Singapore : , : Springer Singapore Pte. Limited, , 2024

©2024

981-9703-31-X

1 online resource (438 pages)

AhmadShakeel

AbbasGhulam

HussainSajjad

HoogenboomGerrit

Inglese

Intro -- Preface -- Contents -- About the Authors -- 1: Cropping Systems and Application of Models -- 1.1  Cropping Systems -- 1.2  Global Cropping Systems -- 1.3  Cropping System Modeling -- 1.4  Conclusion -- References -- 2: Sequential Modeling -- 2.1  Introduction -- 2.2  Types of Multiple-Cropping Systems -- 2.2.1  Sequential Cropping -- 2.2.2  Intercropping -- 2.2.3  Relay Cropping -- 2.2.4  Mixed Cropping -- 2.3  Cropping Systems in the World -- 2.4  Cereal-Based Cropping Systems -- 2.4.1  Rice-Wheat Cropping System -- 2.4.2  Rice-Rice Cropping System -- 2.4.3  Wheat-Maize Cropping System -- 2.4.4  Rice-Maize Cropping System -- 2.5  Legume-Based Cropping Systems -- 2.6  Oilseed-Based Cropping Systems -- 2.7  Fodder-Based Cropping Systems -- 2.8  Cropping System Research -- 2.9  Decision Support System for Cropping System Research -- 2.10  DSSAT Model Description -- 2.11  DSSAT Sequence Analysis: Soybean-Chickpea Cropping System-A Case Study -- 2.11.1  DSSAT Sequence Analysis Program Description -- 2.11.2  Input and Output Files for DSSAT Sequence Analysis -- 2.11.3  DSSAT Sequence Analysis Program Operation -- 2.11.4  DSSAT Sequence Analysis's Economic Analysis -- 2.12  APSIM Model -- 2.13  APSIM Model Rotation Analysis: A Case Study of Wheat-Alfalfa Rotation -- 2.13.1  APSIM Model

Rotational Analysis Program Description -- 2.13.2  APSIM Rotational Program Operation -- 2.14  Conclusion -- References -- 3: Rice-Wheat System -- 3.1  Introduction -- 3.2  Issues of Rice-Wheat Cropping System -- 3.3  Rice-Wheat Modeling -- 3.4  Climate Change Influence on Rice-Wheat System Phenology -- 3.5  Climate Change Influence on Rice-Wheat System -- 3.5.1  Impact of Climate Change on Rice -- 3.5.2  Impact of Climate Change on Wheat -- 3.6  Rice-Wheat Cropping System Under Changing Climate: AgMIP Pakistan, a Case Study.

3.6.1  Sensitivity of Current Rice-Wheat System Productivity to Climate Change -- 3.6.2  The Impacts of Climate Change on Future Rice-Wheat System Production -- 3.7  Conclusion -- References -- 4: Maize-Maize System -- 4.1  Introduction -- 4.2  Issues of Maize-Maize System -- 4.3  Decision Support System for Agrotechnology Transfer -- 4.4  Climate Change and Temperature Trend -- 4.5  Climate Warming Impact on Maize Morphophysiological Responses -- 4.6  Impact of Climate Change on Crop Phenology -- 4.7  Case Study in Pakistan -- 4.8  Climate Change Impact on Current and Future Scenarios of Crop Productivity -- 4.9  Adaption Strategies -- 4.10  Conclusion -- References -- 5: Sunflower-Sunflower System -- 5.1  Introduction -- 5.2  Issues of Sunflower-Sunflower Cropping System -- 5.3  Decision Support System for Agrotechnology Transfer -- 5.4  Climate Change and Temperature Trend -- 5.5  Climate Change Impact on Sunflower Morphophysiological Responses -- 5.6  Impact of Climate Change on Crop Phenology -- 5.7  Case Study in Pakistan -- 5.8  Impact of Climate Change on Current and Future Scenarios of Crop Production -- 5.9  Adaption Strategies -- 5.10  Conclusion -- References -- 6: Cotton-Wheat System -- 6.1  Introduction -- 6.2  Description of Cropping System Investigated -- 6.3  Issues of Cotton-Wheat Cropping System -- 6.4  Cotton-Wheat Modeling -- 6.5  Climate Change Influence on Cotton-Wheat System Phenology -- 6.6  Impact of Climate Change on Cotton Production -- 6.7  Impact of Climate Change on Wheat Production -- 6.8  AgMIP Case Study -- 6.9  Conclusion -- References -- 7: Chickpea-Mung Bean System -- 7.1  Introduction -- 7.2  Issues of Chickpea-Mung Bean Cropping System -- 7.3  Decision Support System for Agrotechnology Transfer -- 7.3.1  Chickpea -- 7.3.2  Mung Bean -- 7.4  Climate Change and Temperature Trend.

