Advancing understanding of land–atmosphere interactions by breaking discipline and scale barriers

Jordi Vilà-Guerau de Arellano; Oscar Hartogensis; Imme Benedict; Hugo de Boer; Peter J.M. Bosman; Santiago Botía; Micael Amore Cecchini; Kim A.P. Faassen; Raquel González-Armas; Kevin van Diepen; Bert G. Heusinkveld; Martin Janssens; Felipe Lobos-Roco; Ingrid T. Luijkx; Luiz A.T. Machado; Mary Rose Mangan; Arnold F. Moene; Wouter B. Mol; Michiel van der Molen; Robbert Moonen; H. G. Ouwersloot; So Won Park; Xabier Pedruzo-Bagazgoitia; Thomas Röckmann; Getachew Agmuas Adnew; Reinder Ronda; Martin Sikma; Ruben Schulte; Bart J.H. van Stratum; Menno A. Veerman; Margreet C. van Zanten; Chiel C. van Heerwaarden

doi:10.1111/nyas.14956

Advancing understanding of land–atmosphere interactions by breaking discipline and scale barriers

Jordi Vilà-Guerau de Arellano^*, Oscar Hartogensis, Imme Benedict, Hugo de Boer, Peter J.M. Bosman, Santiago Botía, Micael Amore Cecchini, Kim A.P. Faassen, Raquel González-Armas, Kevin van Diepen, Bert G. Heusinkveld, Martin Janssens, Felipe Lobos-Roco, Ingrid T. Luijkx, Luiz A.T. Machado, Mary Rose Mangan, Arnold F. Moene, Wouter B. Mol, Michiel van der Molen, Robbert MoonenH. G. Ouwersloot, So Won Park, Xabier Pedruzo-Bagazgoitia, Thomas Röckmann, Getachew Agmuas Adnew, Reinder Ronda, Martin Sikma, Ruben Schulte, Bart J.H. van Stratum, Menno A. Veerman, Margreet C. van Zanten, Chiel C. van Heerwaarden

^*Corresponding author af dette arbejde

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

14 Citationer (Scopus)

Abstract

Vegetation and atmosphere processes are coupled through a myriad of interactions linking plant transpiration, carbon dioxide assimilation, turbulent transport of moisture, heat and atmospheric constituents, aerosol formation, moist convection, and precipitation. Advances in our understanding are hampered by discipline barriers and challenges in understanding the role of small spatiotemporal scales. In this perspective, we propose to study the atmosphere–ecosystem interaction as a continuum by integrating leaf to regional scales (multiscale) and integrating biochemical and physical processes (multiprocesses). The challenges ahead are (1) How do clouds and canopies affect the transferring and in-canopy penetration of radiation, thereby impacting photosynthesis and biogenic chemical transformations? (2) How is the radiative energy spatially distributed and converted into turbulent fluxes of heat, moisture, carbon, and reactive compounds? (3) How do local (leaf-canopy-clouds, 1 m to kilometers) biochemical and physical processes interact with regional meteorology and atmospheric composition (kilometers to 100 km)? (4) How can we integrate the feedbacks between cloud radiative effects and plant physiology to reduce uncertainties in our climate projections driven by regional warming and enhanced carbon dioxide levels? Our methodology integrates fine-scale explicit simulations with new observational techniques to determine the role of unresolved small-scale spatiotemporal processes in weather and climate models.

Originalsprog	Engelsk
Tidsskrift	Annals of the New York Academy of Sciences
Vol/bind	1522
Udgave nummer	1
Sider (fra-til)	74-97
Antal sider	24
ISSN	0077-8923
DOI	https://doi.org/10.1111/nyas.14956
Status	Udgivet - apr. 2023
Udgivet eksternt	Ja

Bibliografisk note

Publisher Copyright:
© 2023 The Authors. Annals of the New York Academy of Sciences published by Wiley Periodicals LLC on behalf of New York Academy of Sciences.

