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Aim Projections of future climate change suggest that regional climates may evolve to states that are unlike any climate regime found on Earth today. These climates will impose novel constraints on plant species, and are likely to give rise to plant associations that are compositionally unlike any found on Earth today. Here, we explore whether the geographical distribution of previously mapped no-analogue climates corresponds to the geographical distribution of simulated no-analogue vegetation under scenarios of global warming. Location Global landmasses. Methods We used JeDi, a process-based vegetation model that accounts for ecophysiological trade-offs in plant growth and survival, to identify the assembly of...
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Aim Projections of future climate change suggest that regional climates may evolve to states that are unlike any climate regime found on Earth today. These climates will impose novel constraints on plant species, and are likely to give rise to plant associations that are compositionally unlike any found on Earth today. Here, we explore whether the geographical distribution of previously mapped no-analogue climates corresponds to the geographical distribution of simulated no-analogue vegetation under scenarios of global warming. Location Global landmasses. Methods We used JeDi, a process-based vegetation model that accounts for ecophysiological trade-offs in plant growth and survival, to identify the assembly of...
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Aim Projections of future climate change suggest that regional climates may evolve to states that are unlike any climate regime found on Earth today. These climates will impose novel constraints on plant species, and are likely to give rise to plant associations that are compositionally unlike any found on Earth today. Here, we explore whether the geographical distribution of previously mapped no-analogue climates corresponds to the geographical distribution of simulated no-analogue vegetation under scenarios of global warming. Location Global landmasses. Methods We used JeDi, a process-based vegetation model that accounts for ecophysiological trade-offs in plant growth and survival, to identify the assembly of...
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