Contrasting thermophilization among forests, grasslands and alpine summits

Kai Yue; Pieter Vangansbeke; Isla H. Myers-Smith; Donald M. Waller; Kris Verheyen; Markus Bernhardt-Römermann; Lander Baeten; Ingmar R. Staude; Anne D. Bjorkman; Radim Hédl; Christopher Andrews; Elena Barni; Thomas Becker; Antoine Becker-Scarpitta; José-Luis Benito-Alonso; Jonathan Bennie; Imre Berki; Volker Blüml; Jörg Brunet; James M. Bullock; Hans Van Calster; Michele Carbognani; Markéta Chudomelová; Déborah Closset-Kopp; Pavel Dan Turtureanu; Gergana N. Daskalova; Guillaume Decocq; Jan Dick; Martin Diekmann; Thomas Dirnböck; Tomasz Durak; Ove Eriksson; Brigitta Erschbamer; Bente Jessen Graae; Thilo Heinken; Martin Hermy; Peter Horchler; Ute Jandt; Bogdan Jaroszewicz; Róbert Kanka; Jozef Kollár; Martin Kopecký; Thomas Kudernatsch; Andrea Lamprecht; Jonathan Lenoir; Martin Macek; Marek Malicki; František Máliš; Ottar Michelsen; Fraser Mitchell; Tobias Naaf; Thomas A. Nagel; Miles Newman; Adrian C. Newton; Lena Nicklas; Ludovica Oddi; Anna Orczewska; Simone Orsenigo; Adrienne Ortmann-Ajkai; Jan den Ouden; Harald Pauli; George Peterken; Petr Petřík; Remigiusz Pielech; Mihai Puşcaş; Christophe Randin; Kamila Reczyńska; Christian Rixen; Fride Høistad Schei; Wolfgang Schmidt; Jan Šebesta; Alina Stachurska-Swakon; Tibor Standovár; Krzysztof Świerkosz; Balázs Teleki; Jean-Paul Theurillat; Tudor-Mihai Ursu; Thomas Vanneste; Mark Vellend; Philippine Vergeer; Ondřej Vild; Luis Villar; Pascal Vittoz; Manuela Winkler; Sonja Wipf; Fuzhong Wu; Shengmin Zhang; Pieter De Frenne

doi:10.1038/s41586-025-09622-7

Contrasting thermophilization among forests, grasslands and alpine summits

Kai Yue
, Pieter Vangansbeke
, Isla H. Myers-Smith
, Donald M. Waller
, Kris Verheyen
, Markus Bernhardt-Römermann
, Lander Baeten
, Ingmar R. Staude
, Anne D. Bjorkman
, Radim Hédl
, Christopher Andrews
, Elena Barni
, Thomas Becker
, Antoine Becker-Scarpitta
, José-Luis Benito-Alonso
, Jonathan Bennie
, Imre Berki
, Volker Blüml
, Jörg Brunet
, James M. Bullock

Hans Van Calster, Michele Carbognani, Markéta Chudomelová, Déborah Closset-Kopp, Pavel Dan Turtureanu, Gergana N. Daskalova, Guillaume Decocq, Jan Dick, Martin Diekmann, Thomas Dirnböck, Tomasz Durak, Ove Eriksson, Brigitta Erschbamer, Bente Jessen Graae, Thilo Heinken, Martin Hermy, Peter Horchler, Ute Jandt, Bogdan Jaroszewicz, Róbert Kanka, Jozef Kollár, Martin Kopecký, Thomas Kudernatsch, Andrea Lamprecht, Jonathan Lenoir, Martin Macek, Marek Malicki, František Máliš, Ottar Michelsen, Fraser Mitchell, Tobias Naaf, Thomas A. Nagel, Miles Newman, Adrian C. Newton, Lena Nicklas, Ludovica Oddi, Anna Orczewska, Simone Orsenigo, Adrienne Ortmann-Ajkai, Jan den Ouden, Harald Pauli, George Peterken, Petr Petřík, Remigiusz Pielech, Mihai Puşcaş, Christophe Randin, Kamila Reczyńska, Christian Rixen, Fride Høistad Schei, Wolfgang Schmidt, Jan Šebesta, Alina Stachurska-Swakon, Tibor Standovár, Krzysztof Świerkosz, Balázs Teleki, Jean-Paul Theurillat, Tudor-Mihai Ursu, Thomas Vanneste, Mark Vellend, Philippine Vergeer, Ondřej Vild, Luis Villar, Pascal Vittoz, Manuela Winkler, Sonja Wipf, Fuzhong Wu, Shengmin Zhang, Pieter De Frenne

Research output: Contribution to journal › A1: Web of Science-article › peer-review

