Climate change fingerprints in recent European plant phenology

Menzel, Annette; Yuan, Ye; Matiu, Michael; Sparks, Tim H.; Scheifinger, Helfried; Gehrig, Regula; Estrella, Nicole

doi:10.1111/gcb.15000

Cited by 233 publications

(189 citation statements)

References 60 publications

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“…Numerous methods have been utilized to elucidate the intensity of the effect of climate change on agronomic cereal crops. The methods include analysis of satellite images on vegetation greenness, measurement of net primary production with Normalized Difference Vegetation Index (NDVI), and particularly, determination of temporal and spatial variations in phenological seasonality 26,79,[110][111][112][113][114][115] . The data on stages and phases of cereal crop phenology and climate meteorological data are collected from phenological networks or through designated observation stations.…”

Section: Role Of Phenological Stages and Phases In Cereal Crop Grain mentioning

confidence: 99%

“…Thus the asymmetric and opposing response of phenology to daytime and night-time was studied by Wang et al 82 and concluded that T max and night-time T min had opposite effects on the timing of start of the season, delayed end of the season and prolonged length of growing season. Furthermore, several earlier studies documented that the intensity of the response of phenological stages and phases of agricultural crops to warming trend is variable at spatio-temporal scales 79 , 83 , 84 . Phenology is well known climate change indicator.…”

Section: Introductionmentioning

confidence: 99%

“…Crop phenology is the most significant feature of crop adaptation, and spatial and temporal changes in phenological stages and phases provide well-built indications of the biological influence of thermal trend. Change in phenological seasonality is having both direct and indirect effects on natural vegetation and cereal crop productivity 25,26,[79][80][81] . Measured climate-warming trends have been implicated as a reason for accelerated cereal crop growth rates and reduced growing durations.…”

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confidence: 99%

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The fingerprints of climate warming on cereal crops phenology and adaptation options

Fatima

Ahmed

Hussain

et al. 2020

Sci Rep

187

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Growth and development of cereal crops are linked to weather, day length and growing degree-days (GDDs) which make them responsive to the specific environments in specific seasons. Global temperature is rising due to human activities such as burning of fossil fuels and clearance of woodlands for building construction. The rise in temperature disrupts crop growth and development. Disturbance mainly causes a shift in phenological development of crops and affects their economic yield. Scientists and farmers adapt to these phenological shifts, in part, by changing sowing time and cultivar shifts which may increase or decrease crop growth duration. Nonetheless, climate warming is a global phenomenon and cannot be avoided. In this scenario, food security can be ensured by improving cereal production through agronomic management, breeding of climate-adapted genotypes and increasing genetic biodiversity. In this review, climate warming, its impact and consequences are discussed with reference to their influences on phenological shifts. Furthermore, how different cereal crops adapt to climate warming by regulating their phenological development is elaborated. Based on the above mentioned discussion, different management strategies to cope with climate warming are suggested.

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Section: Role Of Phenological Stages and Phases In Cereal Crop Grain mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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The fingerprints of climate warming on cereal crops phenology and adaptation options

Fatima

Ahmed

Hussain

et al. 2020

Sci Rep

187

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“…Additional cues associated with spring phenological events for some species include autumn temperature (Heide, 2003;Sparks et al, 2020), day length (Heide, 1993a;Heide, 1993b;Körner and Basler, 2010;Basler and Körner, 2012;Laube et al, 2014a), light quality (Brelsford and Robson, 2018), air humidity (Düring, 1979;Laube et al, 2014b;Zipf and Primack, 2017), or nutrient availability (Jochner et al, 2013a). Under natural in situ conditions it is difficult to disentangle these multiple and often co-varying environmental factors (e.g., Piao et al, 2019;Menzel et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Chilling and Forcing From Cut Twigs—How to Simplify Phenological Experiments for Citizen Science

et al. 2020

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Low-cost phenological experiments with cut twigs are increasingly used to study bud development in response to spring warming and photoperiod. However, a broader variety of species needs to be tackled and in particular the influence of insufficient winter chilling deserves more attention. Therefore, we investigated if and how chilling requirements can be efficiently investigated by cut twigs and how this low-tech approach could be successfully implemented as a citizen science or school project. We conducted an experiment on bud burst and leaf development of Corylus avellana L. twigs, with natural chilling outdoors on a shrub (S) and another chilling treatment as cut twigs in containers (C), and subsequent forcing indoors. Subsampling of the number of cutting dates and number of twigs was used to infer minimum required sample sizes. Apart from insufficiently chilled twigs,~80% of the twigs (both S and C) reached leaf out. For multiple definitions of chilling and forcing, a negative exponential relationship was revealed between chilling and amount of forcing needed to reach certain developmental stages. At least 5 out of 15 cutting dates or alternatively half of the 10 twig repetitions, but especially those mirroring low chilling conditions, were needed to describe the chillingforcing relationship with some degree of robustness. In addition, for cutting dates with long chilling, i.e., from January onwards, freshly cut twigs (S) required significantly more forcing to reach bud burst than twigs from containers (C), although the effect was small. In general, chilling conditions of mature shrubs were well captured by cut twigs, therefore opening the possibility of chilling through refrigeration. We conclude that experimental protocols as outlined here are feasible for citizen scientists, school projects, and science education, and would have the potential to advance the research field if carried out on a large scale. We provide an easy-to-use Shiny simulation app to enable citizen scientists to build up a bud development model based on their own experimental data and then simulate future phenological development with winter and/or spring warming. This may encourage them to further study other aspects of climate change and the impacts of climate change.

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“…The changes in the annual cycle of plants are closely linked to the seasonal course of temperature, light and water supply, among other factors, and phenological observations constitute direct evidence of plants’ responses to these changes. With these regards, phenological data contribute tangibly to our understanding of global change biology (Menzel 2000 , 2002 ; Parmesan and Yohe 2003 ; Piao et al 2019 ; Menzel et al 2020 ). In Europe, the plant phenological data have demonstrated an average advance of spring/summer 2.5 days per decade between the years 1971 and 2000, in accordance with instrumentally observed warming (Menzel et al 2006 ).…”

Section: Introductionmentioning

confidence: 99%

Finnish National Phenological Network 1997–2017: from observations to trend detection

et al. 2020

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Plant phenological dataset collected at 42 sites across the mainland of Finland and covering the years 1997–2017 is presented and analysed for temporal trends. The dataset of n = 16,257 observations represents eleven plant species and fifteen phenological stages and results in forty different variables, i.e. phenophases. Trend analysis was carried out for n = 808 phenological time-series that contained at least 10 observations over the 21-year study period. A clear signal of advancing spring and early-summer phenology was detected, 3.4 days decade−1, demonstrated by a high proportion of negative trends for phenophases occurring in April through June. Latitudinal correlation indicated stronger signal of spring and early-summer phenology towards the northern part of the study region. The autumn signal was less consistent and showed larger within-site variations than those observed in other seasons. More than 60% of the dates based on single tree/monitoring square were exactly the same as the averages from multiple trees/monitoring squares within the site. In particular, the reliability of data on autumn phenology was increased by multiple observations per site. The network is no longer active.

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Climate change fingerprints in recent European plant phenology

Cited by 233 publications

References 60 publications

The fingerprints of climate warming on cereal crops phenology and adaptation options

The fingerprints of climate warming on cereal crops phenology and adaptation options

Chilling and Forcing From Cut Twigs—How to Simplify Phenological Experiments for Citizen Science

Finnish National Phenological Network 1997–2017: from observations to trend detection

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