Selection of the best nitrogen fertilizer management scenario in wheat based on Palmer drought severity index with an environmental perspective

Selection of the best nitrogen fertilizer management scenario in wheat based on Palmer drought severity index with an environmental perspective

In arid and semi-arid regions, where winter wheat relies partially on precipitation for its water requirements, the timing and amount of precipitation play a pivotal role in nitrogen (N) losses. Given the extensive cultivation of wheat in these areas, farmers' oversight of N rates, N splitting,...

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Veröffentlicht in:European journal of agronomy 2023-11, Vol.151, p.126980, Article 126980
Hauptverfasser: Amirhajloo, Sajad, Gheysari, Mahdi, Shayannejad, Mohammad, Shirvani, Mehran
Format: Artikel
Sprache:eng
Schlagworte:
absorption
agronomy
biomass
CERES-Wheat
Crop Environment Resource Synthesis models
drought
farmers
fertilizer rates
irrigation water
meteorological data
model validation
Nitrate
nitrogen
nitrogen fertilizers
nutrient use efficiency
principal component analysis
Principal component analysis (PCA)
Soil available water content (AWC)
soil water
water content
winter wheat
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container_start_page 126980
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creator Amirhajloo, Sajad
Gheysari, Mahdi
Shayannejad, Mohammad
Shirvani, Mehran
description In arid and semi-arid regions, where winter wheat relies partially on precipitation for its water requirements, the timing and amount of precipitation play a pivotal role in nitrogen (N) losses. Given the extensive cultivation of wheat in these areas, farmers' oversight of N rates, N splitting, and the impact of precipitation patterns on N losses have led to water resources contamination. Therefore, tailoring N management to drought condition fluctuations can reduce N losses. The goal was to boost wheat yield while minimizing N losses. The CERES-Wheat model was meticulously calibrated and evaluated over three years, involving an experimental field and five farmer fields. The calibrated model simulated twenty-five N fertilizer scenarios, spanning various N levels (50–250 kg ha−1) and split patterns. This conesidered soil textures and meteorological data from 1992 to 2020. The model's outcomes, encompassing various yield indices and performance metrics such as water productivity (WP), irrigation water productivity (IWP), N residual in soil (NR), N leaching (NL), available N use efficiency (ANUE), N absorption efficiency (NAE), and N utilization efficiency (NUE), were categorized into four distinct groups based on the Palmer's Drought Severity Index (PDSI): Group A: Positive PDSI all season, Group B: Negative PDSI all season, Group C: Positive early, negative later, and Group D: Negative early, positive later. Indices underwent thorough Principal Component Analysis (PCA) to identify the optimal scenario. Model evaluation represented key parameters comprehensively. Simulated total biomass matched real-world conditions (NRMSE 12.44–26.08%, d-index 0.86–0.97). Soil moisture and N fell within specific ranges (NRMSE 18.79–25.60%, RMSE 1.98–4.95 mg kg−1). Comparing different drought and soil conditions, significant performance metric differences emerged. Specifically, in Groups A and D, WP, IWP, ANUE, and NAE increased by 3.38%, 11.53%, 5.86%, and 5.76% compared to C and B. Group B had an 8.55-fold NL increase over A, while Group A saw a substantial 50.64% NR surge compared to B. In overall assessment, the study has identified that the optimal N application rate for the study area is 150 kg ha−1. However, determining the most appropriate N split pattern hinges on the dynamic interplay between PDSI and soil available water content (AWC). [Display omitted] •25 nitrogen scenarios were tested, spanning various N levels and split patterns.•The simulation of N scenarios