Adgang til dokumentet

10.1111/nyas.14956

Citationsformater

Vilà-Guerau de Arellano, J., Hartogensis, O., Benedict, I., de Boer, H., Bosman, P. J. M., Botía, S., Cecchini, M. A., Faassen, K. A. P., González-Armas, R., van Diepen, K., Heusinkveld, B. G., Janssens, M., Lobos-Roco, F., Luijkx, I. T., Machado, L. A. T., Mangan, M. R., Moene, A. F., Mol, W. B., van der Molen, M., ... van Heerwaarden, C. C. (2023). Advancing understanding of land–atmosphere interactions by breaking discipline and scale barriers. Annals of the New York Academy of Sciences, 1522(1), 74-97. https://doi.org/10.1111/nyas.14956

Vilà-Guerau de Arellano, J, Hartogensis, O, Benedict, I, de Boer, H, Bosman, PJM, Botía, S, Cecchini, MA, Faassen, KAP, González-Armas, R, van Diepen, K, Heusinkveld, BG, Janssens, M, Lobos-Roco, F, Luijkx, IT, Machado, LAT, Mangan, MR, Moene, AF, Mol, WB, van der Molen, M, Moonen, R, Ouwersloot, HG, Park, SW, Pedruzo-Bagazgoitia, X, Röckmann, T, Adnew, GA, Ronda, R, Sikma, M, Schulte, R, van Stratum, BJH, Veerman, MA, van Zanten, MC & van Heerwaarden, CC 2023, 'Advancing understanding of land–atmosphere interactions by breaking discipline and scale barriers', Annals of the New York Academy of Sciences, bind 1522, nr. 1, s. 74-97. https://doi.org/10.1111/nyas.14956

@article{b06faf794ad64c279521147a04763094,

title = "Advancing understanding of land–atmosphere interactions by breaking discipline and scale barriers",

abstract = "Vegetation and atmosphere processes are coupled through a myriad of interactions linking plant transpiration, carbon dioxide assimilation, turbulent transport of moisture, heat and atmospheric constituents, aerosol formation, moist convection, and precipitation. Advances in our understanding are hampered by discipline barriers and challenges in understanding the role of small spatiotemporal scales. In this perspective, we propose to study the atmosphere–ecosystem interaction as a continuum by integrating leaf to regional scales (multiscale) and integrating biochemical and physical processes (multiprocesses). The challenges ahead are (1) How do clouds and canopies affect the transferring and in-canopy penetration of radiation, thereby impacting photosynthesis and biogenic chemical transformations? (2) How is the radiative energy spatially distributed and converted into turbulent fluxes of heat, moisture, carbon, and reactive compounds? (3) How do local (leaf-canopy-clouds, 1 m to kilometers) biochemical and physical processes interact with regional meteorology and atmospheric composition (kilometers to 100 km)? (4) How can we integrate the feedbacks between cloud radiative effects and plant physiology to reduce uncertainties in our climate projections driven by regional warming and enhanced carbon dioxide levels? Our methodology integrates fine-scale explicit simulations with new observational techniques to determine the role of unresolved small-scale spatiotemporal processes in weather and climate models.",

keywords = "clouds, land–atmosphere interactions, leaf to regional, photosynthesis",

author = "{Vil{\`a}-Guerau de Arellano}, Jordi and Oscar Hartogensis and Imme Benedict and {de Boer}, Hugo and Bosman, {Peter J.M.} and Santiago Bot{\'i}a and Cecchini, {Micael Amore} and Faassen, {Kim A.P.} and Raquel Gonz{\'a}lez-Armas and {van Diepen}, Kevin and Heusinkveld, {Bert G.} and Martin Janssens and Felipe Lobos-Roco and Luijkx, {Ingrid T.} and Machado, {Luiz A.T.} and Mangan, {Mary Rose} and Moene, {Arnold F.} and Mol, {Wouter B.} and {van der Molen}, Michiel and Robbert Moonen and Ouwersloot, {H. G.} and Park, {So Won} and Xabier Pedruzo-Bagazgoitia and Thomas R{\"o}ckmann and Adnew, {Getachew Agmuas} and Reinder Ronda and Martin Sikma and Ruben Schulte and {van Stratum}, {Bart J.H.} and Veerman, {Menno A.} and {van Zanten}, {Margreet C.} and {van Heerwaarden}, {Chiel C.}",

