Your search keyword '"Liu, Buchun"' showing total 5 results

1. Carbon footprint of maize-wheat cropping system after 40-year fertilization

Author

Shao, Guodong, Zhou, Jie, Liu, Buchun, Alharbi, Sulaiman Almwarai, Liu, Enke, and Kuzyakov, Yakov

Published

2024

2. Analysis of the Demand for Weather Index Agricultural Insurance on Household level in Anhui, China.

Author

Liu, BuChun, Li, MaoSong, Guo, Ying, and Shan, Kun

Subjects

AGRICULTURAL insurance, AGRICULTURE & the environment, FARMERS, NATURAL disasters

Abstract

Abstract: As an innovative tool, weather index agricultural insurance (WIAI) was introduced into China in 2008. Before product designing and selling to farmers, it is necessary to understand farmers’ real desire so that the product can be tailored to fit their needs. This paper focuses on the demand analysis for WIAI on household level. With this goal, 660 households located in 22 administrative villages in Changfeng and Huaiyuan county, Anhui province, China were surveyed. Survey questions covered risks faced by households, their coping mechanisms and willingness to pay for WIAI. Survey data were assessed and findings are shown as below: drought and flood were major weather risks for crops; the key coping strategies to crop loss were seeking employment elsewhere, or borrowing money from relatives or friends; most of investigated farmers showed interest in WIAI; those who were more familiar with insurance, or whose losses were higher due to deficient or excessive rainfall, or who had more trust in the accuracy of local weather forecasts, expressed more interest in WIAI with the quite low correlation coefficient, while statistically significant. It hints that there are potential demands for WIAI among farmers. However, methodologies deserve further development so as to provide more reliable assessment of the relationships between the willingness to pay and the abovementioned three factors. [ABSTRACT FROM AUTHOR]

Published

2010

3. Estimating potential yield and change in water budget for wheat and maize across Huang-Huai-Hai Plain in the future.

Author

Shirazi, Sana Zeeshan, Mei, Xurong, Liu, Buchun, and Liu, Yuan

Subjects

*WINTER wheat, *AGRICULTURAL productivity, *WHEAT, *CLIMATE change mitigation, *CORN, *WINTER grain, *WEATHER

Abstract

Climate change impacts crop productivity as atmospheric conditions and water supply change, particularly in intensive cropping areas. This study used the validated AquaCrop Model, which was run with downscaled daily climate data produced by SDSM and CanESM2. The changes in the potential grain yield of winter wheat and summer maize and water budget during the cropping seasons were estimated for the Huang-Huai-Hai Plain (3H Plain) under RCP4.5 and RCP8.5 scenarios. The results show that the potential yield of winter wheat is increasing with similar spatial patterns in the 2030s, 2050s, and 2080s, with much of the increase is distributed in Shandong and northeastern parts of Henan. During the winter wheat growth period, the water budget deficit will likely improve from −210 mm in the 2030s to −202 mm in 2080s under RCP4.5 and from −206 mm in the 2030s to −191 mm in 2080s under RCP8.5 across the 3H Plain. The water budget during the winter wheat period will continue to be in deficit in the north 3H Plain and improvements are estimated mostly in the lower southern areas of the Plain. The summer maize potential yield is estimated to increase from the baseline period, but yields will decrease by 0.81%, 1.19%, and 2.10% in the 2030s, 2050s, and 2080s, respectively, under RCP8.5 compared to RCP4.5. During the summer maize growth period, the water budget is also estimated to improve from 109 mm in 2030s to 126 mm in 2080s under RCP4.5 and 107 mm in the 2030s to 163 mm in 2080s under RCP8.5. This increase is mainly estimated in the central and south of the 3H Plain. The estimated ET c of winter wheat shows no significant decrease, while the reduction of 6 mm and 13 mm for summer maize is observed under RCP4.5 and RCP8.5, respectively. The study provides scientific evidence to devise adaptation and mitigation climate change strategies for agricultural productivity and water resource management. • The potential winter wheat yield will increase under RCP4.5 and RCP8.5 scenarios. • The increase in wheat yield follows a similar spatial pattern under both RCP scenarios. • The potential summer maize yield will decrease under RCP8.5 as compared to RCP4.5. • Water deficit for wheat will remain similar to the present with increased temperature. • Water budget during summer will significantly improve in the latter half of this century. [ABSTRACT FROM AUTHOR]

