Dry‐Season Greening and Water Stress in Amazonia: The Role of Modeling Leaf Phenology

Manoli, Gabriele; Ivanov, V. Y.; Fatichi, Simone

doi:10.1029/2017jg004282

Cited by 45 publications

(51 citation statements)

References 104 publications

(215 reference statements)

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“…Numerical simulations were carried using the ecosystem model T&C (Fatichi et al, , , ; Fatichi & Pappas, ; Mastrotheodoros et al, ; Manoli et al, ; Paschalis et al, , ; Pappas et al, ) combined with new modules simulating soil biogeochemistry and plant nutrient dynamics (T&C‐BG) described in the following and extensively in the supporting information: Figure S1, Texts S1 and S2, and additional references in the supporting information (Ainsworth & Long, ; Batterman et al, ; Chapin et al, ; Curry & Schmidt, ; Daly et al, ; Daly & Porporato, ; Ebrahimi & Or, ; Friend et al, ; Farquhar et al, ; Hassink & Whitmore, ; Hanson et al, ; Jackson et al, ; Jungk, ; Kögel‐Knabner, ; Moorhead & Sinsabaugh, ; Moyano et al, ; Manzoni et al, , , ; Manzoni & Porporato, ; Manzoni, ; Poorter, ; Poorter & Villar, ; Phillips et al, ; Roumet et al, ; Sparks & Carski, ; Stewart et al, ; Smith & Read, ; Smith & Smith, ; Sinsabaugh et al, , ; Thomas & Stoddart, ; Thomas & Martin, ; Yang et al, ; Zhang et al, ). The original T&C is a mechanistic model simulating energy, water, and CO 2 exchanges at the land surface at an hourly time step.…”

Section: Methodsmentioning

confidence: 99%

“…As usual in T&C applications (Fatichi et al, ; Fatichi & Pappas, ; Mastrotheodoros et al, ), biomes were not parameterized with generic plant functional types, but for each site a parameter set able to provide satisfactory results in terms of vegetation productivity, leaf area index, soil moisture, energy and water fluxes, and local phenology was identified acting on the most sensitive parameters. The capability of the original T&C model to reproduce the observed energy and water fluxes and vegetation phenology as well as response to environmental manipulations against observations has been published before for a large number of location worldwide, and the 20 selected sites are a subset of those (e.g., Fatichi & Leuzinger, ; Fatichi & Ivanov, ; Fatichi et al, , ; Fatichi & Pappas, ; Mastrotheodoros et al, ; Manoli et al, ; Pappas et al, ). A single parameter set for the soil biogeochemistry module was selected based on literature parameters and preliminary model tests and is fully documented in the supporting information.…”

Section: Methodsmentioning

confidence: 99%

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A Mechanistic Model of Microbially Mediated Soil Biogeochemical Processes: A Reality Check

Fatichi

Manzoni

et al. 2019

Global Biogeochemical Cycles

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Present gaps in the representation of key soil biogeochemical processes such as the partitioning of soil organic carbon among functional components, microbial biomass and diversity, and the coupling of carbon and nutrient cycles present a challenge to improving the reliability of projected soil carbon dynamics. We introduce a new soil biogeochemistry module linked with a well‐tested terrestrial biosphere model T&C. The module explicitly distinguishes functional soil organic carbon components. Extracellular enzymes and microbial pools are differentiated based on the functional roles of bacteria, saprotrophic, and mycorrhizal fungi. Soil macrofauna is also represented. The model resolves the cycles of nitrogen, phosphorus, and potassium. Model simulations for 20 sites compared favorably with global patterns of litter and soil stoichiometry, microbial and macrofaunal biomass relations with soil organic carbon, soil respiration, and nutrient mineralization rates. Long‐term responses to bare fallow and nitrogen addition experiments were also in agreement with observations. Some discrepancies between predictions and observations are appreciable in the response to litter manipulation. Upon successful model reproduction of observed general trends, we assessed patterns associated with the carbon cycle that were challenging to address empirically. Despite large site‐to‐site variability, fine root, fungal, bacteria, and macrofaunal respiration account for 33%, 40%, 24%, and 3% on average of total belowground respiration, respectively. Simulated root exudation and carbon export to mycorrhizal fungi represent on average about 13% of plant net primary productivity. These results offer mechanistic and general estimates of microbial biomass and its contribution to respiration fluxes and to soil organic matter dynamics.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

A Mechanistic Model of Microbially Mediated Soil Biogeochemical Processes: A Reality Check