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Given the extensive cultivation of wheat in these areas, farmers' oversight of N rates, N splitting, and the impact of precipitation patterns on N losses have led to water resources contamination. Therefore, tailoring N management to drought condition fluctuations can reduce N losses. The goal was to boost wheat yield while minimizing N losses. The CERES-Wheat model was meticulously calibrated and evaluated over three years, involving an experimental field and five farmer fields. The calibrated model simulated twenty-five N fertilizer scenarios, spanning various N levels (50–250 kg ha−1) and split patterns. This conesidered soil textures and meteorological data from 1992 to 2020. The model's outcomes, encompassing various yield indices and performance metrics such as water productivity (WP), irrigation water productivity (IWP), N residual in soil (NR), N leaching (NL), available N use efficiency (ANUE), N absorption efficiency (NAE), and N utilization efficiency (NUE), were categorized into four distinct groups based on the Palmer's Drought Severity Index (PDSI): Group A: Positive PDSI all season, Group B: Negative PDSI all season, Group C: Positive early, negative later, and Group D: Negative early, positive later. Indices underwent thorough Principal Component Analysis (PCA) to identify the optimal scenario. Model evaluation represented key parameters comprehensively. Simulated total biomass matched real-world conditions (NRMSE 12.44–26.08%, d-index 0.86–0.97). Soil moisture and N fell within specific ranges (NRMSE 18.79–25.60%, RMSE 1.98–4.95 mg kg−1). Comparing different drought and soil conditions, significant performance metric differences emerged. Specifically, in Groups A and D, WP, IWP, ANUE, and NAE increased by 3.38%, 11.53%, 5.86%, and 5.76% compared to C and B. Group B had an 8.55-fold NL increase over A, while Group A saw a substantial 50.64% NR surge compared to B. In overall assessment, the study has identified that the optimal N application rate for the study area is 150 kg ha−1. However, determining the most appropriate N split pattern hinges on the dynamic interplay between PDSI and soil available water content (AWC). 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Given the extensive cultivation of wheat in these areas, farmers' oversight of N rates, N splitting, and the impact of precipitation patterns on N losses have led to water resources contamination. Therefore, tailoring N management to drought condition fluctuations can reduce N losses. The goal was to boost wheat yield while minimizing N losses. The CERES-Wheat model was meticulously calibrated and evaluated over three years, involving an experimental field and five farmer fields. The calibrated model simulated twenty-five N fertilizer scenarios, spanning various N levels (50–250 kg ha−1) and split patterns. This conesidered soil textures and meteorological data from 1992 to 2020. The model's outcomes, encompassing various yield indices and performance metrics such as water productivity (WP), irrigation water productivity (IWP), N residual in soil (NR), N leaching (NL), available N use efficiency (ANUE), N absorption efficiency (NAE), and N utilization efficiency (NUE), were categorized into four distinct groups based on the Palmer's Drought Severity Index (PDSI): Group A: Positive PDSI all season, Group B: Negative PDSI all season, Group C: Positive early, negative later, and Group D: Negative early, positive later. Indices underwent thorough Principal Component Analysis (PCA) to identify the optimal scenario. Model evaluation represented key parameters comprehensively. Simulated total biomass matched real-world conditions (NRMSE 12.44–26.08%, d-index 0.86–0.97). Soil moisture and N fell within specific ranges (NRMSE 18.79–25.60%, RMSE 1.98–4.95 mg kg−1). Comparing different drought and soil conditions, significant performance metric differences emerged. Specifically, in Groups A and D, WP, IWP, ANUE, and NAE increased by 3.38%, 11.53%, 5.86%, and 5.76% compared to C and B. Group B had an 8.55-fold NL increase over A, while Group A saw a substantial 50.64% NR surge compared to B. In overall assessment, the study has identified that the optimal N application rate for the study area is 150 kg ha−1. However, determining the most appropriate N split pattern hinges on the dynamic interplay between PDSI and soil available water content (AWC). [Display omitted] •25 nitrogen scenarios were tested, spanning various N levels and split patterns.