Latent heat exchange in the boreal and arctic biomes

Ville Kasurinen; Knut Alfredsen; Pasi Kolari; Ivan Mammarella; Pavel Alekseychik; Janne Rinne; Timo Vesala; Pierre Bernier; Julia Boike; Moritz Langer; Luca Belelli Marchesini; Ko Van Huissteden; Han Dolman; Torsten Sachs; Takeshi Ohta; Andrej Varlagin; Adrian Rocha; Altaf Arain; Walter Oechel; Magnus Lund; Achim Grelle; Anders Lindroth; Andy Black; Mika Aurela; Tuomas Laurila; Annalea Lohila; Frank Berninger

doi:10.1111/gcb.12640

Latent heat exchange in the boreal and arctic biomes

Ville Kasurinen, Knut Alfredsen, Pasi Kolari, Ivan Mammarella, Pavel Alekseychik, Janne Rinne, Timo Vesala, Pierre Bernier, Julia Boike, Moritz Langer, Luca Belelli Marchesini, Ko Van Huissteden, Han Dolman, Torsten Sachs, Takeshi Ohta, Andrej Varlagin, Adrian Rocha, Altaf Arain, Walter Oechel, Magnus LundAchim Grelle, Anders Lindroth, Andy Black, Mika Aurela, Tuomas Laurila, Annalea Lohila, Frank Berninger

Research output: Contribution to journal › Review article › peer-review

Abstract

In this study latent heat flux (E) measurements made at 65 boreal and arctic eddy-covariance (EC) sites were analyses by using the Penman-Monteith equation. Sites were stratified into nine different ecosystem types: harvested and burnt forest areas, pine forests, spruce or fir forests, Douglas-fir forests, broadleaf deciduous forests, larch forests, wetlands, tundra and natural grasslands. The Penman-Monteith equation was calibrated with variable surface resistances against half-hourly eddy-covariance data and clear differences between ecosystem types were observed. Based on the modeled behavior of surface and aerodynamic resistances, surface resistance tightly control E in most mature forests, while it had less importance in ecosystems having shorter vegetation like young or recently harvested forests, grasslands, wetlands and tundra. The parameters of the Penman-Monteith equation were clearly different for winter and summer conditions, indicating that phenological effects on surface resistance are important. We also compared the simulated E of different ecosystem types under meteorological conditions at one site. Values of E varied between 15% and 38% of the net radiation in the simulations with mean ecosystem parameters. In general, the simulations suggest that E is higher from forested ecosystems than from grasslands, wetlands or tundra-type ecosystems. Forests showed usually a tighter stomatal control of E as indicated by a pronounced sensitivity of surface resistance to atmospheric vapor pressure deficit. Nevertheless, the surface resistance of forests was lower than for open vegetation types including wetlands. Tundra and wetlands had higher surface resistances, which were less sensitive to vapor pressure deficits. The results indicate that the variation in surface resistance within and between different vegetation types might play a significant role in energy exchange between terrestrial ecosystems and atmosphere. These results suggest the need to take into account vegetation type and phenology in energy exchange modeling.

Original language	English
Pages (from-to)	3439-3456
Journal	Global Change Biology
Volume	20
Issue number	11
DOIs	https://doi.org/10.1111/gcb.12640
Publication status	Published - 2014

Subject classification (UKÄ)

Physical Geography

Free keywords

eddy-covariance
evapotranspiration
latent heat
phenology
stomatal
resistance

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1111/gcb.12640

Cite this

Kasurinen, V., Alfredsen, K., Kolari, P., Mammarella, I., Alekseychik, P., Rinne, J., Vesala, T., Bernier, P., Boike, J., Langer, M., Marchesini, L. B., Van Huissteden, K., Dolman, H., Sachs, T., Ohta, T., Varlagin, A., Rocha, A., Arain, A., Oechel, W., ... Berninger, F. (2014). Latent heat exchange in the boreal and arctic biomes. Global Change Biology, 20(11), 3439-3456. https://doi.org/10.1111/gcb.12640

