Application of the metabolic scaling theory and water–energy balance equation to model large‐scale patterns of maximum forest canopy height. Issue 12 (18th August 2016)
- Record Type:
- Journal Article
- Title:
- Application of the metabolic scaling theory and water–energy balance equation to model large‐scale patterns of maximum forest canopy height. Issue 12 (18th August 2016)
- Main Title:
- Application of the metabolic scaling theory and water–energy balance equation to model large‐scale patterns of maximum forest canopy height
- Authors:
- Choi, Sungho
Kempes, Christopher P.
Park, Taejin
Ganguly, Sangram
Wang, Weile
Xu, Liang
Basu, Saikat
Dungan, Jennifer L.
Simard, Marc
Saatchi, Sassan S.
Piao, Shilong
Ni, Xiliang
Shi, Yuli
Cao, Chunxiang
Nemani, Ramakrishna R.
Knyazikhin, Yuri
Myneni, Ranga B. - Other Names:
- McGill Brian checker.
- Abstract:
- Abstract: Aim: Forest height, an important biophysical property, underlies the distribution of carbon stocks across scales. Because in situ observations are labour intensive and thus impractical for large‐scale mapping and monitoring of forest heights, most previous studies adopted statistical approaches to help alleviate measured data discontinuity in space and time. Here, we document an improved modelling approach which links metabolic scaling theory and the water–energy balance equation with actual observations in order to produce large‐scale patterns of forest heights. Methods: Our model, called allometric scaling and resource limitations (ASRL), accounts for the size‐dependent metabolism of trees whose maximum growth is constrained by local resource availability. Geospatial predictors used in the model are altitude and monthly precipitation, solar radiation, temperature, vapour pressure and wind speed. Disturbance history (i.e. stand age) is also incorporated to estimate contemporary forest heights. Results: This study provides a baseline map ( c . 2005; 1‐km 2 grids) of forest heights over the contiguous United States. The Pacific Northwest/California is predicted as the most favourable region for hosting large trees ( c . 100 m) because of sufficient annual precipitation (> 1400 mm), moderate solar radiation ( c . 330 W m −2 ) and temperature ( c . 14 °C). Our results at sub‐regional level are generally in good and statistically significant ( P ‐value < 0.001)Abstract: Aim: Forest height, an important biophysical property, underlies the distribution of carbon stocks across scales. Because in situ observations are labour intensive and thus impractical for large‐scale mapping and monitoring of forest heights, most previous studies adopted statistical approaches to help alleviate measured data discontinuity in space and time. Here, we document an improved modelling approach which links metabolic scaling theory and the water–energy balance equation with actual observations in order to produce large‐scale patterns of forest heights. Methods: Our model, called allometric scaling and resource limitations (ASRL), accounts for the size‐dependent metabolism of trees whose maximum growth is constrained by local resource availability. Geospatial predictors used in the model are altitude and monthly precipitation, solar radiation, temperature, vapour pressure and wind speed. Disturbance history (i.e. stand age) is also incorporated to estimate contemporary forest heights. Results: This study provides a baseline map ( c . 2005; 1‐km 2 grids) of forest heights over the contiguous United States. The Pacific Northwest/California is predicted as the most favourable region for hosting large trees ( c . 100 m) because of sufficient annual precipitation (> 1400 mm), moderate solar radiation ( c . 330 W m −2 ) and temperature ( c . 14 °C). Our results at sub‐regional level are generally in good and statistically significant ( P ‐value < 0.001) agreement with independent reference datasets: field measurements [mean absolute error (MAE) = 4.0 m], airborne/spaceborne lidar (MAE = 7.0 m) and an existing global forest height product (MAE = 4.9 m). Model uncertainties at county level are also discussed in this study. Main conclusions: We improved the metabolic scaling theory to address variations in vertical forest structure due to ecoregion and plant functional type. A clear mechanistic understanding embedded within the model allowed synergistic combinations between actual observations and multiple geopredictors in forest height mapping. This approach shows potential for prognostic applications, unlike previous statistical approaches. … (more)
- Is Part Of:
- Global ecology & biogeography. Volume 25:Issue 12(2016)
- Journal:
- Global ecology & biogeography
- Issue:
- Volume 25:Issue 12(2016)
- Issue Display:
- Volume 25, Issue 12 (2016)
- Year:
- 2016
- Volume:
- 25
- Issue:
- 12
- Issue Sort Value:
- 2016-0025-0012-0000
- Page Start:
- 1428
- Page End:
- 1442
- Publication Date:
- 2016-08-18
- Subjects:
- Carbon monitoring -- disturbance history -- geospatial predictors -- large‐scale modelling -- maximum forest height -- mechanistic understanding -- metabolic scaling theory -- prognostic applications -- water–energy balance
Ecology -- Periodicals
Biogeography -- Periodicals
Biodiversity -- Periodicals
Macroevolution -- Periodicals
577 - Journal URLs:
- http://onlinelibrary.wiley.com/journal/10.1111/(ISSN)1466-8238 ↗
http://onlinelibrary.wiley.com/ ↗ - DOI:
- 10.1111/geb.12503 ↗
- Languages:
- English
- ISSNs:
- 1466-822X
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 4195.390700
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- 2434.xml