Monitoring nature's calendar from space: Emerging topics in land surface phenology and associated opportunities for science applications

Ma, Xuanlong; Zhu, Xiaolin; Xie, Qiaoyun; Jin, Jiaxin; Zhou, Yuke; Luo, Yunpeng; Liu, Yuxia; Tian, Jiaqi; Zhao, Yuhe

doi:10.1111/gcb.16436

Cited by 24 publications

(13 citation statements)

References 233 publications

(323 reference statements)

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“…The visible colour change often reflects the stochastic occurrence of a first frosty night and hence, leads to an overestimation of the significance attributed to colour change (Keskitalo et al, 2005; Körner & Basler, 2010; Tang et al, 2016), with key developmental processes completed quite a while before. Delayed autumnal leaf colouration has often been assumed to add to seasonal productivity (e.g., Ma et al, 2022; Piao et al, 2008; Yang et al, 2017), while the signals obtained from either eddy‐covariance flux towers or models using remote sensing data reflect ongoing CO 2 exchange by green foliage only (e.g., Keenan et al, 2014), such data cannot be used to infer annual (lasting) C sequestration, a rather popular inference.…”

Section: The Active Season Based On Growth or Developmentmentioning

confidence: 99%

Four ways to define the growing season

2023

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What is addressed as growing season in terrestrial ecosystems is one of the main determinants of annual plant biomass production globally. However, there is no well‐defined concept behind. Here, we show different facets of what might be termed growing season, each with a distinct meaning: (1) the time period during which a plant or a part of it actually grows and produces new tissue, irrespective of net carbon gain (growing season sensu stricto). (2) The period defined by developmental, that is, phenological markers (phenological season). (3) The period during which vegetation as a whole achieves its annual net primary production (NPP) or a net ecosystem production (NEP), expressed as net carbon gain (productive season) and (4) the period during which plants could potentially grow based on meteorological criteria (meteorological season). We hypothesize that the duration of such a ‘window of opportunity’ is a strong predictor for NPP at a global scale, especially for forests. These different definitions have implications for the understanding and modelling of plant growth and biomass production. The common view that variation in phenology is a proxy for variation in productivity is misleading, often resulting in unfounded statements on potential consequences of climatic warming such as carbon sequestration.

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Section: The Active Season Based On Growth or Developmentmentioning

confidence: 99%

Four ways to define the growing season

2023

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“…To our best knowledge, this is the first study focused on the spring phenology over the Pan-Third Pole, and provided satellite-based evidence about how spring phenology changes and their controls, especially during the warming hiatus. Although we detect generally consistent significant advancing trends in spring phenology based on both NDVI3g and NDVIm datasets, there are still large uncertainties in the magnitude and/or sign of trends between different products ( Peng et al., 2017 ; Moon et al., 2021 ; Ma et al., 2022 ). These inconsistencies could stem from the following factors: biological meaning (leaf emergence or plant photosynthesis), extraction methods ( Cong et al., 2012 ), spatial and temporal resolution (different levels of mixed pixel effect, and different observation frequency) ( Zhang et al., 2003 ; Zhang et al., 2009 ; Melaas et al., 2013 ; Shen et al., 2014 ; Tian et al., 2020 ; Tian et al., 2021 ), the BRDF effect (solar illumination angle and satellite view angle) ( Morton et al., 2014 ; Ma et al., 2019 ; Petri and Galvao, 2019 ; Ma et al., 2020 ; Norris and Walker, 2020 ; Lu et al., 2022 ), and effects due to atmospheric (aerosols, clouds, and hazes) ( Chen et al., 2004 ; Cai et al., 2017 ) or snow ( Wang et al., 2013 ).…”

Section: Discussionmentioning

confidence: 60%

Continued spring phenological advance under global warming hiatus over the Pan-Third Pole

Yan

Xu²,

Wang³

et al. 2022

Front. Plant Sci.

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The global surface temperature has witnessed a warming hiatus in the first decade of this century, but how this slowing down of warming will impact spring phenology over Pan-Third Pole remains unclear. Here, we combined multiple satellite-derived vegetation indices with eddy covariance datasets to evaluate the spatiotemporal changes in spring phenological changes over the Pan-Third Pole. We found that the spring phenology over Pan-Third Pole continues to advance at the rate of 4.8 days decade-1 during the warming hiatus period, which is contrasted to a non-significant change over the northern hemisphere. Such a significant and continued advance in spring phenology was mainly attributed to an increase in preseason minimum temperature and water availability. Moreover, there is an overall increasing importance of precipitation on changes in spring phenology during the last four decades. We further demonstrated that this increasingly negative correlation was also found across more than two-thirds of the dryland region, tentatively suggesting that spring phenological changes might shift from temperature to precipitation-controlled over the Pan-Third Pole in a warmer world.

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“…We thus see little reason to expect the variation here is anomalous: multi‐year behavioral studies at specific times of year often exhibit little interannual variation (Cusack et al, 2020). Seasonality is globally widespread, there is increased recognition that it is better defined by biologically relevant measures (e.g., land‐surface phenology) than with strict ordinal dates, and quantifying variation in the duration and timing of seasonal indicators plays a critical role in understanding the impacts of broader global change (Ma et al, 2022). We pose that many landscapes of fear exhibit a broadly predictable phenology related to the timing of precipitation, snow, vegetation growth, and other dynamic environmental attributes, and that these phenologies of fear may themselves be sensitive to global change.…”

Section: Discussionmentioning

confidence: 99%

A phenology of fear: Investigating scale and seasonality in predator–prey games between wolves and white‐tailed deer

Clare

Zuckerberg

Liu

et al. 2023

Ecology

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Predators and prey engage in games where each player must counter the moves of the other, and these games include multiple phases operating at different spatiotemporal scales. Recent work has highlighted potential issues related to scale‐sensitive inferences in predator–prey interactions, and there is growing appreciation that these may exhibit pronounced but predictable dynamics. Motivated by previous assertions about effects arising from foraging games between white‐tailed deer and canid predators (coyotes and wolves), we used a large and year‐round network of trail cameras to characterize deer and predator foraging games, with a particular focus on clarifying its temporal scale and seasonal variation. Linear features were strongly associated with predator detection rates, suggesting these play a central role in canid foraging tactics by expediting movement. Consistent with expectations for prey contending with highly mobile predators, deer responses were more sensitive to proximal risk metrics at finer spatiotemporal scales, suggesting that coarser but more commonly used scales of analysis may miss useful insights into prey risk‐response. Time allocation appears to be a key tactic for deer risk management and was more strongly moderated by factors associated with forage or evasion heterogeneity (forest cover, snow and plant phenology) than factors associated with the likelihood of predator encounter (linear features). Trade‐offs between food and safety appeared to vary as much seasonally as spatially, with snow and vegetation phenology giving rise to a “phenology of fear.” Deer appear free to counter predators during milder times of year, but a combination of poor foraging state, reduced forage availability, greater movements costs, and reproductive state dampen responsiveness during winter. Pronounced intra‐annual variation in predator–prey interactions may be common in seasonal environments.

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Monitoring nature's calendar from space: Emerging topics in land surface phenology and associated opportunities for science applications

Cited by 24 publications

References 233 publications

Four ways to define the growing season

Four ways to define the growing season

Continued spring phenological advance under global warming hiatus over the Pan-Third Pole

A phenology of fear: Investigating scale and seasonality in predator–prey games between wolves and white‐tailed deer

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