the ratio of >2 mm soil aggregates and soil geometric mean diameter (GMD) in the 0–20 cm soil layer compared those of CK and CR treatments. However, CN and CS treatments had a higher soil bulk density and soil compaction in the 0–20 cm layer compared to those with CK and CR treatments. Soil organic carbon and total nitrogen in the 0–20 cm layer under CN and CS were higher than those with CK by 5.1–15.0% and 8.5–15.7%, whereas soil NH4+ was lower by 9.1–13.9% correspondingly. CN also reduced the soil temperature during the early-growth stage of maize. Importance analysis indicated that soil temperature, bulk density, and available nitrogen were the key factors affecting maize yield. Overall, no tillage with straw mulching could improve soil stability and soil fertility but reduced maize yield. Alternatively, minimum tillage (e.g., subsoiling tillage) with straw mulching might be a suitable practice as it maintains the maize yield and improves soil quality compared to those with conventional tillage practices in the semi-arid region of northeast China in the short term. [ABSTRACT FROM AUTHOR]

Published
2023
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21. Effect of Long-Term Organic Amendment Application on the Vertical Distribution of Nutrients in a Vertisol.

Author

Zhang, Yu, Wu, Liuge, Zhang, Xin, Deng, Aixing, Abdulkareem, Raheem, Wang, Daozhong, Zheng, Chengyan, and Zhang, Weijian

Subjects
SOIL profiles, SUSTAINABLE agriculture, NUTRIENT cycles, CROP yields, PLANT nutrients, STRAW, FEEDLOTS
Abstract

Soil nutrients in deep soils are important for nutrient cycling and plant growth. Organic amendments have been widely used for enhancing soil health and crop yield. However, little is known about the effects of organic amendments on the vertical distributions of soil nutrients. Based on a 32-year long-term organic amendment experiment, the objective of this study was to evaluate changes in the vertical distribution of nutrients in a soybean–wheat system Vertisol. The results showed that NPK with manure or straw application significantly increased soil organic carbon (SOC), total N, total P, alkali-hydrolyzable N, available P and available K above the 40 cm soil layer. Variations in soil micronutrients primarily occurred above the 20 cm soil layer, and the highest contents were observed for NPKWS and NPKPM, respectively. Nevertheless, large amounts of NO3−N contents accumulated in the 120–200 cm depth with manure but not straw application, indicating a high potential risk of nitrate leaching in manure treatments. These findings suggested that the application of organic amendment (manure or straw) could be recommendable for improving soil nutrients along the soil profile. Straw incorporation could be used as an alternative option for sustainable agriculture in regions with inadequate manure resources or severe nitrate leaching. [ABSTRACT FROM AUTHOR]

Published
2022
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22. Optimization of Rice-Based Double-Cropping System with Conservation Practice Mitigates Carbon Emission While Ensuring Profitability.

Author

Zhang, Xin, Chen, Tao, Qi, Yongkui, Yang, Ruiping, Deng, Aixing, Wang, Tianshu, Zheng, Chengyan, Zhang, Jun, Shang, Ziyin, Song, Zhenwei, and Zhang, Weijian

Subjects
DOUBLE cropping, CARBON emissions, EMISSIONS (Air pollution), AGRICULTURAL productivity, ECOLOGICAL impact, PADDY fields
Abstract

Including green manure into a rice-based double-cropping system has effects on both crop production and greenhouse gas (GHG) emissions. Yet, few studies have considered the trade-off between crop productivity, profitability, and carbon footprint (CF) in this cropping system of China. Thus, the impacts of different cropping regimes on crop productivity, economic benefits, carbon footprint, and net ecosystem economic budget (NEEB) were investigated. The treatments were rice–wheat (R–W), rice–rape (R–R), rice–hairy vetch (R–H), rice–barley (R–B), rice–faba bean (R–F), and rice–fallow (R). Compared to R–W treatment, planting rape (R–R), green manure (R–F, R–H), or fallow (R) in winter season tended to improve rice yield, but they were not conducive to yield stability. Treatments of R–H, R–F, and R reduced both direct and indirect GHG emission, and thus mitigated the area-scaled carbon footprint by 34.4%, 44.2%, and 49.7%, respectively, compared to R–W treatment. The economic benefits under R–R, R–B, or R system were not different from those of R–W treatment, while R–H reduced the economic benefit by 70.1%. In comparison with R–W treatment, R–H treatment reduced the NEEB, while R–F significantly increased the NEEB by USD 4065 ha−1. The present results indicate that as a measure to realize the combination of food security and environmental cost reduction, substituting leguminous crops with wheat can mitigate carbon emissions while ensuring profitability, on the premise of yield stability. [ABSTRACT FROM AUTHOR]

Published
2022
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23. Nitrogen Fertilization and Straw Management Economically Improve Wheat Yield and Energy Use Efficiency, Reduce Carbon Footprint.

Author

Wu, Liuge, Zhang, Xin, Chen, Huan, Wang, Daozhong, Nawaz, Muhammad Mohsin, Danso, Frederick, Chen, Jian, Deng, Aixing, Song, Zhenwei, Jamali, Hizbullah, Zheng, Chengyan, and Zhang, Weijian

Subjects
ECOLOGICAL impact, ENERGY consumption, FERTILIZERS, WHEAT, WHEAT straw, CATTLE manure
Abstract

Fertilization is an effective agronomic management technique for increasing crop production. However, the overuse of chemical fertilizer stimulates energy consumption and greenhouse gas (GHG) emissions, which are antagonistic to sustainable wheat production. In this study, we estimated the energy and GHG performances of different fertilization regimes based on a 32−year fertilization experiment. In this long−term experiment, there are five treatments: CK (no fertilizer with wheat residue removal), NPK (chemical fertilizer with wheat residue removal), NPKPM (chemical fertilizer and pig manure with wheat residue removal), NPKCM (chemical fertilizer and cattle manure with wheat residue removal), and NPKWS (chemical fertilizer with wheat residue retention). The results indicated that NPKCM and NPKPM consumed higher total energy than NPK and NPKWS, which was attributed to the extra energy usage of farmyard manure. Although NPKCM and NPKPM increased energy output by 4.7 and 2.8%, NPKWS stood out by delivering the highest energy use efficiency (EUE) of 6.66, energy productivity of 0.26 kg MJ−1, energy profitability of 5.66, net return of 1799.82 US$ ha−1 and lower specific energy of 3.84 MJ kg−1. Moreover, the yield scale carbon footprint of NPKWS decreased by 66.7 and 52.3% compared with NPKCM and NPKPM, respectively. This study shows that the application of chemical fertilizer in combination with wheat residue retention is a good strategy to increase EUE and economic benefits while decreasing the carbon footprint of wheat production. [ABSTRACT FROM AUTHOR]

Published
2022
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25. Maize‐based intercropping systems achieve higher productivity and profitability with lesser environmental footprint in a water‐scarce region of northwest China.