note = "Funding Information: The following grants are acknowledged in providing observations and model calculations used in some figures of the paper: project Cloud-Roots - Clouds rooted in a heterogeneous biosphere (https://cloudroots. wur.nl/) (Dutch Research Council NWO OCENW.KLEIN.407), computer calculation time provided by the Dutch Research Council 2021/ENW/01081379, and Ruisdael scientific research infrastructure (https://ruisdael-observatory.nl/) co-financed by the Dutch Research Council (NWO, Grant number 184.034.015). Numerical simulations (Figures 9, 12, and 14) were supported by a NWO-Supercomputer Grant (15744). The contributions of H. J. de Boer were funded through the generosity of Eric and Wendy Schmidt by recommendation of the Schmidt Futures program. We acknowledge the World Climate Research Programme{\textquoteright}s Working Group on Coupled Modeling, which is responsible for CMIP, the climate modeling groups for producing and making their model output, and the Earth System Grid Federation for archiving the data and providing access. Funding Information: The following grants are acknowledged in providing observations and model calculations used in some figures of the paper: project CloudRoots - Clouds rooted in a heterogeneous biosphere (https://cloudroots.wur.nl/) (Dutch Research Council NWO OCENW.KLEIN.407), computer calculation time provided by the Dutch Research Council 2021/ENW/01081379, and Ruisdael scientific research infrastructure (https://ruisdael-observatory.nl/) co-financed by the Dutch Research Council (NWO, Grant number 184.034.015). Numerical simulations (Figures 9, 12, and 14) were supported by a NWO-Supercomputer Grant (15744). The contributions of H. J. de Boer were funded through the generosity of Eric and Wendy Schmidt by recommendation of the Schmidt Futures program. We acknowledge the World Climate Research Programme's Working Group on Coupled Modeling, which is responsible for CMIP, the climate modeling groups for producing and making their model output, and the Earth System Grid Federation for archiving the data and providing access. Publisher Copyright: {\textcopyright} 2023 The Authors. Annals of the New York Academy of Sciences published by Wiley Periodicals LLC on behalf of New York Academy of Sciences.",

year = "2023",

month = apr,

doi = "10.1111/nyas.14956",

language = "English",

volume = "1522",

pages = "74--97",

journal = "Annals of the New York Academy of Sciences",

issn = "0077-8923",

publisher = "Wiley-Blackwell",

number = "1",

}

TY - JOUR

T1 - Advancing understanding of land–atmosphere interactions by breaking discipline and scale barriers

AU - Vilà-Guerau de Arellano, Jordi

AU - Hartogensis, Oscar

AU - Benedict, Imme

AU - de Boer, Hugo

AU - Bosman, Peter J.M.

AU - Botía, Santiago

AU - Cecchini, Micael Amore

AU - Faassen, Kim A.P.

AU - González-Armas, Raquel

AU - van Diepen, Kevin

AU - Heusinkveld, Bert G.

AU - Janssens, Martin

AU - Lobos-Roco, Felipe

AU - Luijkx, Ingrid T.

AU - Machado, Luiz A.T.

AU - Mangan, Mary Rose

AU - Moene, Arnold F.

AU - Mol, Wouter B.

AU - van der Molen, Michiel

AU - Moonen, Robbert

AU - Ouwersloot, H. G.

AU - Park, So Won

AU - Pedruzo-Bagazgoitia, Xabier

AU - Röckmann, Thomas

AU - Adnew, Getachew Agmuas

AU - Ronda, Reinder

AU - Sikma, Martin

AU - Schulte, Ruben

AU - van Stratum, Bart J.H.

AU - Veerman, Menno A.

AU - van Zanten, Margreet C.

AU - van Heerwaarden, Chiel C.