•The simulation of N scenarios is facilitated by the reliable CERES-Wheat model.•The utilization of PDSI proved as a suitable method for determining N rate and split.•Optimal N management relies on considering factors such as mindset, PDSI, and AWC.•The recommended nitrogen supply rate in the Balanced Approach is 150 kg ha−1.</description><subject>absorption</subject><subject>agronomy</subject><subject>biomass</subject><subject>CERES-Wheat</subject><subject>Crop Environment Resource Synthesis models</subject><subject>drought</subject><subject>farmers</subject><subject>fertilizer rates</subject><subject>irrigation water</subject><subject>meteorological data</subject><subject>model validation</subject><subject>Nitrate</subject><subject>nitrogen</subject><subject>nitrogen fertilizers</subject><subject>nutrient use efficiency</subject><subject>principal component analysis</subject><subject>Principal component analysis (PCA)</subject><subject>Soil available water content (AWC)</subject><subject>soil water</subject><subject>water content</subject><subject>winter wheat</subject><issn>1161-0301</issn><issn>1873-7331</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><recordid>eNp9kL1u2zAUhYmgAeI6eYBuHLvI4Y8kUuhUGG0SwEALtJkJirq0aUikS9JOnJfoK4eCO3fiHc75wPMh9ImSFSW0vd-vYK9XjDC-oqztJLlCCyoFrwTn9EO5aUsrwgm9QR9T2hNCJGvqBfr7C0Yw2QWPg8V5B7iHlLF3OYYteGwhZje6N4h40l5vYQKfcTLgdXQBO49fdqAz7nWCARfKTz1OJTzEcNzuShJOEF0-l-QAr_jF5R3WHoM_uRj8DNMjPkBMh_kXJ7hF11aPCe7-vUv0_P3b7_Vjtfnx8LT-uqkMkyxXVnQDJVpYVkvbCNM1Qva2lT2QnvO64boxYqDcSMakFbpvBO8EqaG1MHRM8iX6fOEeYvhzLJPV5MqqcdQewjEpThtOazmjloheoiaGlCJYdYhu0vGsKFGzfLVXRb6a5auL_NL5culA2XByEFUyDryBwcUyVA3B_af9Dh2zj8w</recordid><startdate>202311</startdate><enddate>202311</enddate><creator>Amirhajloo, Sajad</creator><creator>Gheysari, Mahdi</creator><creator>Shayannejad, Mohammad</creator><creator>Shirvani, Mehran</creator><general>Elsevier B.V</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7S9</scope><scope>L.6</scope><orcidid>https://orcid.org/0000-0002-6461-1105</orcidid></search><sort><creationdate>202311</creationdate><title>Selection of the best nitrogen fertilizer management scenario in wheat based on Palmer drought severity index with an environmental perspective</title><author>Amirhajloo, Sajad ; Gheysari, Mahdi ; Shayannejad, Mohammad ; Shirvani, Mehran</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c282t-f79d10a7f248f57c9578bf68be0b33453a5c7d13c8228f7ab5739704e6fed9283</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2023</creationdate><topic>absorption</topic><topic>agronomy</topic><topic>biomass</topic><topic>CERES-Wheat</topic><topic>Crop Environment Resource Synthesis models</topic><topic>drought</topic><topic>farmers</topic><topic>fertilizer rates</topic><topic>irrigation water</topic><topic>meteorological data</topic><topic>model validation</topic><topic>Nitrate</topic><topic>nitrogen</topic><topic>nitrogen fertilizers</topic><topic>nutrient use efficiency</topic><topic>principal component analysis</topic><topic>Principal component analysis (PCA)</topic><topic>Soil available water content (AWC)</topic><topic>soil water</topic><topic>water content</topic><topic>winter wheat</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Amirhajloo, Sajad</creatorcontrib><creatorcontrib>Gheysari, Mahdi</creatorcontrib><creatorcontrib>Shayannejad, Mohammad</creatorcontrib><creatorcontrib>Shirvani, Mehran</creatorcontrib><collection>CrossRef</collection><collection>AGRICOLA</collection><collection>AGRICOLA - Academic</collection><jtitle>European journal of agronomy</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Amirhajloo, Sajad</au><au>Gheysari, Mahdi</au><au>Shayannejad, Mohammad</au><au>Shirvani, Mehran</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Selection