Influence of photothermal quotient in the critical period on yield potential of cereals–A comparison of wheat and barley

IF 5.6 1区农林科学 Q1 AGRONOMY Field Crops Research Pub Date : 2024-11-24 DOI:10.1016/j.fcr.2024.109658

Kenton Porker , Nick Poole , Darcy Warren , Julianne Lilley , Felicity Harris , John Kirkegaard

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Abstract

Context

Research in grain crops has focused on understanding the critical period (CP) for yield formation to develop genetic and agronomic options that minimize stress or resource limitation during this time. While the link between the photothermal quotient (PTQ) in the CP and yield potential is known for wheat, it needs re-evaluation with current genetics and agronomy, and is less explored in barley, especially in high productivity areas.

Objective

Our aim was to determine if a) the PTQ-yield relationship in wheat has evolved with new cultivars and agronomic practices, and b) if barley shares similar CP timing and duration with wheat or requires species-specific adjustments in high production zones.

Methods

From trials In the Australian high production zones, we compiled a dataset (25 site-years) of high-yielding wheat and barley from carefully managed field experiments. The sites analysed had barley and wheat varying in genetics and management across different photothermal environments and where seasonal water supply exceeded 400 mm, and were not constrained by nutrients, allowing us to evaluate the sensitivity to relationship between radiation and temperature during the CP on yield potential.

Results

We created a new PTQ-based yield potential frontier for wheat and barley, measuring yield increase per PTQ unit. The best model used PTQ data from 20 days before to 10 days after flowering. In barley, changes in the CP timing and length didn't affect the results as expected. The slope of the relationship was lower for barley, indicating lower yields at higher PTQ compared to wheat, highlighting their physiological differences.

Conclusions

Our study shows Australia's wheat and barley yields, over 15 Mg ha⁻¹ in wheat and >12 Mg ha⁻¹ in barley respectively, are more influenced by PTQ during the CP than by seasonal water when water supply estimates exceed 400 mm in Australia. We present a simple, physiologically sound PTQ equation as a yield benchmark for wheat (WPYptq= 10.62PTQ-2.85) and barley (BPYptq= 6.73PTQ+1.65).

Implications

Efforts in agronomy and breeding should aim at enhancing resource availability and partitioning during the CP and aligning the CP with environmental conditions. The straightforward PTQ model for predicting yield potential in Australia's higher production areas matches complex simulations well, aiding in optimizing production systems and guiding future yield potential research.

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临界期光热商对谷物产量潜力的影响--小麦和大麦的比较

背景谷物作物研究的重点是了解产量形成的关键期（CP），以开发遗传和农艺方案，最大限度地减少这一时期的压力或资源限制。虽然小麦关键期的光热商（PTQ）与产量潜力之间的联系是已知的，但需要根据当前的遗传学和农艺学对其进行重新评估，而对大麦的研究则较少，尤其是在高产地区。我们的目的是确定：a）小麦中 PTQ 与产量的关系是否随着新的栽培品种和农艺实践而演变；b）在高产地区，大麦是否与小麦具有相似的 CP 时间和持续时间，或者是否需要进行物种特异性调整。分析地点的大麦和小麦在不同光热环境下的遗传和管理各不相同，季节性供水量超过 400 毫米，而且不受养分限制，这使我们能够评估光合作用期间辐射和温度之间的关系对产量潜力的敏感性。结果我们为小麦和大麦创建了基于 PTQ 的新产量潜力前沿，衡量每个 PTQ 单位的增产情况。最佳模型使用了开花前 20 天至开花后 10 天的 PTQ 数据。在大麦中，CP 时间和长度的变化并未如预期那样影响结果。我们的研究表明，澳大利亚的小麦和大麦产量（分别超过 1,500 万克/公顷-1 小麦和 1,200 万克/公顷-1 大麦）受 CP 期间 PTQ 的影响比受季节水的影响更大，因为澳大利亚的供水量估计超过 400 毫米。我们提出了一个简单、生理上合理的 PTQ 公式，作为小麦（WPYptq= 10.62PTQ-2.85）和大麦（BPYptq= 6.73PTQ+1.65）的产量基准。用于预测澳大利亚高产区产量潜力的简单 PTQ 模型与复杂的模拟结果十分吻合，有助于优化生产系统并指导未来的产量潜力研究。

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来源期刊

Field Crops Research 农林科学-农艺学

CiteScore

9.60

自引率

12.10%

发文量

307

审稿时长

46 days

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.

期刊最新文献

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