Abstract

Climate warming is shifting biological communities, with warmth-demanding species being favoured at the expense of cold-adapted species in a process referred to as thermophilization1–4. Because biodiversity responses often lag behind climate warming, climatic debts are accumulating in many ecosystems across the world5–7. Although we might expect that thermophilization and climatic debts will vary among habitats, standardized quantification across ecosystems is lacking. Here we analysed multidecadal data from 6,067 resurveyed vegetation plots over 12–78 years in forests, grasslands and on alpine summits across Europe. We demonstrate that forest understory and grassland plant communities experienced positive thermophilization, although not significantly different from zero. By contrast, alpine summit vegetation showed much stronger (up to five times) and significant thermophilization. Thermophilization was driven largely by increases in warmth-demanding species in grasslands, by declines in cold-adapted species on alpine summits and by both processes in forests. Significant climatic debts have accumulated in forests and alpine summits, but less so in grasslands, with debts positively correlated with macroclimate temperature changes. Our findings uncover divergent thermophilization trajectories and increasing climatic debts across ecosystems. Moreover, we highlight the mechanisms that enable some communities to track climate change more closely than others and provide a basis for projecting future shifts in plant communities under accelerating climate warming.

Original language	English
Journal	Nature: International Weekly Journal of Science
Pages (from-to)	1
Number of pages	29
ISSN	1476-4687
DOIs	https://doi.org/10.1038/s41586-025-09622-7
Publication status	Published - 18-Mar-2026

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10.1038/s41586-025-09622-7

Cite this

Yue, K., Vangansbeke, P., Myers-Smith, I. H., Waller, D. M., Verheyen, K., Bernhardt-Römermann, M., Baeten, L., Staude, I. R., Bjorkman, A. D., Hédl, R., Andrews, C., Barni, E., Becker, T., Becker-Scarpitta, A., Benito-Alonso, J.-L., Bennie, J., Berki, I., Blüml, V., Brunet, J., ... De Frenne, P. (2026). Contrasting thermophilization among forests, grasslands and alpine summits. Nature: International Weekly Journal of Science, 1. https://doi.org/10.1038/s41586-025-09622-7

@article{00f0aa8d2ff8487cb7005d731d6c6052,

title = "Contrasting thermophilization among forests, grasslands and alpine summits",

abstract = "Climate warming is shifting biological communities, with warmth-demanding species being favoured at the expense of cold-adapted species in a process referred to as thermophilization1–4. Because biodiversity responses often lag behind climate warming, climatic debts are accumulating in many ecosystems across the world5–7. Although we might expect that thermophilization and climatic debts will vary among habitats, standardized quantification across ecosystems is lacking. Here we analysed multidecadal data from 6,067 resurveyed vegetation plots over 12–78 years in forests, grasslands and on alpine summits across Europe. We demonstrate that forest understory and grassland plant communities experienced positive thermophilization, although not significantly different from zero. By contrast, alpine summit vegetation showed much stronger (up to five times) and significant thermophilization. Thermophilization was driven largely by increases in warmth-demanding species in grasslands, by declines in cold-adapted species on alpine summits and by both processes in forests. Significant climatic debts have accumulated in forests and alpine summits, but less so in grasslands, with debts positively correlated with macroclimate temperature changes. Our findings uncover divergent thermophilization trajectories and increasing climatic debts across ecosystems. Moreover, we highlight the mechanisms that enable some communities to track climate change more closely than others and provide a basis for projecting future shifts in plant communities under accelerating climate warming.",