7.5  Climate Change Impact on Chickpea-Mung Bean Morphophysiological Responses -- 7.5.1  Chickpea -- 7.5.2  Mung Bean -- 7.6  Impact of Climate Change on Phenology -- 7.7  Impact of Climate Change on Current and Future Scenarios of Crop Production -- 7.7.1  Chickpea -- 7.7.2  Mung Bean -- 7.8  Adaption Strategies -- 7.9  Conclusion -- References -- 8: Soybean-Soybean System -- 8.1  Introduction -- 8.2  Issues of Soybean-Soybean Cropping System -- 8.3  Decision Support System for Agrotechnology Transfer -- 8.4  Climate Change and Temperature Trend -- 8.5  Climate Change Impact on Soybean Morphophysiological Responses -- 8.6  Impact of Climate Change on Soybean Phenology -- 8.7  Impact of Climate Change on Current and Future Scenarios of Soybean Production -- 8.8 Soybean Case Study in Pakistan -- 8.9  Adaption Strategies -- 8.10  Conclusion -- References -- 9: Sugarcane System -- 9.1  Introduction -- 9.2  Issues of Sugarcane Crop -- 9.3  Sugarcane Modeling -- 9.4  Climate Change Impact on Sugarcane Phenology -- 9.5  Impact of Climate Change on Phenology: A Case Study in Pakistan -- 9.6  CTWN Model Sensitivity for Sugarcane -- 9.7  Climate Change Impact on Sugarcane Production Systems -- 9.8  Climate Change's Impact on Sugarcane Morphophysiology -- 9.9  Climate Change's Impact on Sugarcane Quality -- 9.10  Climate Change's Impact of Pest

on Sugarcane -- 9.11  Adaptation Strategies -- 9.12  Conclusion -- References -- 10: Potato-Potato System -- 10.1  Introduction -- 10.2  Background -- 10.3  Potato Cropping System and Global Distribution -- 10.4  Decision Support System for Agrotechnology Transfer for Potato System -- 10.5  Impact of Climate Change on Potato Phenology -- 10.6  Potato-Potato System: A Case Study of Pakistan -- 10.7  Impact of Climate Change on Current and Future Scenarios of Potato Production Systems.

10.8  Climate Change Impact on Potato Production -- 10.9  Adaptation Strategies -- 10.10  Conclusion -- References -- 11: Sweet Corn-Bell Pepper System -- 11.1  Introduction -- 11.2  Cropping Systems and Geographical Distribution -- 11.3  Decision Support System for Agrotechnology Transfer -- 11.4  Climate Change -- 11.5  Impact of Climate Change on Crop Phenology -- 11.6  Effects of Climate Change on Crop Production Scenarios for the Present and the Future -- 11.7  Case Study -- 11.8  Adaptation Techniques -- 11.9  Conclusion -- References -- 12: C4 Cereal-Based Fodder Systems -- 12.1  Introduction -- 12.2  Issues of C4 Summer Cereal-Based Fodder Cropping Systems -- 12.3  Decision Support System for Agrotechnology Transfer -- 12.4  Climate Change and Temperature Trends -- 12.5  Climate Change Impact on Maize, Millet, and Sorghum Biomass Production on Current and Future Scenarios -- 12.6  Adaptation Strategies -- 12.7  Conclusion -- References -- 13: Alfalfa System -- 13.1  Introduction -- 13.2  Issues of Alfalfa Cropping System -- 13.3  Alfalfa Modeling -- 13.4  Modeling of the Dynamics of Seed Lot Germination -- 13.5  Impact of Climate Change on Alfalfa Phenology -- 13.6  Climate Change Impact on Alfalfa Production -- 13.7  Climate Change's Impact on Alfalfa Quality -- 13.8  Adaptation Strategies -- 13.9  Conclusion -- References -- 14: Groundnut-Canola System -- 14.1  Introduction -- 14.2  Issues of Groundnut-Canola Cropping System -- 14.3  Decision Support System for Agrotechnology Transfer -- 14.3.1  Groundnut -- 14.3.2  Canola -- 14.4  Climate Change and Temperature Trend -- 14.5  Climate Change Impact on Groundnut-Canola Morphophysiological Responses -- 14.5.1  Groundnut -- 14.5.2  Canola -- 14.6  Impact of Climate Change on Groundnut-Canola System Phenology -- 14.6.1  Groundnut -- 14.6.2  Canola -- 14.6.2.1  Case Study in Pakistan in Asia.

14.7  Impact of Climate Change on Current and Future Scenarios of Crop Production -- 14.7.1  Groundnut -- 14.7.2  Canola -- 14.8  Adaptation Strategies -- 14.9  Conclusion -- References -- 15: Guar-Wheat System -- 15.1  Introduction -- 15.2  Guar Phenology -- 15.3  Decision Support System for Agrotechnology Transfer -- 15.4  Application of CROPGRO Model for Simulating Guar Growth and Productivity -- 15.5  Integration of Guar in Dryland Wheat System -- 15.6  Conclusion -- References.