of the best nitrogen fertilizer management scenario in wheat based on Palmer drought severity index with an environmental perspective</atitle><jtitle>European journal of agronomy</jtitle><date>2023-11</date><risdate>2023</risdate><volume>151</volume><spage>126980</spage><pages>126980-</pages><artnum>126980</artnum><issn>1161-0301</issn><eissn>1873-7331</eissn><abstract>In arid and semi-arid regions, where winter wheat relies partially on precipitation for its water requirements, the timing and amount of precipitation play a pivotal role in nitrogen (N) losses. Given the extensive cultivation of wheat in these areas, farmers' oversight of N rates, N splitting, and the impact of precipitation patterns on N losses have led to water resources contamination. Therefore, tailoring N management to drought condition fluctuations can reduce N losses. The goal was to boost wheat yield while minimizing N losses. The CERES-Wheat model was meticulously calibrated and evaluated over three years, involving an experimental field and five farmer fields. The calibrated model simulated twenty-five N fertilizer scenarios, spanning various N levels (50–250 kg ha−1) and split patterns. This conesidered soil textures and meteorological data from 1992 to 2020. The model's outcomes, encompassing various yield indices and performance metrics such as water productivity (WP), irrigation water productivity (IWP), N residual in soil (NR), N leaching (NL), available N use efficiency (ANUE), N absorption efficiency (NAE), and N utilization efficiency (NUE), were categorized into four distinct groups based on the Palmer's Drought Severity Index (PDSI): Group A: Positive PDSI all season, Group B: Negative PDSI all season, Group C: Positive early, negative later, and Group D: Negative early, positive later. Indices underwent thorough Principal Component Analysis (PCA) to identify the optimal scenario. Model evaluation represented key parameters comprehensively. Simulated total biomass matched real-world conditions (NRMSE 12.44–26.08%, d-index 0.86–0.97). Soil moisture and N fell within specific ranges (NRMSE 18.79–25.60%, RMSE 1.98–4.95 mg kg−1). Comparing different drought and soil conditions, significant performance metric differences emerged. Specifically, in Groups A and D, WP, IWP, ANUE, and NAE increased by 3.38%, 11.53%, 5.86%, and 5.76% compared to C and B. Group B had an 8.55-fold NL increase over A, while Group A saw a substantial 50.64% NR surge compared to B. In overall assessment, the study has identified that the optimal N application rate for the study area is 150 kg ha−1. However, determining the most appropriate N split pattern hinges on the dynamic interplay between PDSI and soil available water content (AWC). [Display omitted] •25 nitrogen scenarios were tested, spanning various N levels and split patterns.•The simulation of N scenarios is facilitated by the reliable CERES-Wheat model.•The utilization of PDSI proved as a suitable method for determining N rate and split.•Optimal N management relies on considering factors such as mindset, PDSI, and AWC.•The recommended nitrogen supply rate in the Balanced Approach is 150 kg ha−1.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.eja.2023.126980</doi><orcidid>https://orcid.org/0000-0002-6461-1105</orcidid></addata></record>
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source Elsevier ScienceDirect Journals
subjects absorption
agronomy
biomass
CERES-Wheat
Crop Environment Resource Synthesis models
drought
farmers
fertilizer rates
irrigation water
meteorological data
model validation
Nitrate
nitrogen
nitrogen fertilizers
nutrient use efficiency
principal component analysis
Principal component analysis (PCA)
Soil available water content (AWC)
soil water
water content
winter wheat
title Selection of the best nitrogen fertilizer management scenario in wheat based on Palmer drought severity index with an environmental perspective
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