author = "Kai Yue and Pieter Vangansbeke and Myers-Smith, \{Isla H.\} and Waller, \{Donald M.\} and Kris Verheyen and Markus Bernhardt-R{\"o}mermann and Lander Baeten and Staude, \{Ingmar R.\} and Bjorkman, \{Anne D.\} and Radim H{\'e}dl and Christopher Andrews and Elena Barni and Thomas Becker and Antoine Becker-Scarpitta and Jos{\'e}-Luis Benito-Alonso and Jonathan Bennie and Imre Berki and Volker Bl{\"u}ml and J{\"o}rg Brunet and Bullock, \{James M.\} and \{Van Calster\}, Hans and Michele Carbognani and Mark{\'e}ta Chudomelov{\'a} and D{\'e}borah Closset-Kopp and \{Dan Turtureanu\}, Pavel and Daskalova, \{Gergana N.\} and Guillaume Decocq and Jan Dick and Martin Diekmann and Thomas Dirnb{\"o}ck and Tomasz Durak and Ove Eriksson and Brigitta Erschbamer and Graae, \{Bente Jessen\} and Thilo Heinken and Martin Hermy and Peter Horchler and Ute Jandt and Bogdan Jaroszewicz and R{\'o}bert Kanka and Jozef Koll{\'a}r and Martin Kopeck{\'y} and Thomas Kudernatsch and Andrea Lamprecht and Jonathan Lenoir and Martin Macek and Marek Malicki and Franti{\v s}ek M{\'a}li{\v s} and Ottar Michelsen and Fraser Mitchell and Tobias Naaf and Nagel, \{Thomas A.\} and Miles Newman and Newton, \{Adrian C.\} and Lena Nicklas and Ludovica Oddi and Anna Orczewska and Simone Orsenigo and Adrienne Ortmann-Ajkai and Ouden, \{Jan den\} and Harald Pauli and George Peterken and Petr Pet{\v r}{\'i}k and Remigiusz Pielech and Mihai Pu{\c s}ca{\c s} and Christophe Randin and Kamila Reczy{\'n}ska and Christian Rixen and Schei, \{Fride H{\o}istad\} and Wolfgang Schmidt and Jan {\v S}ebesta and Alina Stachurska-Swakon and Tibor Standov{\'a}r and Krzysztof {\'S}wierkosz and Bal{\'a}zs Teleki and Jean-Paul Theurillat and Tudor-Mihai Ursu and Thomas Vanneste and Mark Vellend and Philippine Vergeer and Ond{\v r}ej Vild and Luis Villar and Pascal Vittoz and Manuela Winkler and Sonja Wipf and Fuzhong Wu and Shengmin Zhang and \{De Frenne\}, Pieter",

year = "2026",

month = mar,

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doi = "10.1038/s41586-025-09622-7",

language = "English",

pages = "1",

journal = "Nature: International Weekly Journal of Science",

issn = "1476-4687",

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Yue, K, Vangansbeke, P, Myers-Smith, IH, Waller, DM, Verheyen, K, Bernhardt-Römermann, M, Baeten, L, Staude, IR, Bjorkman, AD, Hédl, R, Andrews, C, Barni, E, Becker, T, Becker-Scarpitta, A, Benito-Alonso, J-L, Bennie, J, Berki, I, Blüml, V, Brunet, J, Bullock, JM, Van Calster, H, Carbognani, M, Chudomelová, M, Closset-Kopp, D, Dan Turtureanu, P, Daskalova, GN, Decocq, G, Dick, J, Diekmann, M, Dirnböck, T, Durak, T, Eriksson, O, Erschbamer, B, Graae, BJ, Heinken, T, Hermy, M, Horchler, P, Jandt, U, Jaroszewicz, B, Kanka, R, Kollár, J, Kopecký, M, Kudernatsch, T, Lamprecht, A, Lenoir, J, Macek, M, Malicki, M, Máliš, F, Michelsen, O, Mitchell, F, Naaf, T, Nagel, TA, Newman, M, Newton, AC, Nicklas, L, Oddi, L, Orczewska, A, Orsenigo, S, Ortmann-Ajkai, A, Ouden, JD, Pauli, H, Peterken, G, Petřík, P, Pielech, R, Puşcaş, M, Randin, C, Reczyńska, K, Rixen, C, Schei, FH, Schmidt, W, Šebesta, J, Stachurska-Swakon, A, Standovár, T, Świerkosz, K, Teleki, B, Theurillat, J-P, Ursu, T-M, Vanneste, T, Vellend, M, Vergeer, P, Vild, O, Villar, L, Vittoz, P, Winkler, M, Wipf, S, Wu, F, Zhang, S & De Frenne, P 2026, 'Contrasting thermophilization among forests, grasslands and alpine summits', Nature: International Weekly Journal of Science, pp. 1. https://doi.org/10.1038/s41586-025-09622-7

TY - JOUR

T1 - Contrasting thermophilization among forests, grasslands and alpine summits

AU - Yue, Kai

AU - Vangansbeke, Pieter

AU - Myers-Smith, Isla H.

AU - Waller, Donald M.

AU - Verheyen, Kris

AU - Bernhardt-Römermann, Markus

AU - Baeten, Lander

AU - Staude, Ingmar R.

AU - Bjorkman, Anne D.

AU - Hédl, Radim

AU - Andrews, Christopher

AU - Barni, Elena

AU - Becker, Thomas

AU - Becker-Scarpitta, Antoine

AU - Benito-Alonso, José-Luis

AU - Bennie, Jonathan

AU - Berki, Imre

AU - Blüml, Volker

AU - Brunet, Jörg

AU - Bullock, James M.

AU - Van Calster, Hans

AU - Carbognani, Michele

AU - Chudomelová, Markéta

AU - Closset-Kopp, Déborah

AU - Dan Turtureanu, Pavel

AU - Daskalova, Gergana N.