Author

Sun, Tao, Zhao, Cai, Feng, Xiaomin, Yin, Wen, Gou, Zhiwen, Lal, Rattan, Deng, Aixing, Chai, Qiang, Song, Zhenwei, and Zhang, Weijian

Subjects
INTERCROPPING, CATCH crops, WATER efficiency, CROPPING systems, CROP yields, FOOTPRINTS
Abstract

Global agriculture is facing multiple challenges to meet the food demands, optimize resource utilization, and mitigate the climate change. A field study, combined with the life cycle assessment (LCA), was conducted to select the effective and sustainable cropping systems in northwestern China. The study compared four maize‐based intercropping and corresponding monoculture systems on crop yield, evapotranspiration (ET), water use efficiency (WUE), profitability, and carbon footprint (CF). Maize/wheat intercropping had the highest energy yield (532.5 GJ/ha, on average) and maize equivalent energy yield (MEEY) (522.3 G/ha, on average), followed by those from the maize/rape intercropping system, and the lowest by the sole potato system. The WUE of maize equivalent energy yield (WUEMEEY) was the highest (1.06 GJ ha−1 mm−1) for sole rape system, followed by those for the maize/wheat and maize/rape intercropping systems. Maize/potato intercropping had the highest benefit: cost ratio at 3.30, followed by those for the maize/wheat intercropping (2.58), sole potato (2.57), and maize/rape intercropping (2.53). Lower CF and higher net ecosystem economic budget (NEEB) were observed in maize‐based intercropping systems. The maize/wheat intercropping system had the lowest CF per maize equivalent energy yield (CFm) (10.7 kg CO2‐eq GJ−1 year−1), and the maize/potato intercropping system had the lowest CF per unit economic output (CFe) (0.14 kg CO2‐eq US$−1 year−1), and the highest NEEB (7,352.8 US$/ha). The data presented indicate that maize‐based intercropping system may be a viable practice for the synthesized goals of higher productivity and profitability while lesser environmental footprint in a water‐scarce region of northwest China. [ABSTRACT FROM AUTHOR]

Published
2021
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26. Lower‐than‐expected CH4 emissions from rice paddies with rising CO2 concentrations.

Author

Qian, Haoyu, Huang, Shan, Chen, Jin, Wang, Ling, Hungate, Bruce A., Kessel, Chris, Zhang, Jun, Deng, Aixing, Jiang, Yu, Groenigen, Kees Jan, and Zhang, Weijian

Subjects
PADDY fields, WHEAT straw, STRAW, MICROBIAL growth, SOILS
Abstract

Elevated atmospheric CO2 (eCO2) generally increases carbon input in rice paddy soils and stimulates the growth of methane‐producing microorganisms. Therefore, eCO2 is widely expected to increase methane (CH4) emissions from rice agriculture, a major source of anthropogenic CH4. Agricultural practices strongly affect CH4 emissions from rice paddies as well, but whether these practices modulate effects of eCO2 is unclear. Here we show, by combining a series of experiments and meta‐analyses, that whereas eCO2 strongly increased CH4 emissions from paddies without straw incorporation, it tended to reduce CH4 emissions from paddy soils with straw incorporation. Our experiments also identified the microbial processes underlying these results: eCO2 increased methane‐consuming microorganisms more strongly in soils with straw incorporation than in soils without straw, with the opposite pattern for methane‐producing microorganisms. Accounting for the interaction between CO2 and straw management, we estimate that eCO2 increases global CH4 emissions from rice paddies by 3.7%, an order of magnitude lower than previous estimates. Our results suggest that the effect of eCO2 on CH4 emissions from rice paddies is smaller than previously thought and underline the need for judicious agricultural management to curb future CH4 emissions. [ABSTRACT FROM AUTHOR]

Published
2020
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27. Nitrous oxide emission, global warming potential, and denitrifier abundances as affected by long-term fertilization on Mollisols of Northeastern China.

Author

Feng, Xiaomin, Gao, Hongjun, Lal, Rattan, Zhu, Ping, Peng, Chang, Deng, Aixing, Zheng, Chengyan, Song, Zhenwei, and Zhang, Weijian

Subjects
MOLLISOLS, FERTILIZERS, GLOBAL warming, NITROUS oxide, HISTOSOLS, FERTILIZER application, ORGANIC fertilizers
Abstract

A long-term field experiment was performed to assess the effects of fertilization regimes on greenhouse gas emissions, soil properties, soil denitrifies, and maize (Zea mays) grain yield on Mollisols of Northeastern China. Chemical nitrogen (N), phosphorus (P), and potassium (K) fertilizers plus pig manure (MNPK) treatment significantly increased soil N2O emissions by 29.9–226.4% and global warming potential (GWP) by 29.8–230.7% compared to unfertilized control (CK), chemical N fertilizer only (N), chemical N, P, and K fertilizers (NPK) and chemical N, P, and K fertilizers plus corn straw (SNPK) treatments. However, the MNPK treatment yielded similar greenhouse gas intensity (GHGI) as compared with other treatments, mainly due to higher maize grain yield. There were also higher gene copy numbers of nirK, nirS, and nosZ in topsoil (0–20 cm depth) under MNPK treatment. Automatic linear modeling analysis indicated that main factors influencing soil N2O emissions were soil organic carbon (SOC), NO3 content, and nirK gene abundance. Although the application of chemical fertilizers plus organic manure increases N2O emissions due to higher N and C availability and nirK gene activity in the soil, this is still a promising fertilizer management due to its notable enhancement of maize grain yield and SOC content. [ABSTRACT FROM AUTHOR]

Published
2019
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28. Impacts of wheat photosynthate allocation on soil N2O emission during post-anthesis period.

Author

Deng, Aixing, Zhang, Xin, Zhang, Xingyue, Qian, Haoyu, Zhang, Yu, Chen, Changli, Jiang, Yu, Zheng, Chengyan, and Zhang, Weijian

Subjects
*WHEAT, *ROOT growth, *SOILS, *LOW temperatures, *GREENHOUSE gases
Abstract

Both spikelet removal and low temperature stress largely reduced photosynthate allocation to wheat grain; the former stimulated the average N2O emissions by 31.3% and 33.2% under the field and pot conditions; the latter increased average N2O emission by 19.9% under pot condition. Spikelet removal and low temperature stress significantly reduced total plant N uptake, thereby increasing soil NO3–-N content, and increased root biomass. Our findings indicated that photosynthate allocation affects the soil N2O emissions from wheat fields through altering plant N uptake and root growth, and suggest that promoting photosynthate allocation to grain may not only benefit higher wheat yield but also mitigate greenhouse gas emissions. [ABSTRACT FROM AUTHOR]

Published
2019
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29. Limited potential of harvest index improvement to reduce methane emissions from rice paddies.

