Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area

Simon Mark Smart; Helen Glanville; Maria del Carmen Blanes; Lina Maria Mercado; Bridget Emmett; Bernard Cosby; David Jones; Robert Hunter Marrs; Adam  Butler; Miles Marshall; Sabine Reinsch; Cristina Herrero-Jauregui; John Gavin Hodgson

doi:10.1111/1365-2435.12832

Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area

Simon Mark Smart
, Helen Glanville
, Maria del Carmen Blanes
, Lina Maria Mercado
, Bridget Emmett
, Bernard Cosby
, David Jones
, Robert Hunter Marrs
, Adam Butler
, Miles Marshall
, Sabine Reinsch
, Cristina Herrero-Jauregui
, John Gavin Hodgson

NERC (Centre for Ecology & Hydrology)
University of Exeter
University of Liverpool
Biomathematics and Statistics Scotland
Universidad Complutense de Madrid
University of Sheffield

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

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Abstract

Reliable modelling of above-ground net primary production (aNPP) at fine resolution is a significant challenge. A promising avenue for improving process models is to include response and effect trait relationships. However, uncertainties remain over which leaf traits are correlated most strongly with aNPP. We compared abundance-weighted values of two of the most widely used traits from the leaf economics spectrum (specific leaf area and leaf dry matter content) with measured aNPP across a temperate ecosystem gradient. We found that leaf dry matter content (LDMC) as opposed to specific leaf area (SLA) was the superior predictor of aNPP (R-2=055). Directly measured insitu trait values for the dominant species improved estimation of aNPP significantly. Introducing intraspecific trait variation by including the effect of replicated trait values from published databases did not improve the estimation of aNPP. Our results support the prospect of greater scientific understanding for less cost because LDMC is much easier to measure than SLA.

Original language	English
Pages (from-to)	1336-1344
Journal	Functional Ecology
Volume	31
Issue number	6
Early online date	2 Jun 2017
DOIs	https://doi.org/10.1111/1365-2435.12832
Publication status	Published - Jun 2017

Keywords

Bayesian modelling; ecosystem function; global change; intraspecific variation; measurement error

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Paper_v10_main_text-3Accepted author manuscript, 613 KB

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Smart, S. M., Glanville, H., del Carmen Blanes, M., Mercado, L. M., Emmett, B., Cosby, B., Jones, D., Marrs, R. H., Butler, A., Marshall, M., Reinsch, S., Herrero-Jauregui, C., & Hodgson, J. G. (2017). Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area. Functional Ecology, 31(6), 1336-1344. https://doi.org/10.1111/1365-2435.12832

@article{5e87eb2be81d42bfa1eef1638aa9d0f0,

title = "Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area",

abstract = "Reliable modelling of above-ground net primary production (aNPP) at fine resolution is a significant challenge. A promising avenue for improving process models is to include response and effect trait relationships. However, uncertainties remain over which leaf traits are correlated most strongly with aNPP. We compared abundance-weighted values of two of the most widely used traits from the leaf economics spectrum (specific leaf area and leaf dry matter content) with measured aNPP across a temperate ecosystem gradient. We found that leaf dry matter content (LDMC) as opposed to specific leaf area (SLA) was the superior predictor of aNPP (R-2=055). Directly measured insitu trait values for the dominant species improved estimation of aNPP significantly. Introducing intraspecific trait variation by including the effect of replicated trait values from published databases did not improve the estimation of aNPP. Our results support the prospect of greater scientific understanding for less cost because LDMC is much easier to measure than SLA. ",

keywords = "Bayesian modelling; ecosystem function; global change; intraspecific variation; measurement error ",

author = "Smart, \{Simon Mark\} and Helen Glanville and \{del Carmen Blanes\}, Maria and Mercado, \{Lina Maria\} and Bridget Emmett and Bernard Cosby and David Jones and Marrs, \{Robert Hunter\} and Adam Butler and Miles Marshall and Sabine Reinsch and Cristina Herrero-Jauregui and Hodgson, \{John Gavin\}",

year = "2017",

month = jun,

doi = "10.1111/1365-2435.12832",

language = "English",

volume = "31",

pages = "1336--1344",

journal = "Functional Ecology",

issn = "0269-8463",

publisher = "Wiley-Blackwell",

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Smart, SM, Glanville, H, del Carmen Blanes, M, Mercado, LM, Emmett, B, Cosby, B, Jones, D, Marrs, RH, Butler, A, Marshall, M, Reinsch, S, Herrero-Jauregui, C & Hodgson, JG 2017, 'Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area', Functional Ecology, vol. 31, no. 6, pp. 1336-1344. https://doi.org/10.1111/1365-2435.12832

TY - JOUR

T1 - Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area

AU - Smart, Simon Mark

AU - Glanville, Helen

AU - del Carmen Blanes, Maria

AU - Mercado, Lina Maria

AU - Emmett, Bridget

AU - Cosby, Bernard

AU - Jones, David

AU - Marrs, Robert Hunter

AU - Butler, Adam

AU - Marshall, Miles

AU - Reinsch, Sabine

AU - Herrero-Jauregui, Cristina

AU - Hodgson, John Gavin

PY - 2017/6

Y1 - 2017/6

N2 - Reliable modelling of above-ground net primary production (aNPP) at fine resolution is a significant challenge. A promising avenue for improving process models is to include response and effect trait relationships. However, uncertainties remain over which leaf traits are correlated most strongly with aNPP. We compared abundance-weighted values of two of the most widely used traits from the leaf economics spectrum (specific leaf area and leaf dry matter content) with measured aNPP across a temperate ecosystem gradient. We found that leaf dry matter content (LDMC) as opposed to specific leaf area (SLA) was the superior predictor of aNPP (R-2=055). Directly measured insitu trait values for the dominant species improved estimation of aNPP significantly. Introducing intraspecific trait variation by including the effect of replicated trait values from published databases did not improve the estimation of aNPP. Our results support the prospect of greater scientific understanding for less cost because LDMC is much easier to measure than SLA.

AB - Reliable modelling of above-ground net primary production (aNPP) at fine resolution is a significant challenge. A promising avenue for improving process models is to include response and effect trait relationships. However, uncertainties remain over which leaf traits are correlated most strongly with aNPP. We compared abundance-weighted values of two of the most widely used traits from the leaf economics spectrum (specific leaf area and leaf dry matter content) with measured aNPP across a temperate ecosystem gradient. We found that leaf dry matter content (LDMC) as opposed to specific leaf area (SLA) was the superior predictor of aNPP (R-2=055). Directly measured insitu trait values for the dominant species improved estimation of aNPP significantly. Introducing intraspecific trait variation by including the effect of replicated trait values from published databases did not improve the estimation of aNPP. Our results support the prospect of greater scientific understanding for less cost because LDMC is much easier to measure than SLA.

KW - Bayesian modelling; ecosystem function; global change; intraspecific variation; measurement error

U2 - 10.1111/1365-2435.12832

DO - 10.1111/1365-2435.12832

M3 - Article

SN - 0269-8463

VL - 31

SP - 1336

EP - 1344

JO - Functional Ecology

JF - Functional Ecology

IS - 6

ER -

Leaf dry matter content is better at predicting above-ground net primary production than specific leaf area

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