@article{ec1bf02c356b4ecb864aa7fc11048336,

title = "Latent heat exchange in the boreal and arctic biomes",

abstract = "In this study latent heat flux (E) measurements made at 65 boreal and arctic eddy-covariance (EC) sites were analyses by using the Penman-Monteith equation. Sites were stratified into nine different ecosystem types: harvested and burnt forest areas, pine forests, spruce or fir forests, Douglas-fir forests, broadleaf deciduous forests, larch forests, wetlands, tundra and natural grasslands. The Penman-Monteith equation was calibrated with variable surface resistances against half-hourly eddy-covariance data and clear differences between ecosystem types were observed. Based on the modeled behavior of surface and aerodynamic resistances, surface resistance tightly control E in most mature forests, while it had less importance in ecosystems having shorter vegetation like young or recently harvested forests, grasslands, wetlands and tundra. The parameters of the Penman-Monteith equation were clearly different for winter and summer conditions, indicating that phenological effects on surface resistance are important. We also compared the simulated E of different ecosystem types under meteorological conditions at one site. Values of E varied between 15% and 38% of the net radiation in the simulations with mean ecosystem parameters. In general, the simulations suggest that E is higher from forested ecosystems than from grasslands, wetlands or tundra-type ecosystems. Forests showed usually a tighter stomatal control of E as indicated by a pronounced sensitivity of surface resistance to atmospheric vapor pressure deficit. Nevertheless, the surface resistance of forests was lower than for open vegetation types including wetlands. Tundra and wetlands had higher surface resistances, which were less sensitive to vapor pressure deficits. The results indicate that the variation in surface resistance within and between different vegetation types might play a significant role in energy exchange between terrestrial ecosystems and atmosphere. These results suggest the need to take into account vegetation type and phenology in energy exchange modeling.",

keywords = "eddy-covariance, evapotranspiration, latent heat, phenology, stomatal, resistance",

author = "Ville Kasurinen and Knut Alfredsen and Pasi Kolari and Ivan Mammarella and Pavel Alekseychik and Janne Rinne and Timo Vesala and Pierre Bernier and Julia Boike and Moritz Langer and Marchesini, {Luca Belelli} and {Van Huissteden}, Ko and Han Dolman and Torsten Sachs and Takeshi Ohta and Andrej Varlagin and Adrian Rocha and Altaf Arain and Walter Oechel and Magnus Lund and Achim Grelle and Anders Lindroth and Andy Black and Mika Aurela and Tuomas Laurila and Annalea Lohila and Frank Berninger",

year = "2014",

doi = "10.1111/gcb.12640",

language = "English",

volume = "20",

pages = "3439--3456",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell",

number = "11",

}

Kasurinen, V, Alfredsen, K, Kolari, P, Mammarella, I, Alekseychik, P, Rinne, J, Vesala, T, Bernier, P, Boike, J, Langer, M, Marchesini, LB, Van Huissteden, K, Dolman, H, Sachs, T, Ohta, T, Varlagin, A, Rocha, A, Arain, A, Oechel, W, Lund, M, Grelle, A, Lindroth, A, Black, A, Aurela, M, Laurila, T, Lohila, A & Berninger, F 2014, 'Latent heat exchange in the boreal and arctic biomes', Global Change Biology, vol. 20, no. 11, pp. 3439-3456. https://doi.org/10.1111/gcb.12640