Author

Jiang, Yu, Qian, Haoyu, Wang, Ling, Feng, Jinfei, Huang, Shan, Hungate, Bruce A., van Kessel, Chris, Horwath, William R., Zhang, Xingyue, Qin, Xiaobo, Li, Yue, Feng, Xiaomin, Zhang, Jun, Deng, Aixing, Zheng, Chenyan, Song, Zhenwei, Hu, Shuijin, van Groenigen, Kees Jan, and Zhang, Weijian

Subjects
PADDY fields, METHANE & the environment, ANTHROPOGENIC effects on nature, CLIMATE change, WATER management, FOOD security
Abstract

Rice is a staple food for nearly half of the world's population, but rice paddies constitute a major source of anthropogenic CH4 emissions. Root exudates from growing rice plants are an important substrate for methane‐producing microorganisms. Therefore, breeding efforts optimizing rice plant photosynthate allocation to grains, i.e., increasing harvest index (HI), are widely expected to reduce CH4 emissions with higher yield. Here we show, by combining a series of experiments, meta‐analyses and an expert survey, that the potential of CH4 mitigation from rice paddies through HI improvement is in fact small. Whereas HI improvement reduced CH4 emissions under continuously flooded (CF) irrigation, it did not affect CH4 emissions in systems with intermittent irrigation (II). We estimate that future plant breeding efforts aimed at HI improvement to the theoretical maximum value will reduce CH4 emissions in CF systems by 4.4%. However, CF systems currently make up only a small fraction of the total rice growing area (i.e., 27% of the Chinese rice paddy area). Thus, to achieve substantial CH4 mitigation from rice agriculture, alternative plant breeding strategies may be needed, along with alternative management. Breeding efforts optimizing photosynthate allocation to grains, i.e., increasing harvest index (HI), are widely expected to reduce CH4 emissions from rice cultivation. Here we show, by combining a series of experiments, meta‐analyses, and an expert assessment, that the potential of CH4 mitigation from rice paddies through HI improvement is actually small. We estimate that future HI improvement will reduce CH4 emissions in continuously flooded systems (CF) by 4.4% at most. Furthermore, HI improvement did not affect CH4 emissions in systems with intermittent irrigation (II); these systems make up a large part of the China's rice growing area and are becoming increasingly popular. [ABSTRACT FROM AUTHOR]

Published
2019
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30. Higher yields and lower methane emissions with new rice cultivars.

Author

Jiang, Yu, Groenigen, Kees Jan, Huang, Shan, Hungate, Bruce A., Kessel, Chris, Hu, Shuijin, Zhang, Jun, Wu, Lianhai, Yan, Xiaojun, Wang, Lili, Chen, Jin, Hang, Xiaoning, Zhang, Yi, Horwath, William R., Ye, Rongzhong, Linquist, Bruce A., Song, Zhenwei, Zheng, Chengyan, Deng, Aixing, and Zhang, Weijian

Subjects
META-analysis, CARBON in soils, BIOMASS, GREENHOUSE gases, METHANE, CLIMATE change
Abstract

Breeding high-yielding rice cultivars through increasing biomass is a key strategy to meet rising global food demands. Yet, increasing rice growth can stimulate methane ( CH4) emissions, exacerbating global climate change, as rice cultivation is a major source of this powerful greenhouse gas. Here, we show in a series of experiments that high-yielding rice cultivars actually reduce CH4 emissions from typical paddy soils. Averaged across 33 rice cultivars, a biomass increase of 10% resulted in a 10.3% decrease in CH4 emissions in a soil with a high carbon (C) content. Compared to a low-yielding cultivar, a high-yielding cultivar significantly increased root porosity and the abundance of methane-consuming microorganisms, suggesting that the larger and more porous root systems of high-yielding cultivars facilitated CH4 oxidation by promoting O2 transport to soils. Our results were further supported by a meta-analysis, showing that high-yielding rice cultivars strongly decrease CH4 emissions from paddy soils with high organic C contents. Based on our results, increasing rice biomass by 10% could reduce annual CH4 emissions from Chinese rice agriculture by 7.1%. Our findings suggest that modern rice breeding strategies for high-yielding cultivars can substantially mitigate paddy CH4 emission in China and other rice growing regions. [ABSTRACT FROM AUTHOR]

Published
2017
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31. Climatic Warming Increases Winter Wheat Yield but Reduces Grain Nitrogen Concentration in East China.

Author

Tian, Yunlu, Zheng, Chengyan, Chen, Jin, Chen, Changqing, Deng, Aixing, Song, Zhenwei, Zhang, Baoming, and Zhang, Weijian

Subjects
WINTER wheat, GLOBAL warming, WHEAT yields, NITROGEN content of grain, PLANT biomass, AGRICULTURAL productivity
Abstract

Climatic warming is often predicted to reduce wheat yield and grain quality in China. However, direct evidence is still lacking. We conducted a three-year experiment with a Free Air Temperature Increase (FATI) facility to examine the responses of winter wheat growth and plant N accumulation to a moderate temperature increase of 1.5°C predicted to prevail by 2050 in East China. Three warming treatments (AW: all-day warming; DW: daytime warming; NW: nighttime warming) were applied for an entire growth period. Consistent warming effects on wheat plant were recorded across the experimental years. An increase of ca. 1.5°C in daily, daytime and nighttime mean temperatures shortened the length of pre-anthesis period averagely by 12.7, 8.3 and 10.7 d (P<0.05), respectively, but had no significant impact on the length of the post-anthesis period. Warming did not significantly alter the aboveground biomass production, but the grain yield was 16.3, 18.1 and 19.6% (P<0.05) higher in the AW, DW and NW plots than the non-warmed plot, respectively. Warming also significantly increased plant N uptake and total biomass N accumulation. However, warming significantly reduced grain N concentrations while increased N concentrations in the leaves and stems. Together, our results demonstrate differential impacts of warming on the depositions of grain starch and protein, highlighting the needs to further understand the mechanisms that underlie warming impacts on plant C and N metabolism in wheat. [ABSTRACT FROM AUTHOR]

Published
2014
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32. Monoclonal Antibody-Based Enzyme Linked Immunosorbent Assay for the Analysis of Jasmonates in Plants.

Author

Deng, Aixing, Tan, Weiming, He, Suping, Liu, Wei, Nan, Tiegui, Li, Zhaohu, Wang, Baomin, and Li, Qing X.

