TY - JOUR
T1 - Joint optimization of land carbon uptake and albedo can help achieve moderate instantaneous and long-term cooling effects
AU - Graf, Alexander
AU - Wohlfahrt, Georg
AU - Aranda-Barranco, Sergio
AU - Arriga, Nicola
AU - Brümmer, Christian
AU - Ceschia, Eric
AU - Ciais, Philippe
AU - Desai, Ankur R.
AU - Di Lonardo, Sara
AU - Gharun, Mana
AU - Grünwald, Thomas
AU - Hörtnagl, Lukas
AU - Kasak, Kuno
AU - Klosterhalfen, Anne
AU - Knohl, Alexander
AU - Kowalska, Natalia
AU - Leuchner, Michael
AU - Lindroth, Anders
AU - Mauder, Matthias
AU - Migliavacca, Mirco
AU - Morel, Alexandra C.
AU - Pfennig, Andreas
AU - Poorter, Hendrik
AU - Terán, Christian Poppe
AU - Reitz, Oliver
AU - Rebmann, Corinna
AU - Sanchez-Azofeifa, Arturo
AU - Schmidt, Marius
AU - Šigut, Ladislav
AU - Tomelleri, Enrico
AU - Yu, Ke
AU - Varlagin, Andrej
AU - Vereecken, Harry
N1 - © The Author(s) 2023
Open Access funding enabled and organized by Projekt DEAL.
PY - 2023/8/25
Y1 - 2023/8/25
N2 - Both carbon dioxide uptake and albedo of the land surface affect global climate. However, climate change mitigation by increasing carbon uptake can cause a warming trade-off by decreasing albedo, with most research focusing on afforestation and its interaction with snow. Here, we present carbon uptake and albedo observations from 176 globally distributed flux stations. We demonstrate a gradual decline in maximum achievable annual albedo as carbon uptake increases, even within subgroups of non-forest and snow-free ecosystems. Based on a paired-site permutation approach, we quantify the likely impact of land use on carbon uptake and albedo. Shifting to the maximum attainable carbon uptake at each site would likely cause moderate net global warming for the first approximately 20 years, followed by a strong cooling effect. A balanced policy co-optimizing carbon uptake and albedo is possible that avoids warming on any timescale, but results in a weaker long-term cooling effect.
AB - Both carbon dioxide uptake and albedo of the land surface affect global climate. However, climate change mitigation by increasing carbon uptake can cause a warming trade-off by decreasing albedo, with most research focusing on afforestation and its interaction with snow. Here, we present carbon uptake and albedo observations from 176 globally distributed flux stations. We demonstrate a gradual decline in maximum achievable annual albedo as carbon uptake increases, even within subgroups of non-forest and snow-free ecosystems. Based on a paired-site permutation approach, we quantify the likely impact of land use on carbon uptake and albedo. Shifting to the maximum attainable carbon uptake at each site would likely cause moderate net global warming for the first approximately 20 years, followed by a strong cooling effect. A balanced policy co-optimizing carbon uptake and albedo is possible that avoids warming on any timescale, but results in a weaker long-term cooling effect.
KW - Carbon cycle
KW - Climate-change mitigation
UR - http://www.scopus.com/inward/record.url?scp=85169132523&partnerID=8YFLogxK
U2 - 10.1038/s43247-023-00958-4
DO - 10.1038/s43247-023-00958-4
M3 - Article
C2 - 38665193
SN - 2662-4435
VL - 4
JO - Communications Earth & Environment
JF - Communications Earth & Environment
M1 - 298
ER -