AU - Decocq, Guillaume

AU - Dick, Jan

AU - Diekmann, Martin

AU - Dirnböck, Thomas

AU - Durak, Tomasz

AU - Eriksson, Ove

AU - Erschbamer, Brigitta

AU - Graae, Bente Jessen

AU - Heinken, Thilo

AU - Hermy, Martin

AU - Horchler, Peter

AU - Jandt, Ute

AU - Jaroszewicz, Bogdan

AU - Kanka, Róbert

AU - Kollár, Jozef

AU - Kopecký, Martin

AU - Kudernatsch, Thomas

AU - Lamprecht, Andrea

AU - Lenoir, Jonathan

AU - Macek, Martin

AU - Malicki, Marek

AU - Máliš, František

AU - Michelsen, Ottar

AU - Mitchell, Fraser

AU - Naaf, Tobias

AU - Nagel, Thomas A.

AU - Newman, Miles

AU - Newton, Adrian C.

AU - Nicklas, Lena

AU - Oddi, Ludovica

AU - Orczewska, Anna

AU - Orsenigo, Simone

AU - Ortmann-Ajkai, Adrienne

AU - Ouden, Jan den

AU - Pauli, Harald

AU - Peterken, George

AU - Petřík, Petr

AU - Pielech, Remigiusz

AU - Puşcaş, Mihai

AU - Randin, Christophe

AU - Reczyńska, Kamila

AU - Rixen, Christian

AU - Schei, Fride Høistad

AU - Schmidt, Wolfgang

AU - Šebesta, Jan

AU - Stachurska-Swakon, Alina

AU - Standovár, Tibor

AU - Świerkosz, Krzysztof

AU - Teleki, Balázs

AU - Theurillat, Jean-Paul

AU - Ursu, Tudor-Mihai

AU - Vanneste, Thomas

AU - Vellend, Mark

AU - Vergeer, Philippine

AU - Vild, Ondřej

AU - Villar, Luis

AU - Vittoz, Pascal

AU - Winkler, Manuela

AU - Wipf, Sonja

AU - Wu, Fuzhong

AU - Zhang, Shengmin

AU - De Frenne, Pieter

PY - 2026/3/18

Y1 - 2026/3/18

N2 - Climate warming is shifting biological communities, with warmth-demanding species being favoured at the expense of cold-adapted species in a process referred to as thermophilization1–4. Because biodiversity responses often lag behind climate warming, climatic debts are accumulating in many ecosystems across the world5–7. Although we might expect that thermophilization and climatic debts will vary among habitats, standardized quantification across ecosystems is lacking. Here we analysed multidecadal data from 6,067 resurveyed vegetation plots over 12–78 years in forests, grasslands and on alpine summits across Europe. We demonstrate that forest understory and grassland plant communities experienced positive thermophilization, although not significantly different from zero. By contrast, alpine summit vegetation showed much stronger (up to five times) and significant thermophilization. Thermophilization was driven largely by increases in warmth-demanding species in grasslands, by declines in cold-adapted species on alpine summits and by both processes in forests. Significant climatic debts have accumulated in forests and alpine summits, but less so in grasslands, with debts positively correlated with macroclimate temperature changes. Our findings uncover divergent thermophilization trajectories and increasing climatic debts across ecosystems. Moreover, we highlight the mechanisms that enable some communities to track climate change more closely than others and provide a basis for projecting future shifts in plant communities under accelerating climate warming.

AB - Climate warming is shifting biological communities, with warmth-demanding species being favoured at the expense of cold-adapted species in a process referred to as thermophilization1–4. Because biodiversity responses often lag behind climate warming, climatic debts are accumulating in many ecosystems across the world5–7. Although we might expect that thermophilization and climatic debts will vary among habitats, standardized quantification across ecosystems is lacking. Here we analysed multidecadal data from 6,067 resurveyed vegetation plots over 12–78 years in forests, grasslands and on alpine summits across Europe. We demonstrate that forest understory and grassland plant communities experienced positive thermophilization, although not significantly different from zero. By contrast, alpine summit vegetation showed much stronger (up to five times) and significant thermophilization. Thermophilization was driven largely by increases in warmth-demanding species in grasslands, by declines in cold-adapted species on alpine summits and by both processes in forests. Significant climatic debts have accumulated in forests and alpine summits, but less so in grasslands, with debts positively correlated with macroclimate temperature changes. Our findings uncover divergent thermophilization trajectories and increasing climatic debts across ecosystems. Moreover, we highlight the mechanisms that enable some communities to track climate change more closely than others and provide a basis for projecting future shifts in plant communities under accelerating climate warming.

U2 - 10.1038/s41586-025-09622-7

DO - 10.1038/s41586-025-09622-7

M3 - A1: Web of Science-article

SN - 1476-4687

SP - 1

JO - Nature: International Weekly Journal of Science

JF - Nature: International Weekly Journal of Science

ER -