Subjects
*ENZYME-linked immunosorbent assay, *IMMUNOASSAY, *PLANT regulators, *JASMONIC acid, *IMMUNOENZYME technique
Abstract

Methyl jasmonate (MeJA) and its free-acid form, jasmonic acid (JA) are naturally occurring plant growth regulators widely distributed in higher plants. In order to improve the sensitivity for the analysis of MeJA at low levels in small amounts of plant samples, a monoclonal antibody (MAb) (designated as MAb 3E5D7C4B6) against MeJA was derived from a JA-bovine serum albumin (BSA) conjugate as an immunogen. The antibody belongs to the IgG1 subclass with a κ type light chain and has a dissociation constant of approximately 6.07 × 10−9 M. MAb3E5D7C4B6 is very specific to MeJA. It was used to develop a direct competitive enzyme-linked immunosorbent assay (dcELISA), conventional and simplified indirect competitive ELISAs (icELISA). JA was derivatized into MeJA for the ELISA analysis. The IC50 value and detection range for MeJA were, respectively, 34 and 4–257 ng/mL by the conventional icELISA, 21 and 3–226 ng/mL by the simplified icELISA and 5.0 and 0.7–97.0 ng/mL by the dcELISA. The dcELISA was more sensitive than either the conventional or simplified icELISA. The assays were used to measure the content of jasmonates as MeJA in tobacco leaves under drought stress or inoculated with tobacco mosaic virus and tomato leaves inoculated with tomato mosaic virus or Lirioinyza sativae Blanchard as compared with the corresponding healthy leaves. The increased jasmonates content indicated its role in response to the drought stress and pathogens. [ABSTRACT FROM AUTHOR]

Published
2008
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33. Contributions of Climate and Soil Properties to Wheat and Maize Yield Based on Long-Term Fertilization Experiments.

Author

Wei, Shengbao, Peng, Anchun, Huang, Xiaomin, Deng, Aixing, Chen, Changqing, and Zhang, Weijian

Subjects
PLANT fertilization, AGRICULTURAL climatology, WHEAT, AGRICULTURAL productivity, CROP yields, SOILS
Abstract

Identifying the contributions of climate factors and soil fertility to crop yield is significant for the assessment of climate change impacts on crop production. Three 20-year field experiments were conducted in major Chinese wheat-maize cropping areas. Over the 20-year period, crop yield and soil properties showed significantly dissimilar variation trends under similar climate changes at each experimental site. The correlation between climatic factors and crop yield varied greatly among the fertilization regimes and experimental sites. Across all the fertilization regimes and the experimental sites, the average contribution rates of soil properties to wheat and maize yield were 45.7% and 53.2%, respectively, without considering climate factors, and 40.4% and 36.6%, respectively, when considering climate factors. The contributions of soil properties to wheat and maize yield variation when considering climate factors were significantly lower than those without considering climate factors. Across all experimental sites and all fertilization regimes, the mean contribution rates of climate factors to wheat and maize yield were 29.5% and 33.0%, respectively. The contribution rates of the interaction of climate and soil to wheat and maize yield were 3.7% and −0.9%, respectively. Under balanced fertilization treatments (NPK and NPKM), the change in the contribution rate of soil properties to wheat or maize yield was not obvious, and the average contribution rates of the interaction of climate and soil to wheat and maize yield were positive, at 14.8% and 9.5%, respectively. In contrast, under unbalanced fertilization treatments (CK and N), the contribution rates of soil properties to wheat or maize yield decreased, and the average contribution rates of the interaction of climate and soil were negative, at −7.4% and −11.2%, respectively. The above results indicate that climate and soil synergistically affected crop yields and that, with the optimization of the fertilization regime, positive interactions gradually emerged. [ABSTRACT FROM AUTHOR]

Published
2021
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34. How incorporation depth of corn straw affects straw decomposition rate and C&N release in the wheat-corn cropping system.

Author

Latifmanesh, Hojatollah, Deng, Aixing, Li, Liang, Chen, Zongjin, Zheng, Yuntan, Bao, Xiaotong, Zheng, Chengyan, and Zhang, Weijian

Subjects
*CORN straw, *WHEAT straw, *CROPPING systems, *STRAW, *SOIL temperature
Abstract

• Straw incorporation in topsoil layer promoted soil temperature and total porosity. • Corn straw incorporation in topsoil layer increased straw decomposition rate. • Higher decomposition rate caused higher availability of mineral N and TOC. The effects of straw incorporation on soil characters are well known, however, straw incorporation depth impact on corn straw decomposition rate, microbial biomass carbon (MBC) & microbial biomass nitrogen (MBN), soil carbon (C) and nitrogen (N) concentration during straw decomposition have not been documented. A two-year field experiment was carried out in a wheat-corn cropping system to investigate the effects of straw incorporation depth on decomposition rate of corn straw and soil C and N release. The straw incorporation depths were: topsoil 0–10 cm (TI), medium depth 10–20 cm (MI), and deep depth 20–30 cm (DI). The results showed that corn straw decomposition rate was significantly higher in TI by 24.5 % and 16.5 % than in MI and DI treatments from October 2016 to August 2017. The average contents of MBC and MBN during the decomposition period of straw were higher in TI than in MI and DI treatments (P < 0.01). Additionally, the release of N and C from the corn straw was higher in TI, causing a significantly higher average concentration of NO 3 −–N (P < 0.01) and total organic carbon (P < 0.05) observation in this layer compared with MI and DI. Our results suggest that the corn straw incorporation in topsoil layer of 0–10 cm can decompose faster, and the higher decomposition rate may facilitate the release of C&N from the straw, causing the higher availability of mineral nitrogen and total organic carbon of this layer. [ABSTRACT FROM AUTHOR]

Published
2020
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36. Integrated assessment of the impact of enhanced-efficiency nitrogen fertilizer on N2O emission and crop yield.

