水分胁迫下玉米的建筑模型

C. Birch, D. Thornby, S. Adkins, B. Andrieu, J. Hanan
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引用次数: 9

摘要

2003-04年度,在澳大利亚加顿进行了两项使用玉米(Pioneer 31H50)和三种灌溉制度的田间试验[(i)在整个作物周期内灌溉直到开花,(ii)完全不灌溉(试验1)和(iii)在整个作物周期内完全灌溉和雨养(试验2)]。每隔1 ~ 3天收集一次作物个体发育、叶片、叶鞘、节间长度和叶宽以及衰老的数据。2003年的一项温室试验量化了叶片形状和叶片呈现对不同水分胁迫水平的响应。利用试验1的数据对玉米(ADEL-Maize)结构模型进行修改和参数化,以纳入水分胁迫对玉米冠层特征的影响。修正模型对试验1的最终叶面积和株高拟合值较为准确,但发育过程中叶面积的拟合值低于观测值。作物生长期拟合得相当好,并能准确预测充分灌溉和雨养作物之间的差异。玉米作物冠层的最终表现是真实的。对低叶面积值提供了可能的解释。在使用实验2的数据和其他独立数据进行验证之前,该模型需要使用来自温室研究的数据进一步发展。然后,它将用于扩展玉米体系结构模型中的功能。随着进一步的研究和开发,该模型将特别有助于研究玉米生产对水分胁迫的响应,包括改进对总生物量和粮食产量的预测。这将有助于改进植物生长和发育过程的模拟,允许在次优供水条件下通过环境相互作用研究基因型。
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Architectural modelling of maize under water stress
Two field experiments using maize (Pioneer 31H50) and three watering regimes [(i) irrigated for the whole crop cycle, until anthesis, (ii) not at all (experiment 1) and (iii) fully irrigated and rain grown for the whole crop cycle (experiment 2)] were conducted at Gatton, Australia, during the 2003–04 season. Data on crop ontogeny, leaf, sheath and internode lengths and leaf width, and senescence were collected at 1- to 3-day intervals. A glasshouse experiment during 2003 quantified the responses of leaf shape and leaf presentation to various levels of water stress. Data from experiment 1 were used to modify and parameterise an architectural model of maize (ADEL-Maize) to incorporate the impact of water stress on maize canopy characteristics. The modified model produced accurate fitted values for experiment 1 for final leaf area and plant height, but values during development for leaf area were lower than observed data. Crop duration was reasonably well fitted and differences between the fully irrigated and rain-grown crops were accurately predicted. Final representations of maize crop canopies were realistic. Possible explanations for low values of leaf area are provided. The model requires further development using data from the glasshouse study and before being validated using data from experiment 2 and other independent data. It will then be used to extend functionality in architectural models of maize. With further research and development, the model should be particularly useful in examining the response of maize production to water stress including improved prediction of total biomass and grain yield. This will facilitate improved simulation of plant growth and development processes allowing investigation of genotype by environment interactions under conditions of suboptimal water supply.
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