Confronting terrestrial biosphere models with forest inventory data
Confronting terrestrial biosphere models with forest inventory data
Efforts to test and improve terrestrial biosphere models (TBMs) using a variety of data sources have become increasingly common. Yet, geographically extensive forest inventories have been under-exploited in previous model-data fusion efforts. Inventory observations of forest growth, mortality, and biomass integrate processes across a range of timescales, including slow timescale processes such as species turnover, that are likely to have important effects on ecosystem responses to environmental variation. However, the large number (thousands) of inventory plots precludes detailed measurements at each location, so that uncertainty in climate, soil properties, and other environmental drivers may be large. Errors in driver variables, if ignored, introduce bias into model-data fusion. We estimated errors in climate and soil drivers at U.S. Forest Inventory and Analysis (FIA) plots, and we explored the effects of these errors on model-data fusion with the Geophysical Fluid Dynamics Laboratory LM3V dynamic global vegetation model. When driver errors were ignored or assumed small at FIA plots, responses of biomass production in LM3V to precipitation and soil available water capacity appeared steeper than the corresponding responses estimated from FIA data. These differences became nonsignificant if driver errors at FIA plots were assumed to be large. Ignoring driver errors when optimizing LM3V parameter values yielded estimates for fine-root allocation that were larger than biometric estimates, which is consistent with the expected direction of bias. To explore whether complications posed by driver errors could be circumvented by relying on intensive study sites where driver errors are small, we performed a power analysis. To accurately quantify the response of biomass production to spatial variation in mean annual precipitation within the eastern United States would require at least 40 intensive study sites, which is larger than the number of sites typically available for individual biomes in existing plot networks. Driver errors may be accommodated by several existing model-data fusion approaches, including hierarchical Bayesian methods and ensemble filtering methods; however, these methods are computationally expensive. We propose a new approach, in which the TBM functional response is fit directly to the driver-error-corrected functional response estimated from data, rather than to the raw observations.
Carbon cycle model, Data assimilation, Errors in explanatory variables, Global ecosystem model, Land surface model, Measurement error models
699-715
Lichstein, Jeremy W.
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Golaz, Ni Zhang
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Malyshev, Sergey
6460b11f-bc6c-47aa-9b79-71fb790bfb0b
Shevliakova, Elena
1b75d435-80fe-4792-b21b-29813af267d9
Zhang, Tao
002b6b95-19d0-45ff-8718-34d4fb927203
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Birdsey, Richard A.
d5f69158-7e8f-4c78-8c5b-a8ccb869137f
Sarmiento, Jorge L.
45f5964b-15e6-43e8-bdd4-8789e2eb87cb
Pacala, Stephen W.
367972eb-6594-4c27-b066-de2a4312f815
June 2014
Lichstein, Jeremy W.
df1038ec-e532-4b5a-87da-d1726ed28b6b
Golaz, Ni Zhang
c520a9ab-c1eb-4702-ad70-7102e9c09e5e
Malyshev, Sergey
6460b11f-bc6c-47aa-9b79-71fb790bfb0b
Shevliakova, Elena
1b75d435-80fe-4792-b21b-29813af267d9
Zhang, Tao
002b6b95-19d0-45ff-8718-34d4fb927203
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Birdsey, Richard A.
d5f69158-7e8f-4c78-8c5b-a8ccb869137f
Sarmiento, Jorge L.
45f5964b-15e6-43e8-bdd4-8789e2eb87cb
Pacala, Stephen W.
367972eb-6594-4c27-b066-de2a4312f815
Lichstein, Jeremy W., Golaz, Ni Zhang, Malyshev, Sergey, Shevliakova, Elena, Zhang, Tao, Sheffield, Justin, Birdsey, Richard A., Sarmiento, Jorge L. and Pacala, Stephen W.
(2014)
Confronting terrestrial biosphere models with forest inventory data.
Ecological Applications, 24 (4), .
(doi:10.1890/13-0600.1).
Abstract
Efforts to test and improve terrestrial biosphere models (TBMs) using a variety of data sources have become increasingly common. Yet, geographically extensive forest inventories have been under-exploited in previous model-data fusion efforts. Inventory observations of forest growth, mortality, and biomass integrate processes across a range of timescales, including slow timescale processes such as species turnover, that are likely to have important effects on ecosystem responses to environmental variation. However, the large number (thousands) of inventory plots precludes detailed measurements at each location, so that uncertainty in climate, soil properties, and other environmental drivers may be large. Errors in driver variables, if ignored, introduce bias into model-data fusion. We estimated errors in climate and soil drivers at U.S. Forest Inventory and Analysis (FIA) plots, and we explored the effects of these errors on model-data fusion with the Geophysical Fluid Dynamics Laboratory LM3V dynamic global vegetation model. When driver errors were ignored or assumed small at FIA plots, responses of biomass production in LM3V to precipitation and soil available water capacity appeared steeper than the corresponding responses estimated from FIA data. These differences became nonsignificant if driver errors at FIA plots were assumed to be large. Ignoring driver errors when optimizing LM3V parameter values yielded estimates for fine-root allocation that were larger than biometric estimates, which is consistent with the expected direction of bias. To explore whether complications posed by driver errors could be circumvented by relying on intensive study sites where driver errors are small, we performed a power analysis. To accurately quantify the response of biomass production to spatial variation in mean annual precipitation within the eastern United States would require at least 40 intensive study sites, which is larger than the number of sites typically available for individual biomes in existing plot networks. Driver errors may be accommodated by several existing model-data fusion approaches, including hierarchical Bayesian methods and ensemble filtering methods; however, these methods are computationally expensive. We propose a new approach, in which the TBM functional response is fit directly to the driver-error-corrected functional response estimated from data, rather than to the raw observations.
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More information
Published date: June 2014
Keywords:
Carbon cycle model, Data assimilation, Errors in explanatory variables, Global ecosystem model, Land surface model, Measurement error models
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Local EPrints ID: 480784
URI: http://eprints.soton.ac.uk/id/eprint/480784
ISSN: 1051-0761
PURE UUID: 60d46a9d-c12e-45c0-b815-22e2d9ab8892
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Date deposited: 09 Aug 2023 17:13
Last modified: 17 Mar 2024 03:40
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Contributors
Author:
Jeremy W. Lichstein
Author:
Ni Zhang Golaz
Author:
Sergey Malyshev
Author:
Elena Shevliakova
Author:
Tao Zhang
Author:
Richard A. Birdsey
Author:
Jorge L. Sarmiento
Author:
Stephen W. Pacala
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