Author

Feng, Jinfei, Li, Fengbo, Deng, Aixing, Feng, Xiaomin, Fang, Fuping, and Zhang, Weijian

Subjects
*NITROGEN fertilizers, *CROP yields, *AGRICULTURAL ecology, *META-analysis, *NITRIFICATION inhibitors, *GLOBAL warming
Abstract

Enhanced-efficiency nitrogen fertilizer (EENF) has gained considerable attention for improving nitrogen use efficiency and mitigating N 2 O emission in many agro-ecosystems. However, the effectiveness of EENF is highly variable under field condition. The factors influencing the efficacy of EENF are not well understood. Here, a meta-analysis was conducted to investigate the key factors affecting the efficacy of EENF in upland cropping systems. The effects of EENF were found to be similar among maize, wheat, and barley, while they varied among different EENF products. Inhibitors (IS), including nitrification inhibitors (NI), urease inhibitors (UI), and the combination of UI and NI, significantly mitigated N 2 O emission and increased crop yield, resulting in a greater reduction in yield-scaled N 2 O emission compared with slow- or control-releasing fertilizer (S/CRF). Reductions in yield-scaled N 2 O emission response to IS and S/CRF were both greater in arid regions than in humid regions. Soil pH and texture had less impact on the effect of IS than S/CRF. The efficacy of IS and S/CRF were not significant when N use rates were between 120 and 180 kg N ha −1 . Surface broadcasting were unfavorable for mitigating N 2 O emissions with both IS and S/CRF. The impact of tillage on the efficacy of IS and S/CRF was affected by climate. The effectiveness of S/CRF depended more on these factors than did IS. This meta-analysis highlighted the necessity to connect EENF products with specific climatic, soil, and agronomic attributes for predicting their effectiveness. [ABSTRACT FROM AUTHOR]

Published
2016
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37. Synergistic effect of elevated CO2 and straw amendment on N2O emissions from a rice–wheat cropping system.

Author

Yan, Shengji, Liu, Yunlong, Revillini, Daniel, Delgado-Baquerizo, Manuel, van Groenigen, Kees Jan, Shang, Ziyin, Zhang, Xin, Qian, Haoyu, Jiang, Yu, Deng, Aixing, Smith, Pete, Ding, Yanfeng, and Zhang, Weijian

Subjects
*GREENHOUSE gases, *GREENHOUSE gas mitigation, *ATMOSPHERIC carbon dioxide, *NITROGEN fertilizers, *CROPPING systems
Abstract

Nitrous oxide (N2O) is one of the most important climate-forcing gases, and a large portion of global anthropogenic N2O emissions come from agricultural soils. Yet, how contrasting global change factors and agricultural management can interact to drive N2O emissions remains poorly understood. Here, conducted within a rice–wheat cropping system, we combined a two-year field experiment with two pot experiments to investigate the influences of elevated atmospheric carbon dioxide (eCO2) and crop straw addition to soil in altering N2O emissions under wheat cropping. Our analyses identified consistent and significant interactions between eCO2 and straw addition, whereby eCO2 increased N2O emissions (+ 19.9%) only when straw was added, and independent of different N fertilizer gradients and wheat varieties. Compared with the control (i.e., ambient CO2 without straw addition), eCO2 + straw addition increased N2O emission by 44.7% and dissolved organic carbon to total dissolved nitrogen (DOC/TDN) ratio by 115.3%. Similarly, eCO2 and straw addition significantly impacted soil N2O-related microbial activity. For instance, the ratio of the abundance of N2O production genes (i.e., nirK and nirS) to the abundance of the N2O reduction gene (i.e., nosZ) with straw addition was 26.0% higher than that without straw under eCO2. This indicates an increased denitrification potential and suggests a change in the stoichiometry of denitrification products, affecting the balance between N2O production and reduction, leading to an increase in N2O emissions. Taken together, our results emphasize the critical role of the interaction between the specific agronomic practice of straw addition and eCO2 in shaping greenhouse gas emissions in the wheat production system studied, and underline the need to test the efficacy of greenhouse gas mitigation measures under various management practices and global change scenarios.Graphical abstract: Nitrous oxide (N2O) is one of the most important climate-forcing gases, and a large portion of global anthropogenic N2O emissions come from agricultural soils. Yet, how contrasting global change factors and agricultural management can interact to drive N2O emissions remains poorly understood. Here, conducted within a rice–wheat cropping system, we combined a two-year field experiment with two pot experiments to investigate the influences of elevated atmospheric carbon dioxide (eCO2) and crop straw addition to soil in altering N2O emissions under wheat cropping. Our analyses identified consistent and significant interactions between eCO2 and straw addition, whereby eCO2 increased N2O emissions (+ 19.9%) only when straw was added, and independent of different N fertilizer gradients and wheat varieties. Compared with the control (i.e., ambient CO2 without straw addition), eCO2 + straw addition increased N2O emission by 44.7% and dissolved organic carbon to total dissolved nitrogen (DOC/TDN) ratio by 115.3%. Similarly, eCO2 and straw addition significantly impacted soil N2O-related microbial activity. For instance, the ratio of the abundance of N2O production genes (i.e., nirK and nirS) to the abundance of the N2O reduction gene (i.e., nosZ) with straw addition was 26.0% higher than that without straw under eCO2. This indicates an increased denitrification potential and suggests a change in the stoichiometry of denitrification products, affecting the balance between N2O production and reduction, leading to an increase in N2O emissions. Taken together, our results emphasize the critical role of the interaction between the specific agronomic practice of straw addition and eCO2 in shaping greenhouse gas emissions in the wheat production system studied, and underline the need to test the efficacy of greenhouse gas mitigation measures under various management practices and global change scenarios. [ABSTRACT FROM AUTHOR]

Published
2024
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38. Progressive and active adaptations of cropping system to climate change in Northeast China

Author

Chen, Changqing, Qian, Chunrong, Deng, Aixing, and Zhang, Weijian

Subjects
*CROPPING systems, *BIOLOGICAL adaptation, *CLIMATE change, *VEGETATION & climate, *CROP yields
Abstract

Abstract: To learn the historical response of cropping system to climate change will benefit the strategy decision of future cropping adaptation. In this paper, we conducted an integrated analysis of the climate records of seventy-two meteorological stations and the records of crop yields over the period 1970–2009 in Northeast China. It was found that over these forty years, the daily mean, maximum and minimum temperatures during crop growing season increased on average by 0.34°C, 0.28°C, 0.43°C every ten years, respectively. No significant change in the precipitation was found, although the differences between years were large. After de-trending the agronomic technique contributions to the increments of crop yields, the historical warming had led to great annually increments of 16.6kgha−1, 15.5kgha−1 and 3.2kgha−1 in rice, corn and soybean yields, respectively. According to the historical warming level, present cropping boundaries can be theoretically extended northward about 80km with a prolonged growing period by 10 days compared to the 1970s. Actually, the growth durations of newly approved varieties of rice, corn and soybean have really prolonged by 14.0 days, 7.0 days and 2.7 days since the 1950s, respectively. The actual growing periods of rice and corn have also respectively prolonged by 6 days and 4 days due to the adjustment of sown and harvest dates by the farmer since 1990s. The existing rice cropping region has been extended northward 80km in the 2006 compared to the 1970. These actual responses were consistent with the theoretical calculation according to the historical warming trends. Our results demonstrate that cropping system owns the potential to progressively and actively adapt to the global warming for high yield through a comprehensive strategy. [Copyright &y& Elsevier]

Published
2012
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39. Responses of indica rice yield and quality to extreme high and low temperatures during the reproductive period.

