Yuxing Peng , Feixia Zhang , Shuai Zhang , Zizhong Li , Shuming Cao , Chuxin Luo , Fei Yu
{"title":"Using APSIM to optimize corn nitrogen fertilizer application levels in alfalfa-corn rotation system in Northeast China","authors":"Yuxing Peng , Feixia Zhang , Shuai Zhang , Zizhong Li , Shuming Cao , Chuxin Luo , Fei Yu","doi":"10.1016/j.fcr.2024.109596","DOIUrl":null,"url":null,"abstract":"<div><h3>Context</h3><div>Alfalfa (<em>Medicago sativa</em> L.) consumes a large amount of soil inorganic nitrogen (N) but can supply ample rhizosphere deposited N to subsequent crops. Therefore, N fertilizer application levels should be optimized for corn under long-term alfalfa-corn (AC) rotation system to achieve high yield and N use efficiency.</div></div><div><h3>Objective</h3><div>The present study assessed the yield and water and N use efficiency of corn under N fertilizer application in a long-term AC cropping system and optimized the corn N fertilizer application level using the Agricultural Production Systems sIMulator (APSIM).</div></div><div><h3>Methods</h3><div>APSIM was calibrated and validated utilizing the experimental datasets of yield, aboveground biomass, plant N uptake, soil water storage, and inorganic N at 0−140 cm soil layer during corn growth with four N fertilizer treatments (0, 130, 195, and 260 kg N ha<sup>−1</sup>), which were collected from a six-year-old alfalfa field experiment carried out in Lishu County (Jilin Province, China) from 2020 to 2022; the field experiment was initiated in 2014. The validated APSIM was then utilized to simulate the long-term (1981−2020) characteristics of crop and soil under different corn N fertilizer application levels in a continuous corn (CC) cropping system and different alfalfa-corn rotation systems (one, two, three, four, and five years of alfalfa followed by two years of corn; 1A2C, 2A2C, 3A2C, 4A2C, 5A2C). The simulated N treatments included 0−300 kg N ha<sup>−1</sup> range with an increment of 30 kg N ha<sup>−1</sup>.</div></div><div><h3>Results</h3><div>Model evaluation revealed that APSIM effectively captured the dynamics of the crop, soil water, and soil inorganic N during corn cultivation following alfalfa at four N fertilizer application levels. The normalized root-mean-square errors between the observed and simulated values under different treatments were less than 30 %. Alfalfa had legacy effects on the soil water and soil N mineralization (N<sub>min</sub>) of subsequent first-year corn, which ensured the corn yield following alfalfa. The first-year net N<sub>min</sub> in the soil with corn following alfalfa increased by 140 % (65 %−268 %) compared to the CC cropping system. Alfalfa planting also increased the 0−140 cm soil inorganic N before sowing (N<sub>sow</sub>) by 351 % (292 %−463 %) for the subsequent corn with no N fertilizer application and the 0−140 cm soil water storage before sowing by 22 % for the subsequent corn with relatively high N fertilizer application (300 kg N ha<sup>−1</sup>) compared to the CC cropping system. The highest yield and N use efficiency could be achieved by applying 90 kg N ha<sup>−1</sup> N fertilizer for 1A2C/2A2C/3A2C rotation systems and 60 kg N ha<sup>−1</sup> N fertilizer for 4A2C/5A2C rotation systems to the first-year corn following alfalfa. However, the N fertilizer requirement of the second-year corn following alfalfa under AC rotation systems was the same as that under the CC cropping system (150 kg N ha<sup>−1</sup>).</div></div><div><h3>Conclusions</h3><div>The present study’s findings indicate 60 kg N ha<sup>−1</sup> N fertilizer application to the first-year corn following alfalfa under 1A2C/2A2C/3A2C rotation systems and 90 kg N ha<sup>−1</sup> under 4A2C/5A2C rotation systems.</div></div><div><h3>Implications</h3><div>The study provides a deeper understanding of alfalfa’s effects on subsequent corn and a guidance for planning N fertilizer management in corn production following alfalfa.</div></div>","PeriodicalId":12143,"journal":{"name":"Field Crops Research","volume":"318 ","pages":"Article 109596"},"PeriodicalIF":5.6000,"publicationDate":"2024-09-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Field Crops Research","FirstCategoryId":"97","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0378429024003496","RegionNum":1,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"AGRONOMY","Score":null,"Total":0}
引用次数: 0
Abstract
Context
Alfalfa (Medicago sativa L.) consumes a large amount of soil inorganic nitrogen (N) but can supply ample rhizosphere deposited N to subsequent crops. Therefore, N fertilizer application levels should be optimized for corn under long-term alfalfa-corn (AC) rotation system to achieve high yield and N use efficiency.
