Relationships of frequencies of extreme low temperatures with grain yield of some Australian commercial chickpea cultivars

Chauhan, Y. S.; Allard, Sam; Krosch, Steve; Ryan, Merrill; Rachaputi, Rao C. N.

doi:10.1007/s00484-022-02344-9

Cited by 2 publications

(1 citation statement)

References 43 publications

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“…Derived variables include daily mean temperature, as average of maximum and minimum; thermal amplitude, the difference between maximum and minimum temperature; the photothermal quotient, the ratio of solar radiation and mean temperature (Fischer, 1985); rainy days (rainfall ≥ 0.5 mm); days with frosts (Tmin ≤ 0 °C); and days with chilling (mean temperature ≤ 15 °C) or high temperatures (Tmax ≥ 35 °C). The threshold for chilling temperature is from Chauhan et al (2022) and the threshold for high temperature is from Devasirvatham et al (2012). Daylength, including civil twilights, was computed from sunrise and sunset timetables from the Astronomical Applications Department of the U.S.…”

Section: Weathermentioning

confidence: 99%

Linking phenology, harvest index and genetics to improve chickpea grain yield

Gimenez,

Lake,

Cossani

et al. 2024

Preprint

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Phenology is critical to crop adaptation. We grew 24 chickpea genotypes in 12 environments to analyse: the environmental and genotypic drivers of phenology; associations between phenology and yield; and phenotypes associated with allelic variants of three flowering related candidate loci: CaELF3a; a cluster of three FT genes on chromosome 3; and a region on chromosome 4 with an orthologue of the floral promoter GIGANTEA. A simple model with 3 genotype-specific parameters explained the differences in flowering response to daylength. Environmental factors causing flower abortion, such as low temperature and radiation and high humidity, led to a longer flowering-to-podding interval. Late podding associated with poor partition to grain, limiting yield in favourable environments. Sonali, carrying the early allele of Caelf3a (elf3a), was generally the earliest to set pod, had low biomass but the highest harvest index. Genotypes combining the early variants of GIGANTEA and FT orthologues FTdel, where a deletion in the intergenic region of FTa1-FTa2 was associated with slow development, usually featured early reproduction and high harvest index, returning high yield in favourable environments. We emphasise the importance of pod set, rather than flowering, as a target for breeding, agronomic, and modelling applications.

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Section: Weathermentioning

confidence: 99%

Linking phenology, harvest index and genetics to improve chickpea grain yield

Gimenez,

Lake,

Cossani

et al. 2024

Preprint

View full text Add to dashboard Cite

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Effect of soil water on flowering and pod-set in chickpea: implications for modelling and managing frost and heat stress

Chauhan¹,

Anwar²,

Richards³

et al. 2023

Agron. Sustain. Dev.

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Phenological development is critical for crop adaptation. Phenology models are typically driven by temperature and photoperiod, but chickpea phenology is also modulated by soil water, which is not captured in these models. This study is aimed at evaluating the hypotheses that accounting for soil water improves (i) the prediction of flowering, pod-set, and flowering-to-pod-set interval in chickpea and (ii) the computation of yield-reducing frost and heat events after flowering. To test these hypotheses, we compared three variants of the Agricultural Production System Simulator (APSIM): (i) APSIMc, which models development with no temperature threshold for pod-set; (ii) APSIMx, which sets a threshold of 15 °C for pod-set; and (iii) APSIMw, derived from APSIMc with an algorithm to moderate the developmental rate as a function of soil water, in addition to temperature and photoperiod common to all three models. Comparison of modelled and actual flowering and pod-set of a common cheque cultivar PBA BoundaryA in 54 diverse environments showed that accuracy and precision were superior for APSIMw. Because of improved prediction of flowering and pod-set timing, APSIMw improved the computation of the frequency of post-flowering frosts compared to APSIMc and APSIMx. The number of heat events was similar for all three models. We conclude that accounting for water effects on plant development can allow better matching between phenology and environment.

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Relationships of frequencies of extreme low temperatures with grain yield of some Australian commercial chickpea cultivars

Cited by 2 publications

References 43 publications

Linking phenology, harvest index and genetics to improve chickpea grain yield

Linking phenology, harvest index and genetics to improve chickpea grain yield

Effect of soil water on flowering and pod-set in chickpea: implications for modelling and managing frost and heat stress

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