Fatichi

Manzoni

et al. 2019

Global Biogeochemical Cycles

Self Cite

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“…We used the mechanistic ecohydrological model T&C (Fatichi, Ivanov, & Caporali, ; Fatichi & Leuzinger, ; Fatichi & Pappas, ; Manoli, Ivanov, & Fatichi, ; Pappas, Fatichi, & Burlando, ), which simulates the principal processes of the hydrological cycle, such as precipitation interception, transpiration, ground evaporation, infiltration, and surface/subsurface water fluxes, including the lateral transfer of water. It further simulates plant‐related processes, such as photosynthesis, phenology, carbon allocation, and tissue turnover.…”

Section: Methodsmentioning

confidence: 99%

Ecohydrological dynamics in the Alps: Insights from a modelling analysis of the spatial variability

et al. 2018

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Mountain ecosystems are experiencing rapid warming resulting in ecological changes worldwide. Projecting the response of these ecosystems to climate change is thus crucial, but also uncertain due to complex interactions between topography, climate, and vegetation. Here, we performed numerical simulations in a real and a synthetic spatial domain covering a range of contrasting climatic conditions and vegetation characteristics representative of the European Alps. Simulations were run with the mechanistic ecohydrological model Tethys–Chloris to quantify the drivers of ecosystem functioning and to explore the vulnerability of Alpine ecosystems to climate change. We correlated the spatial distribution of ecohydrological responses with that of meteorological and topographic attributes and computed spatially explicit sensitivities of net primary productivity, transpiration, and snow cover to air temperature, radiation, and water availability. We also quantified how the variance in several ecohydrological processes, such as transpiration, quickly diminishes with increasing spatial aggregation, which highlights the importance of fine spatial resolution for resolving patterns in complex topographies. We conducted controlled numerical experiments in the synthetic domain to disentangle the effect of catchment orientation on ecohydrological variables, such as streamflow. Our results support previous studies reporting an altitude threshold below which Alpine ecosystems are water‐limited in the drier inner‐Alpine valleys and confirm that the wetter areas are temperature‐limited. High‐resolution simulations of mountainous areas can improve our understanding of ecosystem functioning across spatial scales. They can also locate the areas that are the most vulnerable to climate change and guide future measurement campaigns.

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“…In these cases, time of year or “season” serves as a proxy for leaf age, which may work well for some PFTs, but not for tropical evergreen broadleaf forests where the “evergreen” canopy belies cyclic leaf turnover that the PFT rule set does not include. This case study suggests that accounting for cryptic phenology is necessary for correctly detecting, attributing, and modeling the carbon exchange dynamics of tropical forests (De Weirdt et al, ; Kim et al, ; Manoli, Ivanov, & Fatichi, ; Restrepo‐Coupe et al, ).…”

Section: Case Studies In Cryptic Phenologymentioning

confidence: 99%

Cryptic phenology in plants: Case studies, implications, and recommendations

Albert

Restrepo-Coupé

Smith

et al. 2019

Global Change Biology

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Plant phenology—the timing of cyclic or recurrent biological events in plants—offers insight into the ecology, evolution, and seasonality of plant‐mediated ecosystem processes. Traditionally studied phenologies are readily apparent, such as flowering events, germination timing, and season‐initiating budbreak. However, a broad range of phenologies that are fundamental to the ecology and evolution of plants, and to global biogeochemical cycles and climate change predictions, have been neglected because they are “cryptic”—that is, hidden from view (e.g., root production) or difficult to distinguish and interpret based on common measurements at typical scales of examination (e.g., leaf turnover in evergreen forests). We illustrate how capturing cryptic phenology can advance scientific understanding with two case studies: wood phenology in a deciduous forest of the northeastern USA and leaf phenology in tropical evergreen forests of Amazonia. Drawing on these case studies and other literature, we argue that conceptualizing and characterizing cryptic plant phenology is needed for understanding and accurate prediction at many scales from organisms to ecosystems. We recommend avenues of empirical and modeling research to accelerate discovery of cryptic phenological patterns, to understand their causes and consequences, and to represent these processes in terrestrial biosphere models.

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Dry‐Season Greening and Water Stress in Amazonia: The Role of Modeling Leaf Phenology

Cited by 45 publications

References 104 publications

A Mechanistic Model of Microbially Mediated Soil Biogeochemical Processes: A Reality Check

A Mechanistic Model of Microbially Mediated Soil Biogeochemical Processes: A Reality Check

Ecohydrological dynamics in the Alps: Insights from a modelling analysis of the spatial variability

Cryptic phenology in plants: Case studies, implications, and recommendations

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