Objective
The present study assessed the yield and water and N use efficiency of corn under N fertilizer application in a long-term AC cropping system and optimized the corn N fertilizer application level using the Agricultural Production Systems sIMulator (APSIM).
Methods
APSIM was calibrated and validated utilizing the experimental datasets of yield, aboveground biomass, plant N uptake, soil water storage, and inorganic N at 0−140 cm soil layer during corn growth with four N fertilizer treatments (0, 130, 195, and 260 kg N ha−1), which were collected from a six-year-old alfalfa field experiment carried out in Lishu County (Jilin Province, China) from 2020 to 2022; the field experiment was initiated in 2014. The validated APSIM was then utilized to simulate the long-term (1981−2020) characteristics of crop and soil under different corn N fertilizer application levels in a continuous corn (CC) cropping system and different alfalfa-corn rotation systems (one, two, three, four, and five years of alfalfa followed by two years of corn; 1A2C, 2A2C, 3A2C, 4A2C, 5A2C). The simulated N treatments included 0−300 kg N ha−1 range with an increment of 30 kg N ha−1.
Results
Model evaluation revealed that APSIM effectively captured the dynamics of the crop, soil water, and soil inorganic N during corn cultivation following alfalfa at four N fertilizer application levels. The normalized root-mean-square errors between the observed and simulated values under different treatments were less than 30 %. Alfalfa had legacy effects on the soil water and soil N mineralization (Nmin) of subsequent first-year corn, which ensured the corn yield following alfalfa. The first-year net Nmin in the soil with corn following alfalfa increased by 140 % (65 %−268 %) compared to the CC cropping system. Alfalfa planting also increased the 0−140 cm soil inorganic N before sowing (Nsow) by 351 % (292 %−463 %) for the subsequent corn with no N fertilizer application and the 0−140 cm soil water storage before sowing by 22 % for the subsequent corn with relatively high N fertilizer application (300 kg N ha−1) compared to the CC cropping system. The highest yield and N use efficiency could be achieved by applying 90 kg N ha−1 N fertilizer for 1A2C/2A2C/3A2C rotation systems and 60 kg N ha−1 N fertilizer for 4A2C/5A2C rotation systems to the first-year corn following alfalfa. However, the N fertilizer requirement of the second-year corn following alfalfa under AC rotation systems was the same as that under the CC cropping system (150 kg N ha−1).
Conclusions
The present study’s findings indicate 60 kg N ha−1 N fertilizer application to the first-year corn following alfalfa under 1A2C/2A2C/3A2C rotation systems and 90 kg N ha−1 under 4A2C/5A2C rotation systems.
Implications
The study provides a deeper understanding of alfalfa’s effects on subsequent corn and a guidance for planning N fertilizer management in corn production following alfalfa.
期刊介绍:
Field Crops Research is an international journal publishing scientific articles on:
√ experimental and modelling research at field, farm and landscape levels
on temperate and tropical crops and cropping systems,
with a focus on crop ecology and physiology, agronomy, and plant genetics and breeding.