N1 - Funding Information: The following grants are acknowledged in providing observations and model calculations used in some figures of the paper: project Cloud-Roots - Clouds rooted in a heterogeneous biosphere (https://cloudroots. wur.nl/) (Dutch Research Council NWO OCENW.KLEIN.407), computer calculation time provided by the Dutch Research Council 2021/ENW/01081379, and Ruisdael scientific research infrastructure (https://ruisdael-observatory.nl/) co-financed by the Dutch Research Council (NWO, Grant number 184.034.015). Numerical simulations (Figures 9, 12, and 14) were supported by a NWO-Supercomputer Grant (15744). The contributions of H. J. de Boer were funded through the generosity of Eric and Wendy Schmidt by recommendation of the Schmidt Futures program. We acknowledge the World Climate Research Programme’s Working Group on Coupled Modeling, which is responsible for CMIP, the climate modeling groups for producing and making their model output, and the Earth System Grid Federation for archiving the data and providing access. Funding Information: The following grants are acknowledged in providing observations and model calculations used in some figures of the paper: project CloudRoots - Clouds rooted in a heterogeneous biosphere (https://cloudroots.wur.nl/) (Dutch Research Council NWO OCENW.KLEIN.407), computer calculation time provided by the Dutch Research Council 2021/ENW/01081379, and Ruisdael scientific research infrastructure (https://ruisdael-observatory.nl/) co-financed by the Dutch Research Council (NWO, Grant number 184.034.015). Numerical simulations (Figures 9, 12, and 14) were supported by a NWO-Supercomputer Grant (15744). The contributions of H. J. de Boer were funded through the generosity of Eric and Wendy Schmidt by recommendation of the Schmidt Futures program. We acknowledge the World Climate Research Programme's Working Group on Coupled Modeling, which is responsible for CMIP, the climate modeling groups for producing and making their model output, and the Earth System Grid Federation for archiving the data and providing access. Publisher Copyright: © 2023 The Authors. Annals of the New York Academy of Sciences published by Wiley Periodicals LLC on behalf of New York Academy of Sciences.

PY - 2023/4

Y1 - 2023/4

N2 - Vegetation and atmosphere processes are coupled through a myriad of interactions linking plant transpiration, carbon dioxide assimilation, turbulent transport of moisture, heat and atmospheric constituents, aerosol formation, moist convection, and precipitation. Advances in our understanding are hampered by discipline barriers and challenges in understanding the role of small spatiotemporal scales. In this perspective, we propose to study the atmosphere–ecosystem interaction as a continuum by integrating leaf to regional scales (multiscale) and integrating biochemical and physical processes (multiprocesses). The challenges ahead are (1) How do clouds and canopies affect the transferring and in-canopy penetration of radiation, thereby impacting photosynthesis and biogenic chemical transformations? (2) How is the radiative energy spatially distributed and converted into turbulent fluxes of heat, moisture, carbon, and reactive compounds? (3) How do local (leaf-canopy-clouds, 1 m to kilometers) biochemical and physical processes interact with regional meteorology and atmospheric composition (kilometers to 100 km)? (4) How can we integrate the feedbacks between cloud radiative effects and plant physiology to reduce uncertainties in our climate projections driven by regional warming and enhanced carbon dioxide levels? Our methodology integrates fine-scale explicit simulations with new observational techniques to determine the role of unresolved small-scale spatiotemporal processes in weather and climate models.

AB - Vegetation and atmosphere processes are coupled through a myriad of interactions linking plant transpiration, carbon dioxide assimilation, turbulent transport of moisture, heat and atmospheric constituents, aerosol formation, moist convection, and precipitation. Advances in our understanding are hampered by discipline barriers and challenges in understanding the role of small spatiotemporal scales. In this perspective, we propose to study the atmosphere–ecosystem interaction as a continuum by integrating leaf to regional scales (multiscale) and integrating biochemical and physical processes (multiprocesses). The challenges ahead are (1) How do clouds and canopies affect the transferring and in-canopy penetration of radiation, thereby impacting photosynthesis and biogenic chemical transformations? (2) How is the radiative energy spatially distributed and converted into turbulent fluxes of heat, moisture, carbon, and reactive compounds? (3) How do local (leaf-canopy-clouds, 1 m to kilometers) biochemical and physical processes interact with regional meteorology and atmospheric composition (kilometers to 100 km)? (4) How can we integrate the feedbacks between cloud radiative effects and plant physiology to reduce uncertainties in our climate projections driven by regional warming and enhanced carbon dioxide levels? Our methodology integrates fine-scale explicit simulations with new observational techniques to determine the role of unresolved small-scale spatiotemporal processes in weather and climate models.

KW - clouds

KW - land–atmosphere interactions

KW - leaf to regional

KW - photosynthesis

U2 - 10.1111/nyas.14956

DO - 10.1111/nyas.14956

M3 - Journal article

C2 - 36726230

AN - SCOPUS:85152174498

SN - 0077-8923

VL - 1522

SP - 74

EP - 97

JO - Annals of the New York Academy of Sciences

JF - Annals of the New York Academy of Sciences

IS - 1

ER -