TY - JOUR

T1 - Latent heat exchange in the boreal and arctic biomes

AU - Kasurinen, Ville

AU - Alfredsen, Knut

AU - Kolari, Pasi

AU - Mammarella, Ivan

AU - Alekseychik, Pavel

AU - Rinne, Janne

AU - Vesala, Timo

AU - Bernier, Pierre

AU - Boike, Julia

AU - Langer, Moritz

AU - Marchesini, Luca Belelli

AU - Van Huissteden, Ko

AU - Dolman, Han

AU - Sachs, Torsten

AU - Ohta, Takeshi

AU - Varlagin, Andrej

AU - Rocha, Adrian

AU - Arain, Altaf

AU - Oechel, Walter

AU - Lund, Magnus

AU - Grelle, Achim

AU - Lindroth, Anders

AU - Black, Andy

AU - Aurela, Mika

AU - Laurila, Tuomas

AU - Lohila, Annalea

AU - Berninger, Frank

PY - 2014

Y1 - 2014

N2 - In this study latent heat flux (E) measurements made at 65 boreal and arctic eddy-covariance (EC) sites were analyses by using the Penman-Monteith equation. Sites were stratified into nine different ecosystem types: harvested and burnt forest areas, pine forests, spruce or fir forests, Douglas-fir forests, broadleaf deciduous forests, larch forests, wetlands, tundra and natural grasslands. The Penman-Monteith equation was calibrated with variable surface resistances against half-hourly eddy-covariance data and clear differences between ecosystem types were observed. Based on the modeled behavior of surface and aerodynamic resistances, surface resistance tightly control E in most mature forests, while it had less importance in ecosystems having shorter vegetation like young or recently harvested forests, grasslands, wetlands and tundra. The parameters of the Penman-Monteith equation were clearly different for winter and summer conditions, indicating that phenological effects on surface resistance are important. We also compared the simulated E of different ecosystem types under meteorological conditions at one site. Values of E varied between 15% and 38% of the net radiation in the simulations with mean ecosystem parameters. In general, the simulations suggest that E is higher from forested ecosystems than from grasslands, wetlands or tundra-type ecosystems. Forests showed usually a tighter stomatal control of E as indicated by a pronounced sensitivity of surface resistance to atmospheric vapor pressure deficit. Nevertheless, the surface resistance of forests was lower than for open vegetation types including wetlands. Tundra and wetlands had higher surface resistances, which were less sensitive to vapor pressure deficits. The results indicate that the variation in surface resistance within and between different vegetation types might play a significant role in energy exchange between terrestrial ecosystems and atmosphere. These results suggest the need to take into account vegetation type and phenology in energy exchange modeling.

AB - In this study latent heat flux (E) measurements made at 65 boreal and arctic eddy-covariance (EC) sites were analyses by using the Penman-Monteith equation. Sites were stratified into nine different ecosystem types: harvested and burnt forest areas, pine forests, spruce or fir forests, Douglas-fir forests, broadleaf deciduous forests, larch forests, wetlands, tundra and natural grasslands. The Penman-Monteith equation was calibrated with variable surface resistances against half-hourly eddy-covariance data and clear differences between ecosystem types were observed. Based on the modeled behavior of surface and aerodynamic resistances, surface resistance tightly control E in most mature forests, while it had less importance in ecosystems having shorter vegetation like young or recently harvested forests, grasslands, wetlands and tundra. The parameters of the Penman-Monteith equation were clearly different for winter and summer conditions, indicating that phenological effects on surface resistance are important. We also compared the simulated E of different ecosystem types under meteorological conditions at one site. Values of E varied between 15% and 38% of the net radiation in the simulations with mean ecosystem parameters. In general, the simulations suggest that E is higher from forested ecosystems than from grasslands, wetlands or tundra-type ecosystems. Forests showed usually a tighter stomatal control of E as indicated by a pronounced sensitivity of surface resistance to atmospheric vapor pressure deficit. Nevertheless, the surface resistance of forests was lower than for open vegetation types including wetlands. Tundra and wetlands had higher surface resistances, which were less sensitive to vapor pressure deficits. The results indicate that the variation in surface resistance within and between different vegetation types might play a significant role in energy exchange between terrestrial ecosystems and atmosphere. These results suggest the need to take into account vegetation type and phenology in energy exchange modeling.

KW - eddy-covariance

KW - evapotranspiration

KW - latent heat

KW - phenology

KW - stomatal

KW - resistance

U2 - 10.1111/gcb.12640

DO - 10.1111/gcb.12640

M3 - Review article

C2 - 24889888

SN - 1354-1013

VL - 20

SP - 3439

EP - 3456

JO - Global Change Biology

JF - Global Change Biology

IS - 11

ER -

Latent heat exchange in the boreal and arctic biomes

Abstract

Subject classification (UKÄ)

Free keywords

UN SDGs

Access to Document

Fingerprint

Cite this