Author

Siddik, Mohammad Abubakar, Zhang, Jun, Chen, Jin, Qian, Haoyu, Jiang, Yu, Raheem, Abdul kareem, Deng, Aixing, Song, Zhenwei, Zheng, Chengyan, and Zhang, Weijian

Subjects
*RICE quality, *LOW temperatures, *HIGH temperatures, *RICE yields, *CHLOROPHYLL spectra, *GRAIN yields
Abstract

Highlights • Global warming frequently induces extreme temperatures in rice cropping. • Extreme HT impacts severely on rice yield and quality than the LT. • The most responding stage to quality at the 2nd week of post-heading period. Abstract Extreme temperatures will likely occur with greater frequency and intensity under the conditions of climatic warming, presenting a serious challenge for future crop development. The responses of rice yield and quality to extreme high (HT) and low temperature (LT) during precise reproductive periods are still unclear. Therefore, we conducted a walk-in climate chamber experiment with two indica cultivars and three temperature treatments –CK: 20–28 °C, LT: 12–20 °C and HT: 28–36 °C as the mean values of night-day temperatures– for seven days in four key periods –the last week of pre-heading, and the first, second and third week of post-heading–, respectively. Extreme temperatures reduced rice leaf chlorophyll fluorescence, photosynthetic rate and dry matter translocation, consequently decreasing the grain yield by 5–13 percent under LT and 12–15 percent under HT. The most sensitive periods of rice yield to extreme temperatures were found during the last week of pre-heading and the first week of post-heading. Extreme temperatures significantly declined the grain appearance, milling and cooking quality traits with inversely enhanced chalkiness, broken rice and gelatinization temperature. The most responsive period of rice quality to extreme temperatures occurred during the second week of post-heading. HT exhibited a more severe impact on rice quality than by LT. Our results indicate that the responses of rice yield and quality to extreme temperatures are different among reproductive periods. [ABSTRACT FROM AUTHOR]

Published
2019
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40. Nighttime warming increases winter-sown wheat yield across major Chinese cropping regions.

Author

Zheng, Chengyan, Zhang, Jun, Chen, Jin, Chen, Changqing, Tian, Yunlu, Deng, Aixing, Song, Zhenwei, Nawaz, Muhammad Mohsin, van Groenigen, Kees Jan, and Zhang, Weijian

Subjects
*WINTER wheat, *GRAIN yields, *CROP yields, *EFFECT of global warming on plants, *WHEAT breeding, *CROPPING systems
Abstract

Understanding the actual impacts of climatic warming on winter-sown wheat production will benefit cultivar breeding efforts and agronomic innovations and may help to improve food security. Therefore, we conducted a comprehensive study across the main Chinese winter wheat cropping regions, comprising field warming experiments at four locations and an analysis of 36 years of winter wheat yield data. In the field warming experiments, an increase of 1.0 °C in nighttime temperature enhanced wheat yield by 10.1% on average ( P < 0.05 ). Warming-induced enhancement of 1000-grain weight explained most of these yield increases. Warming shortened the length of pre-flowering phase by 5.4 days, while it prolonged the length of post-flowering phase by 3.8 days. Grain yield increases with warming were similar across experimental sites, even though warming-induced changes in the length of growth periods decreased with increasing ambient temperature. Our analysis of the historical data set was consistent with our field warming experiments; between 1980 and 2015, the major Chinese cropping regions experienced significant warming, especially in daily minimum temperature. Across the historical data set, daily minimum temperature was positively correlated with wheat yield (142.0 kg ha −1 °C −1 ). Our findings are inconsistent with previous reports of yield decreases with warming and may help to inform policy decisions and agronomic innovations of Chinese wheat production to better cope with future climate warming. [ABSTRACT FROM AUTHOR]

Published
2017
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41. Interactive effects of straw incorporation and tillage on crop yield and greenhouse gas emissions in double rice cropping system.

Author

Zhang, Jun, Hang, Xiaoning, Lamine, Samoura Mohamed, Jiang, Yu, Afreh, Daniel, Qian, Haoyu, Feng, Xiaomin, Zheng, Chengyan, Deng, Aixing, Song, Zhenwei, and Zhang, Weijian

Subjects
*CROP yields, *TILLAGE, *GREENHOUSE gas mitigation, *RICE farming, *GLOBAL warming
Abstract

Great efforts have been made on the assessment of the effects of straw managements or tillage practices on rice yield and greenhouse gas (GHG) emissions. However, their interactive effects were not well documented. Based on a seven-year field experiment under a double rice system, we tested the effects of rotary tillage (RT) vs. plough tillage (PT) on rice yield, methane (CH 4 ) and nitrous oxide (N 2 O) emissions with or without straw incorporation. As compared to straw removal, straw incorporation increased rice yield by 12.7% and 1.3% under the PT and the RT, respectively. Straw incorporation significantly stimulated CH 4 emissions under both tillage regimes in the late rice season, while no significant effect occurred in the early rice season. Compared to the RT, PT significantly decreased DOC concentrations and methanogen abundances, resulting in a reduction in CH 4 emission. The PT decreased yield-scaled global warming potential (GWP) with or without straw incorporation by 31.0% and 15.5%, respectively, as compared to the RT. Together, our results indicate that straw incorporation with plough tillage benefits rice production for higher-yield with less GHG emissions in double rice cropping areas. [ABSTRACT FROM AUTHOR]

Published
2017
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42. Differences in the impacts of nighttime warming on crop growth of rice-based cropping systems under field conditions.

Author

Chen, Jin, Chen, Changing, Tian, Yunlu, Zhang, Xin, Dong, Wenjun, Zhang, Bin, Zhang, Jun, Zheng, Chengyan, Deng, Aixing, Song, Zhenwei, Peng, Chunrui, and Zhang, Weijian

Subjects
*RICE, *GLOBAL warming, *CROP growth, *CROPPING systems, *CLIMATE change, *PHYSIOLOGY
Abstract

Great attentions have been taken to the effects of climatic warming on crop production, however, fewer were known about the actual impacts of nighttime warming under different cropping systems. Therefore, a three-year field experiment with a passive nighttime warming (PNW) facility and a one-year field experiment with free air temperature increase (FATI) facility were conducted in major Chinese rice cropping systems. Four-year field observations from different rice cropping systems all showed that nighttime warming less than 1.0 °C could shorten the length of crop pre-flowering phase period while prolonged the length of post-flowering phase period, resulting in insignificant reduction in the length of crop entire growth period. The temperature increase caused significant increments in grain yields by 16.2, 12.7 and 12.0% for late rice in the rice–rice cropping system, wheat in the rice-wheat cropping system and rice in the single rice cropping system, respectively. However, this warming declined grain yields significantly by 4.5 and 6.5% for early rice in the rice–rice cropping system and rice in the rice-wheat cropping system, respectively. Since warming-induced yield reduction was less than warming-induced increment in each cropping system, the annual yields was higher in the warmed plots than the non-warmed under all systems. Our findings can provide important references to cropping system adjustment for coping with global warming in China and other regions. [ABSTRACT FROM AUTHOR]

Published
2017
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43. Dense planting with less basal nitrogen fertilization might benefit rice cropping for high yield with less environmental impacts.