Published

2022

4. Assessment of the AquaCrop Model under different irrigation scenarios in the North China Plain.

Author

Shirazi, Sana Zeeshan, Mei, Xurong, Liu, Buchun, and Liu, Yuan

Subjects

*WINTER wheat, *IRRIGATION, *IRRIGATION management, *STANDARD deviations, *AGRICULTURAL productivity, *GRAIN yields

Abstract

Crop simulation models play an essential role in evaluating irrigation management strategies for improving agricultural water use in crop production. In this study, the AquaCrop model was used to calibrate and validate the grain yield and biomass of 11 cultivars (9 winter wheat and 2 summer maize) under full and water-saving irrigation practices. The model results were verified with the available data from the published literature. Under the full irrigation practice, widely used by farmers in the region for winter wheat, the Normalized Root Mean Square Error (NRMSE) was found to be between 2.00–9.90% for grain yield, 2.40–10.85% for biomass, and 0.42–19.61% for water productivity. Under water-saving irrigation for winter wheat, the NRMSE range was found to be between 5.80–16.00% for grain yield, 3.70–17.30% for biomass, and 3.80–13.79% for water productivity. For summer maize, the NRMSE was 5.95%, 6.08%, and 16.41% under full irrigation, and 9.51%, 8.41%, and 3.60% under water-saving irrigation for grain yield, biomass, and water productivity, respectively. For winter wheat and summer maize, the simulation accuracy of grain yield was high under full irrigation, with percent deviations under ± 11.00%. In this study, the simulation accuracy for winter wheat was low under water-saving irrigation, while the model simulated the yield and biomass for summer maize to acceptable accuracy. The model can be reliably used as a tool to simulate grain yield and biomass across the NCP region for winter wheat and summer maize. However, the limitations of the model must be considered when simulating winter wheat under water-stressed conditions. • AquaCrop is a crop growth model to simulate yield response to water. • The model simulation accuracy was high under full irrigation for wheat and maize. • For water-saving irrigation, model accuracy was high for maize compared to wheat. • The model can be reliably used as a tool to simulate yield and biomass across NCP. [ABSTRACT FROM AUTHOR]

Published

2021

5. Transcriptomics integrated with metabolomics reveals the effect of regulated deficit irrigation on anthocyanin biosynthesis in Cabernet Sauvignon grape berries.

Author

Yang, Bohan, He, Shuang, Liu, Yuan, Liu, Buchun, Ju, Yanlun, Kang, Dengzhao, Sun, Xiangyu, and Fang, Yulin

Subjects

*CABERNET wines, *DEFICIT irrigation, *BIOSYNTHESIS, *GRAPES, *METABOLOMICS, *BERRIES

Abstract

• Effects of RDI on anthocyanin biosynthesis in wine grapes was investigated. • RDI1 treatment increased anthocyanin content most effectively. • Revealing the changes of genes and substances under RDI by Omics. • Mapping the effects of anthocyanin biosynthetic pathway under RDI. Regulated deficit irrigation (RDI) is a new type of water-saving irrigation technology developed in recent years which was well suited to arid and semi-arid grape plant areas. The anthocyanin synthesis of grapes under RDI was revealed through omics in this study. RDI slightly decreased the hundred-grain weight and increased the soluble solid content, juice pH, reducing sugar content, and total anthocyanin content. Meanwhile, the total acid content decreased before ripening. Transcriptomics and metabolomics analyses revealed that large numbers of differentially expressed genes (DEGs) and significantly changed metabolites (SCMs) were filtered in the RDI groups. RDI1 with 30% ETc upregulated 7 related gene expression levels in the anthocyanin biosynthetic pathway and also increased some metabolites contents. Eventually, the contents of most monomeric anthocyanins in the RDI groups were increased, and the proportion of Mv increased in the ripe grapes of the RDI groups. In all, RDI is a useful water-saving irrigation method which could also increase anthocyanin content in grapes. [ABSTRACT FROM AUTHOR]

Published

2020