Ecosystem-scale measurements of biomass water using cosmic ray neutrons

Trenton E. Franz; Marek Zreda; Rafael Rosolem; Brian K. Hornbuckle; Samantha L. Irvin; Henry Adams; Thomas E. Kolb; Chris Zweck; W. James Shuttleworth

doi:10.1002/grl.50791

Ecosystem-scale measurements of biomass water using cosmic ray neutrons

Trenton E. Franz, Marek Zreda, Rafael Rosolem, Brian K. Hornbuckle, Samantha L. Irvin, Henry Adams, Thomas E. Kolb, Chris Zweck, W. James Shuttleworth

Daugherty Water for Food Global Institute

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

57 Scopus citations

Abstract

Accurate estimates of biomass are imperative for understanding the global carbon cycle. However, measurements of biomass and water in the biomass are difficult to obtain at a scale consistent with measurements of mass and energy transfer, ∼1 km, leading to substantial uncertainty in dynamic global vegetation models. Here we use a novel cosmic ray neutron method to estimate a stoichiometric predictor of ecosystem-scale biomass and biomass water equivalent over tens of hectares. We present two experimental studies, one in a ponderosa pine forest and the other in a maize field, where neutron-derived estimates of biomass water equivalent are compared and found consistent with direct observations. Given the new hectometer scale of nondestructive observation and potential for continuous measurements, we anticipate this technique to be useful to many scientific disciplines.

Original language	English (US)
Pages (from-to)	3929-3933
Number of pages	5
Journal	Geophysical Research Letters
Volume	40
Issue number	15
DOIs	https://doi.org/10.1002/grl.50791
State	Published - Aug 16 2013

Keywords

biomass
cosmic ray neutrons
large scale

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

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10.1002/grl.50791

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title = "Ecosystem-scale measurements of biomass water using cosmic ray neutrons",

abstract = "Accurate estimates of biomass are imperative for understanding the global carbon cycle. However, measurements of biomass and water in the biomass are difficult to obtain at a scale consistent with measurements of mass and energy transfer, ∼1 km, leading to substantial uncertainty in dynamic global vegetation models. Here we use a novel cosmic ray neutron method to estimate a stoichiometric predictor of ecosystem-scale biomass and biomass water equivalent over tens of hectares. We present two experimental studies, one in a ponderosa pine forest and the other in a maize field, where neutron-derived estimates of biomass water equivalent are compared and found consistent with direct observations. Given the new hectometer scale of nondestructive observation and potential for continuous measurements, we anticipate this technique to be useful to many scientific disciplines.",

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T1 - Ecosystem-scale measurements of biomass water using cosmic ray neutrons

AU - Franz, Trenton E.

AU - Zreda, Marek

AU - Rosolem, Rafael

AU - Hornbuckle, Brian K.

AU - Irvin, Samantha L.

AU - Adams, Henry

AU - Kolb, Thomas E.

AU - Zweck, Chris

AU - Shuttleworth, W. James

PY - 2013/8/16

Y1 - 2013/8/16

N2 - Accurate estimates of biomass are imperative for understanding the global carbon cycle. However, measurements of biomass and water in the biomass are difficult to obtain at a scale consistent with measurements of mass and energy transfer, ∼1 km, leading to substantial uncertainty in dynamic global vegetation models. Here we use a novel cosmic ray neutron method to estimate a stoichiometric predictor of ecosystem-scale biomass and biomass water equivalent over tens of hectares. We present two experimental studies, one in a ponderosa pine forest and the other in a maize field, where neutron-derived estimates of biomass water equivalent are compared and found consistent with direct observations. Given the new hectometer scale of nondestructive observation and potential for continuous measurements, we anticipate this technique to be useful to many scientific disciplines.

AB - Accurate estimates of biomass are imperative for understanding the global carbon cycle. However, measurements of biomass and water in the biomass are difficult to obtain at a scale consistent with measurements of mass and energy transfer, ∼1 km, leading to substantial uncertainty in dynamic global vegetation models. Here we use a novel cosmic ray neutron method to estimate a stoichiometric predictor of ecosystem-scale biomass and biomass water equivalent over tens of hectares. We present two experimental studies, one in a ponderosa pine forest and the other in a maize field, where neutron-derived estimates of biomass water equivalent are compared and found consistent with direct observations. Given the new hectometer scale of nondestructive observation and potential for continuous measurements, we anticipate this technique to be useful to many scientific disciplines.

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KW - cosmic ray neutrons

KW - large scale

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Ecosystem-scale measurements of biomass water using cosmic ray neutrons

Abstract

Keywords

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