Author

Zhu, Xiangcheng, Zhang, Jun, Zhang, Zhenping, Deng, Aixing, and Zhang, Weijian

Subjects
*RICE yields, *EFFECT of nitrogen on plants, *EFFECT of greenhouse gases on plants, *SEEDLINGS, *METHANE content of soils, *ENVIRONMENTAL impact analysis
Abstract

Dense planting and less basal nitrogen (N) fertilization have been recommended to further increase rice ( Oryza sativa L.) grain yield and N use efficiency (NUE), respectively. The objective of this study was to evaluate the integrative impacts of dense planting with reduced basal N application (DR) on rice yield, NUE and greenhouse gas (GHG) emissions. Field experiments with one conventional sparse planting (CK) and four treatments of dense planting (increased seedlings per hill) with less basal N application were conducted in northeast China from 2012 to 2013. In addition, a two-factor experiment was conducted to isolate the effect of planting density and basal N rate on CH 4 emission in 2013. Our results show that an increase in planting density by about 50% with a correspondingly reduction in basal N rate by about 30% (DR1 and DR2) enhanced NUE by 14.3–50.6% and rice grain yield by 0.5–7.4% over CK. Meanwhile, DR1 and DR2 reduced GWP by 6.4–12.6% and yield-scaled GWP by 7.0–17.0% over CK. According to the two-factor experiment, soil CH 4 production and oxidation and CH 4 emission were not affected by planting density. However, reduced basal N rate decreased CH 4 emission due to it significantly reduced soil CH 4 production with a smaller reduction in soil CH 4 oxidation. The above results indicate that moderate dense planting with less basal N application might be an environment friendly mode for rice cropping for high yield and NUE with less GHG emissions. [ABSTRACT FROM AUTHOR]

Published
2016
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44. Effects of Dense Planting with Less Basal N Fertilization on Rice Yield, N Use Efficiency and Greenhouse Gas Emissions.

Author

Zhu, Xiangcheng, Wang, Xiaofei, Li, Zhijie, Deng, Aixing, Zhang, Zhenping, Zhang, Jun, and Zhang, Weijian

Subjects
*PLANT spacing, *PLANTING, *NITROGEN fertilizers, *RICE yields, *GREENHOUSE gases & the environment, *AGRICULTURAL productivity
Abstract

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. © 2015 Friends Science Publishers [ABSTRACT FROM AUTHOR]

Published
2015
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45. Aboveground morphological traits do not predict rice variety effects on CH4 emissions.

Author

Zhang, Yi, Jiang, Yu, Li, Zhijie, Zhu, Xiangchen, Wang, Xiaofei, Chen, Jin, Hang, Xiaoning, Deng, Aixing, Zhang, Jun, and Zhang, Weijian

Subjects
*RICE varieties, *PLANT morphology, *METHANE, *DISSOCIATION (Chemistry), *SOIL solutions
Abstract

High-yield varieties with low methane emissions will benefit sustainable rice ( Oryza sativa L.) production. However, no specific plant characteristics have been identified to be primarily responsible for rice variety impacts on the CH 4 emission. We conducted a comprehensive study through comparing effects of 66 varieties on CH 4 under both greenhouse and field conditions to identify rice plant characteristics that may significantly affect soil CH 4 emission. Although there were significant differences in CH 4 emissions among the tested rice varieties, no significant and consistent relationships were observed between aboveground traits and CH 4 fluxes or dissolved CH 4 concentrations in soil solutions. Yet dissolved CH 4 concentrations were significantly correlated with the mean CH 4 flux over the growing season. In addition, cutting rice plants 5 cm off above the floodwater did not increase CH 4 fluxes, indicating that the CH 4 transport through the removed part of rice plant contributed little to the total CH 4 emission. Taken together, our results indicate that differences in CH 4 emissions among rice varieties primarily stem from the differential effects of rice plants on the belowground CH 4 production and oxidation. Aboveground plant traits do not provide reliable predictions of variety effects on CH 4 emissions. Future efforts should be focused on understanding belowground processes and the underlying mechanisms that govern rice variety impacts on the CH 4 emission. [ABSTRACT FROM AUTHOR]

Published
2015
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46. Intermittent flooding lowers the impact of elevated atmospheric CO2 on CH4 emissions from rice paddies.

Author

Qian, Haoyu, Chen, Jin, Zhu, Xiangchen, Wang, Ling, Liu, Yunlong, Zhang, Jun, Deng, Aixing, Song, Zhenwei, Ding, Yanfeng, Jiang, Yu, van Groenigen, Kees Jan, and Zhang, Weijian

Subjects
*ATMOSPHERIC carbon dioxide, *CARBON emissions, *GREENHOUSE gases, *CARBON dioxide, *FIELD emission
Abstract

Atmospheric CO 2 concentrations and water management practices both affect greenhouse gas (GHG) emissions from rice paddies, but interactive effects between these two factors are still unknown. Here, we show the first study to compare the impact of elevated atmospheric CO 2 (eCO 2) on GHG emissions under continuously flooded irrigation (CF) and under intermittently flooded (IF) conditions. Elevated CO 2 stimulated CH 4 emissions under CF by 50% in a field experiment and by 46% in a pot experiment, but it had no effect under IF in both experiments. Elevated CO 2 had no effect on N 2 O emissions in either the field or pot experiment. Rice root biomass, aboveground biomass and grain yield increased with eCO 2 , but were not affected by water management. Elevated CO 2 only stimulated the abundance of methanogens under CF, suggesting that increased soil O 2 availability with IF limited methanogenic activity under eCO 2. Our findings suggest that estimates of CH 4 emissions from global rice agriculture with eCO 2 need to account for recent changes in water management. • The first study to compare the effect of elevated CO 2 on GHG emissions under CF and IF. • Elevated CO 2 stimulated CH 4 emissions under CF, but had no effect under IF. • Elevated CO 2 did not affect N 2 O emissions under CF and IF. • Elevated CO 2 increased the abundance of methanogens under CF only. • Current estimates of CO 2 effects on CH 4 emissions from rice paddies may be too high. [ABSTRACT FROM AUTHOR]

Published
2022
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47. Organic amendments increase crop yield while mitigating greenhouse gas emissions from the perspective of carbon fees in a soybean-wheat system.

