Tropical forest leaves may darken in response to climate change

Christopher E. Doughty; Paul Efren Santos-Andrade; Alexander Shenkin; Gregory R. Goldsmith; Lisa P. Bentley; Benjamin Blonder; Sandra Díaz; Norma Salinas; Brian J. Enquist; Roberta E. Martin; Gregory P. Asner; Yadvinder Malhi

doi:10.1038/s41559-018-0716-y

Tropical forest leaves may darken in response to climate change

Christopher E. Doughty, Paul Efren Santos-Andrade, Alexander Shenkin, Gregory R. Goldsmith, Lisa P. Bentley, Benjamin Blonder, Sandra Díaz, Norma Salinas, Brian J. Enquist, Roberta E. Martin, Gregory P. Asner, Yadvinder Malhi

Informatics, Computing, and Cyber Systems, School of

Research output: Contribution to journal › Article › peer-review

25 Scopus citations

Abstract

Tropical forest leaf albedo (reflectance) greatly impacts how much energy the planet absorbs; however; little is known about how it might be impacted by climate change. Here, we measure leaf traits and leaf albedo at ten 1-ha plots along a 3,200-m elevation gradient in Peru. Leaf mass per area (LMA) decreased with warmer temperatures along the elevation gradient; the distribution of LMA was positively skewed at all sites indicating a shift in LMA towards a warmer climate and future reduced tropical LMA. Reduced LMA was significantly (P < 0.0001) correlated with reduced leaf near-infrared (NIR) albedo; community-weighted mean NIR albedo significantly (P < 0.01) decreased as temperature increased. A potential future 2 °C increase in tropical temperatures could reduce lowland tropical leaf LMA by 6–7 g m ⁻ ² (5–6%) and reduce leaf NIR albedo by 0.0015–0.002 units. Reduced NIR albedo means that leaves are darker and absorb more of the Sun’s energy. Climate simulations indicate this increased absorbed energy will warm tropical forests more at high CO ₂ conditions with proportionately more energy going towards heating and less towards evapotranspiration and cloud formation.

Original language	English (US)
Pages (from-to)	1918-1924
Number of pages	7
Journal	Nature Ecology and Evolution
Volume	2
Issue number	12
DOIs	https://doi.org/10.1038/s41559-018-0716-y
State	Published - Dec 1 2018

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Ecology

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title = "Tropical forest leaves may darken in response to climate change",

abstract = " Tropical forest leaf albedo (reflectance) greatly impacts how much energy the planet absorbs; however; little is known about how it might be impacted by climate change. Here, we measure leaf traits and leaf albedo at ten 1-ha plots along a 3,200-m elevation gradient in Peru. Leaf mass per area (LMA) decreased with warmer temperatures along the elevation gradient; the distribution of LMA was positively skewed at all sites indicating a shift in LMA towards a warmer climate and future reduced tropical LMA. Reduced LMA was significantly (P < 0.0001) correlated with reduced leaf near-infrared (NIR) albedo; community-weighted mean NIR albedo significantly (P < 0.01) decreased as temperature increased. A potential future 2 °C increase in tropical temperatures could reduce lowland tropical leaf LMA by 6–7 g m − 2 (5–6%) and reduce leaf NIR albedo by 0.0015–0.002 units. Reduced NIR albedo means that leaves are darker and absorb more of the Sun{\textquoteright}s energy. Climate simulations indicate this increased absorbed energy will warm tropical forests more at high CO 2 conditions with proportionately more energy going towards heating and less towards evapotranspiration and cloud formation.",

author = "Doughty, {Christopher E.} and Santos-Andrade, {Paul Efren} and Alexander Shenkin and Goldsmith, {Gregory R.} and Bentley, {Lisa P.} and Benjamin Blonder and Sandra D{\'i}az and Norma Salinas and Enquist, {Brian J.} and Martin, {Roberta E.} and Asner, {Gregory P.} and Yadvinder Malhi",

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AU - Doughty, Christopher E.

AU - Santos-Andrade, Paul Efren

AU - Shenkin, Alexander

AU - Goldsmith, Gregory R.

AU - Bentley, Lisa P.

AU - Blonder, Benjamin

AU - Díaz, Sandra

AU - Salinas, Norma

AU - Enquist, Brian J.

AU - Martin, Roberta E.

AU - Asner, Gregory P.

AU - Malhi, Yadvinder

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N2 - Tropical forest leaf albedo (reflectance) greatly impacts how much energy the planet absorbs; however; little is known about how it might be impacted by climate change. Here, we measure leaf traits and leaf albedo at ten 1-ha plots along a 3,200-m elevation gradient in Peru. Leaf mass per area (LMA) decreased with warmer temperatures along the elevation gradient; the distribution of LMA was positively skewed at all sites indicating a shift in LMA towards a warmer climate and future reduced tropical LMA. Reduced LMA was significantly (P < 0.0001) correlated with reduced leaf near-infrared (NIR) albedo; community-weighted mean NIR albedo significantly (P < 0.01) decreased as temperature increased. A potential future 2 °C increase in tropical temperatures could reduce lowland tropical leaf LMA by 6–7 g m − 2 (5–6%) and reduce leaf NIR albedo by 0.0015–0.002 units. Reduced NIR albedo means that leaves are darker and absorb more of the Sun’s energy. Climate simulations indicate this increased absorbed energy will warm tropical forests more at high CO 2 conditions with proportionately more energy going towards heating and less towards evapotranspiration and cloud formation.

AB - Tropical forest leaf albedo (reflectance) greatly impacts how much energy the planet absorbs; however; little is known about how it might be impacted by climate change. Here, we measure leaf traits and leaf albedo at ten 1-ha plots along a 3,200-m elevation gradient in Peru. Leaf mass per area (LMA) decreased with warmer temperatures along the elevation gradient; the distribution of LMA was positively skewed at all sites indicating a shift in LMA towards a warmer climate and future reduced tropical LMA. Reduced LMA was significantly (P < 0.0001) correlated with reduced leaf near-infrared (NIR) albedo; community-weighted mean NIR albedo significantly (P < 0.01) decreased as temperature increased. A potential future 2 °C increase in tropical temperatures could reduce lowland tropical leaf LMA by 6–7 g m − 2 (5–6%) and reduce leaf NIR albedo by 0.0015–0.002 units. Reduced NIR albedo means that leaves are darker and absorb more of the Sun’s energy. Climate simulations indicate this increased absorbed energy will warm tropical forests more at high CO 2 conditions with proportionately more energy going towards heating and less towards evapotranspiration and cloud formation.

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Tropical forest leaves may darken in response to climate change

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