Intra-annual tree growth responds to micrometeorological variability in the central Amazon

Intra-annual distribution of precipitation in central Amazonia leads to a short mild dry season, which is associated with an increase in irradiance and temperature and a decline in relative humidity; however, the independent effect of each individual climatic variable on tree growth is still under i...
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Autor*in:	Antezana-Vera SA [verfasserIn] Marenco RA [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2021

Schlagwörter:	Atmospheric Evaporative Demand Tropical Rainforest Wood Density

Übergeordnetes Werk:	In: iForest - Biogeosciences and Forestry - Italian Society of Silviculture and Forest Ecology (SISEF), 2019, 14(2021), 1, Seite 242-249
Übergeordnetes Werk:	volume:14 ; year:2021 ; number:1 ; pages:242-249

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3832/ifor3532-014

Katalog-ID:	DOAJ002626071

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author	Antezana-Vera SA
spellingShingle	Antezana-Vera SA misc SD1-669.5 misc Atmospheric Evaporative Demand misc Tropical Rainforest misc Wood Density misc Forestry Intra-annual tree growth responds to micrometeorological variability in the central Amazon
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topic_title	SD1-669.5 Intra-annual tree growth responds to micrometeorological variability in the central Amazon Atmospheric Evaporative Demand Tropical Rainforest Wood Density
topic	misc SD1-669.5 misc Atmospheric Evaporative Demand misc Tropical Rainforest misc Wood Density misc Forestry
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title	Intra-annual tree growth responds to micrometeorological variability in the central Amazon
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title_full	Intra-annual tree growth responds to micrometeorological variability in the central Amazon
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title_sort	intra-annual tree growth responds to micrometeorological variability in the central amazon
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title_auth	Intra-annual tree growth responds to micrometeorological variability in the central Amazon
abstract	Intra-annual distribution of precipitation in central Amazonia leads to a short mild dry season, which is associated with an increase in irradiance and temperature and a decline in relative humidity; however, the independent effect of each individual climatic variable on tree growth is still under investigation. The objective of this study was to determine how tree growth (inferred from radial stem increment) responds to monthly variations of micrometeorological variables in the central Amazon. During five years (2013-2017) we measured tree growth in 51 trees from nine species and, above the forest canopy, collected environmental data, such as photosynthetically active radiation (PAR), air temperature (T), precipitation, air relative humidity (RH), air vapor pressure deficit (VPD), reference evapotranspiration (ETo), and soil water content (SWC). We used principal component regression to evaluate the effect of micrometeorological variability on tree growth. Mean tree growth across species was responsive to variations in almost all the micrometeorological variables examined, with the exception of mean and minimum temperature, maximum RH, and minimum VPD. Mean tree growth across species increased with increasing precipitation, RHmean, RHmin and SWC, while it decreased with increasing PAR, Tmax, and ETo. It was also shown that an increase in VPDmean and VPDmax has a negative effect on tree growth. These results contribute to improve our understanding of effect of climate variability on tree growth, and shed light on the potential effect of severe droughts in the central Amazon.
abstractGer	Intra-annual distribution of precipitation in central Amazonia leads to a short mild dry season, which is associated with an increase in irradiance and temperature and a decline in relative humidity; however, the independent effect of each individual climatic variable on tree growth is still under investigation. The objective of this study was to determine how tree growth (inferred from radial stem increment) responds to monthly variations of micrometeorological variables in the central Amazon. During five years (2013-2017) we measured tree growth in 51 trees from nine species and, above the forest canopy, collected environmental data, such as photosynthetically active radiation (PAR), air temperature (T), precipitation, air relative humidity (RH), air vapor pressure deficit (VPD), reference evapotranspiration (ETo), and soil water content (SWC). We used principal component regression to evaluate the effect of micrometeorological variability on tree growth. Mean tree growth across species was responsive to variations in almost all the micrometeorological variables examined, with the exception of mean and minimum temperature, maximum RH, and minimum VPD. Mean tree growth across species increased with increasing precipitation, RHmean, RHmin and SWC, while it decreased with increasing PAR, Tmax, and ETo. It was also shown that an increase in VPDmean and VPDmax has a negative effect on tree growth. These results contribute to improve our understanding of effect of climate variability on tree growth, and shed light on the potential effect of severe droughts in the central Amazon.
abstract_unstemmed	Intra-annual distribution of precipitation in central Amazonia leads to a short mild dry season, which is associated with an increase in irradiance and temperature and a decline in relative humidity; however, the independent effect of each individual climatic variable on tree growth is still under investigation. The objective of this study was to determine how tree growth (inferred from radial stem increment) responds to monthly variations of micrometeorological variables in the central Amazon. During five years (2013-2017) we measured tree growth in 51 trees from nine species and, above the forest canopy, collected environmental data, such as photosynthetically active radiation (PAR), air temperature (T), precipitation, air relative humidity (RH), air vapor pressure deficit (VPD), reference evapotranspiration (ETo), and soil water content (SWC). We used principal component regression to evaluate the effect of micrometeorological variability on tree growth. Mean tree growth across species was responsive to variations in almost all the micrometeorological variables examined, with the exception of mean and minimum temperature, maximum RH, and minimum VPD. Mean tree growth across species increased with increasing precipitation, RHmean, RHmin and SWC, while it decreased with increasing PAR, Tmax, and ETo. It was also shown that an increase in VPDmean and VPDmax has a negative effect on tree growth. These results contribute to improve our understanding of effect of climate variability on tree growth, and shed light on the potential effect of severe droughts in the central Amazon.
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title_short	Intra-annual tree growth responds to micrometeorological variability in the central Amazon
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