Author

Zhang, Xin, Qian, Haoyu, Hua, Keke, Chen, Huan, Deng, Aixing, Song, Zhenwei, Zhang, Jun, Raheem, Abdulkareem, Danso, Frederick, Wang, Daozhong, Zheng, Chengyan, and Zhang, Weijian

Subjects
*CROP yields, *WHEAT straw, *GREENHOUSE gases, *CATTLE manure, *FERTILIZERS, *CROP improvement
Abstract

Organic amendment often affects both crop yield and greenhouse gas (GHG) emission. Yet the impact of organic amendment on yield gains and GHG emissions is still unclear, particularly in long-term soybean-wheat cropping system. Based on a 30-year soybean-wheat cropping system experiment, the impact of organic amendments (i.e. straw and manure) on soil properties, crop yield, N 2 O and CH 4 emissions, and net ecosystem economic budget (NEEB) were investigated. The treatments were: chemical NPK fertilizer (NPK), chemical NPK plus low amount of wheat straw (NPKLS), chemical NPK plus high amount of wheat straw (NPKHS), chemical NPK plus pig manure (NPKPM), chemical NPK plus cattle manure (NPKCM), and a control with no fertilizer applied (CK). The long-term straw and manure amendments enhanced soybean yield by 13.1% and 44.0%, and improved wheat yield by 6.4% and 9.9%, respectively. Meanwhile, they stimulated N 2 O emissions by 25.1% and 49.0% respectively, without significant effect on CH 4 emissions, compared to the chemical NPK fertilizer treatment (NPK). The results of structural equation model showed that soil properties tested explained 76% of the variations observed in N 2 O emissions, which were directly affected by soil nitrification capacity, pH and denitrification capacity. Although straw and manure amendments increased the total GHG emissions investigated by 25.7% and 48.6% respectively, they showed insignificant effects on the greenhouse gas intensity (GHGI), and increased NEEB by 8.6% and 21.1%, respectively, compared to the NPK treatment. This indicates that the benefits arising from crop yield improvement through the use of organic amendments can cover the carbon fees caused by increased GHG emissions. Our findings suggest that organic amendment can be an effective strategy to simultaneously increase crop yield while mitigating greenhouse gas emissions from the perspective of carbon fees. [Display omitted] • Organic amendments stimulated total GHG emissions of N 2 O and CH 4. • Soil properties tested explained 76% of the variation in N 2 O emissions. • Organic amendments improved yield without increasing the greenhouse gas intensity. • Straw and manure amendments increased the net ecosystem economic budget. [ABSTRACT FROM AUTHOR]

Published
2022
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48. Impacts of planting systems on soil moisture, soil temperature and corn yield in rainfed area of Northeast China.

Author

Song, Zhenwei, Guo, Jinrui, Zhang, Zhenping, Kou, Taiji, Deng, Aixing, Zheng, Chengyan, Ren, Jun, and Zhang, Weijian

Subjects
*PLANTING, *SOIL moisture, *SOIL temperature, *CORN yields, *DRY farming
Abstract

Highlights: [•] Corn yield is affected by climate patterns in cool-high latitude rainfed area. [•] Flat planting increases topsoil water storage and minimum temperature at early stage. [•] Ridge planting can reduce waterlogging risk at middle and later growth stages. [•] Flat planting with ridge at V6 stage achieves higher corn yield due to improved soil moisture and temperature conditions. [Copyright &y& Elsevier]

Published
2013
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49. Warming impacts on winter wheat phenophase and grain yield under field conditions in Yangtze Delta Plain, China

Author

Tian, Yunlu, Chen, Jin, Chen, Changqing, Deng, Aixing, Song, Zhenwei, Zheng, Chengyan, Hoogmoed, Willem, and Zhang, Weijian

Subjects
*WINTER wheat, *GRAIN yields, *BIOMASS, *PLANT canopies, *PLANT communities, *GRAIN harvesting, *GLOBAL warming
Abstract

Abstract: A five-year experiment with Free Air Temperature Increase facility was conducted to investigate the actual responses of winter wheat phenophase and yield to warming in Yangtze Delta Plain, China. Air temperature increase of around 1.5°C in wheat canopy advanced crop phenophases significantly, leading to a reduction in length of the entire growth period by 10 days (P <0.05). This reduction was mainly found in the length of pre-anthesis phase, while the length of post-anthesis phase was prolonged slightly. Warming increased grain yield by 16.3% (P <0.05) whereas no significant effects were found on the aboveground biomass. Warming tended to increase the numbers of productive spike and filled grain and the harvest index. The areas of flag leaf and total green leaf at anthesis and the 1000-grain weight were 36.0, 19.2 and 5.9% higher in the warmed plots than the un-warmed control (P <0.05), respectively. Warming stimulated the filling rate of inferior grain (P <0.05), while the rate of superior grain stayed almost unchanged. The above evidences suggest that anticipated warming may facilitate winter wheat production in East China. [Copyright &y& Elsevier]

Published
2012
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50. Responses of dissolved organic carbon and dissolved nitrogen in surface water and soil to CO2 enrichment in paddy field

Author

Guo, Jia, Zhang, Mingqian, Zhang, Li, Deng, Aixing, Bian, Xinmin, Zhu, Jianguo, and Zhang, Weijian

Subjects
*DISSOLVED organic matter, *CARBON in soils, *NITROGEN in soils, *RICE, *CLIMATE change, *WETLANDS, *DRAINAGE, *CARBON compounds
Abstract

Abstract: Increasing evidences have shown that dissolved organic components are responsible for the significant C and N exports from terrestrial ecosystems to the surrounding aquatic ecosystems and very sensitive to CO2 enrichment. However, there is still a lack of direct evidence about CO2-led effects on these components at the ecosystem scale, especially in wetlands. We, therefore, simultaneously investigated the contents of dissolved organic carbon (DOC) and dissolved nitrogen (DN) in the surface water and soil layer in a paddy field under FACE facility in Eastern China. Elevated CO2 significantly increased the contents of DOC and DN in the surface water by 18.0% and 14.3% on average. Elevated CO2 also increased DOC content in the soil, but decreased DN content. The contents of DOC and DN in the soil–water interface of 0–1cm soil layer were on average 22.4% and 47.5% higher than in the 5–15cm soil layer. Besides, significant higher DOC and DN contents existed in the soil porewater than in the surface water. Due to multiple drainage regime and rainstorm-induced runoffs in rice cropping regions, CO2-led DOC and DN increments in the surface water may increase C and N exports from paddies to the surrounding aquatic ecosystems under future climate patterns. [Copyright &y& Elsevier]

Published
2011
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