Water use dynamics of dryland wheat grown under elevated CO₂ with supplemental nitrogen

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dc.contributor.authorUddin, S.
dc.contributor.authorParvin, S.
dc.contributor.authorArmstrong, R.
dc.contributor.authorFitzgerald, G.J.
dc.contributor.authorLöw, M.
dc.contributor.authorHoushmandfar, A.
dc.contributor.authorTavakkoli, E.
dc.contributor.authorTausz-Posch, S.
dc.contributor.authorO'Leary, G.J.
dc.contributor.authorTausz, M.
dc.contributor.editorFukai, S.
dc.date.issued2024
dc.descriptionPublished: 14 August 2023
dc.description.abstractContext. Elevated atmospheric CO2 (e[CO2]) and nitrogen (N) fertilisation stimulate biomass and yield of crops. However, their interactions depend on crop growth stages and may affect water use dynamics. Aims and methods. This study investigated the interactive effects of two N rates, 0 and 100 kg N ha−1 , and two CO2 concentrations, ambient (a[CO2], ~400 μmol mol−1 ) and e[CO2] (~550 μmol mol−1 ), on biomass, yield and water use of two wheat cultivars, Wyalkatchem (N-use efficient) and Yitpi (local), using a free air CO2 enrichment facility. Key results. Elevated [CO2] stimulated leaf area (10%, P = 0.003) and aboveground biomass (11%, P = 0.03). In addition, e[CO2] reduced stomatal conductance (25%, P < 0.001) and increased net assimilation rates (12%, P < 0.001), resulting in greater (40%, P < 0.001) intrinsic water use efficiency. During early growth stages, e[CO2]resulted in higher water use than a[CO2]; however, this difference disappeared laterin the season, resulting in similar cumulative water use under both CO2 concentrations. Supplemental N stimulated grain yield of Yitpi by 14% while decreasing that of Wyalkatchem by 7% (N × cultivar, P = 0.063). With supplemental N, Yitpi maintained greater post-anthesis leaf N, chlorophyll content, canopy cover and net assimilation rate than Wyalkatchem. Conclusions. During early growth stages, the e[CO2]-induced stimulation of leaf-level water use efficiency was offset by greater biomass, resulting in higher water use. By the end of the season, similar cumulative water use under both CO2 concentrations indicates the dominating effect of the prevailing seasonal conditions in the study area. Observed yield responses of the studied cultivarsto supplemental N were associated with their ability to maintain post-anthesis photosynthetic capabilities. Implications. Our findings suggest that N-use efficiency traits and responsiveness need to be considered independently to optimise benefits from the ‘CO2 fertilisation effect’ through breeding.
dc.description.statementofresponsibilityShihab Uddin, Shahnaj Parvin, Roger Armstrong, Glenn J. Fitzgerald, Markus Löw, Alireza Houshmandfar, Ehsan Tavakkoli, Sabine Tausz-Posch, Garry J. O'Leary and Michael Tausz
dc.identifier.citationCrop and Pasture Science, 2024; 75(1):CP22344-1-CP22344-17
dc.identifier.doi10.1071/CP22344
dc.identifier.issn1836-0947
dc.identifier.issn1836-5795
dc.identifier.orcidTavakkoli, E. [0000-0002-2676-6018]
dc.identifier.urihttps://hdl.handle.net/2440/139489
dc.language.isoen
dc.publisherCSIRO Publishing
dc.relation.grantARC
dc.rights© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons AttributionNonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND).
dc.source.urihttps://doi.org/10.1071/cp22344
dc.subjectAGFACE; climate change; dryland agriculture; FACE; leaf gas exchange; N-use efficiency; root length; water use
dc.titleWater use dynamics of dryland wheat grown under elevated CO₂ with supplemental nitrogen
dc.title.alternativeWater use dynamics of dryland wheat grown under elevated CO2 with supplemental nitrogen
dc.typeJournal article
pubs.publication-statusPublished

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