Field-scale studies quantify limitations for wheat grain zinc biofortification in dryland areas

被引:6
作者
Li, Chao [1 ]
Guo, Zikang [1 ]
Wang, Xingshu [1 ]
Ma, Yue [1 ]
Liu, Jinshan [1 ,2 ]
Shi, Mei [1 ,2 ]
Zhang, Di [3 ]
Malhi, Sukhdev S. [4 ]
Siddique, Kadambot H. M. [5 ]
Wang, Zhaohui [1 ,2 ]
机构
[1] Northwest A&F Univ, Coll Nat Resources & Environm, Minist Agr, Key Lab Plant Nutr & Agri Environm Northwest China, Shaanxi 712100, Peoples R China
[2] Northwest A&F Univ, State Key Lab Crop Stress Biol Arid Areas, Shaanxi 712100, Peoples R China
[3] Yangling Vocat & Tech Coll, Shaanxi 712100, Peoples R China
[4] Univ Alberta, Dept Renewable Resources, Edmonton, AB, Canada
[5] Univ Western Australia, UWA Inst Agr, Perth, WA 6001, Australia
来源
EUROPEAN JOURNAL OF AGRONOMY | 2023年 / 142卷
关键词
Wheat; Grain Zn concentration; DTPA-Zn; Olsen-P; Cultivar; SOIL FERTILITY MANAGEMENT; WINTER-WHEAT; AGRONOMIC BIOFORTIFICATION; MAIZE PRODUCTIVITY; CEREAL-GRAINS; IRON; PHOSPHORUS; YIELD; PROTEIN; FERTILIZATION;
D O I
10.1016/j.eja.2022.126687
中图分类号
S3 [农学(农艺学)];
学科分类号
0901 ;
摘要
Optimizing of agronomic measures is an efficient way to improve crop zinc (Zn) nutrition and human dietary Zn intake. We collected field management, soil, and plant information from 78 fields in Shuiqing, 106 fields in Yongshou, and 120 fields in Qiujialing on China's Loess Plateau to explore limitations in wheat grain Zn and design alternative options to achieve the target grain Zn concentration (40 mg kg-1). The Shuiqing fields had an average grain yield of 5022 kg ha-1 and grain Zn concentration of 22.8 mg kg-1, with no fields achieving the target grain Zn concentration due to phosphorus (P) fertilizer overuse (254 kg P2O5 ha-1) and very low soil DTPA-Zn (0.23 mg kg-1). Two Yongshou fields reached the target grain Zn concentration but had 52.3%, 16.0%, and 51.4% lower average grain yield, P fertilizer rate, and soil Olsen-P, respectively, than other fields. The Qiujialing fields had an average grain Zn concentration of 34.8 mg kg-1, with 18.3% of fields >= 40 mg kg-1, of which 91% had soil DTPA-Zn >= 0.5 mg kg-1 and 45.2% higher grain Zn uptake than other fields due to newly released wheat cultivars, low P fertilizer rates, low soil Olsen-P, and high soil mineral nitrogen. In conclusion, a feasible framework for achieving the target grain Zn level would be using cultivars with high Zn uptake capacity, reducing P fertilizer use and soil Olsen-P, and improving soil available Zn in low Zn soils.
引用
收藏
页数:10
相关论文
共 50 条
  • [31] Field-Scale Precision: Predicting Grain Yield of Diverse Wheat Breeding Lines Using High-Throughput UAV Multispectral Imaging
    Ali, Nisar
    Mohammed, Ahmed
    Bais, Abdul
    Berraies, Samia
    Ruan, Yuefeng
    Cuthbert, Richard D.
    Sangha, Jatinder S.
    [J]. IEEE JOURNAL OF SELECTED TOPICS IN APPLIED EARTH OBSERVATIONS AND REMOTE SENSING, 2024, 17 : 11419 - 11433
  • [32] Key factors influencing wheat grain zinc and manganese concentration in areas with different soil available phosphorus
    Liu, Chenrui
    Wang, Haolin
    Ma, Yue
    Guan, Peiyi
    Sun, Qing
    Wang, Ziming
    Wang, Zilin
    Wang, Zhaohui
    Shi, Mei
    [J]. FIELD CROPS RESEARCH, 2024, 317
  • [33] Seed priming with zinc sulfate and zinc chloride affects physio-biochemical traits, grain yield and biofortification of bread wheat (Triticum aestivum)
    Rehman, Abdul
    Farooq, Muhammad
    Ullah, Aman
    Nawaz, Ahmad
    Din, Muhammad Moeen ud
    Shahzad, Babar
    [J]. CROP & PASTURE SCIENCE, 2022, 73 (05) : 449 - 460
  • [34] Agronomic and genetic assessment of organic wheat performance in England: a field-scale cultivar evaluation with a network of farms
    Ambrogio Costanzo
    Dominic Amos
    Charlotte Bickler
    Andrew Trump
    [J]. Agronomy for Sustainable Development, 2021, 41
  • [35] Biofortification of wheat (Triticum aestivum L.) genotypes with zinc and manganese lead to improve the grain yield and quality in sandy loam soil
    Dhaliwal, Salwinder Singh
    Sharma, Vivek
    Shukla, Arvind Kumar
    Behera, Sanjib Kumar
    Verma, Vibha
    Kaur, Manmeet
    Singh, Prabhjot
    Alamri, Saud
    Skalicky, Milan
    Hossain, Akbar
    [J]. FRONTIERS IN SUSTAINABLE FOOD SYSTEMS, 2023, 7
  • [36] Grain yield, zinc efficiency and zinc concentration of wheat cultivars grown in a zinc-deficient calcareous soil in field and greenhouse
    Kalayci, M
    Torun, B
    Eker, S
    Aydin, M
    Ozturk, L
    Cakmak, I
    [J]. FIELD CROPS RESEARCH, 1999, 63 (01) : 87 - 98
  • [37] Inhibition of arsenic transport from soil to rice grain with a sustained field-scale aerobic rice cultural practice
    Majumder, Supriya
    Banik, Pabitra
    [J]. JOURNAL OF ENVIRONMENTAL MANAGEMENT, 2021, 279
  • [38] Evolution of Industrial Quality Parameters of Wheat during Storage in White and Colored Silo Bags: A Field-Scale Study
    Bartosik, Ricardo Enrique
    Cardoso, Marcelo Leandro
    Carpaneto, Barbara Bettina
    Astiz, Valentina
    Molfese, Elena Rosa
    de la Torre, Diego Antonio
    [J]. AGRICULTURE-BASEL, 2024, 14 (06):
  • [39] Prediction of Field-Scale Wheat Yield Using Machine Learning Method and Multi-Spectral UAV Data
    Bian, Chaofa
    Shi, Hongtao
    Wu, Suqin
    Zhang, Kefei
    Wei, Meng
    Zhao, Yindi
    Sun, Yaqin
    Zhuang, Huifu
    Zhang, Xuewei
    Chen, Shuo
    [J]. REMOTE SENSING, 2022, 14 (06)
  • [40] Development and testing of a risk indexing framework to determine field-scale critical source areas of faecal bacteria on grassland
    Oliver, David M.
    Page, Trevor
    Hodgson, Chris J.
    Heathwaite, A. Louise
    Chadwick, Dave R.
    Fish, Rob D.
    Winter, Michael
    [J]. ENVIRONMENTAL MODELLING & SOFTWARE, 2010, 25 (04) : 503 - 512
12345