Limited capacity of tree growth to mitigate the global greenhouse effect under predicted warming

Abstract

AbstractIt is generally accepted that animal heartbeat and lifespan are often inversely correlated, however, the relationship between productivity and longevity has not yet been described for trees growing under industrial and pre-industrial climates. Using 1768 annually resolved and absolutely dated ring width measurement series from living and dead conifers that grew in undisturbed, high-elevation sites in the Spanish Pyrenees and the Russian Altai over the past 2000 years, we test the hypothesis of grow fast—die young. We find maximum tree ages are significantly correlated with slow juvenile growth rates. We conclude, the interdependence between higher stem productivity, faster tree turnover, and shorter carbon residence time, reduces the capacity of forest ecosystems to store carbon under a climate warming-induced stimulation of tree growth at policy-relevant timescales.

Autoren

Ulf Büntgen
Paul J Krusic
Alma Piermattei
David A Coomes
Jan Esper
Vladimir S Myglan
Alexander V Kirdyanov
J Julio Camarero
Alan Crivellaro
Christian Körner

DOI

10.1038/s41467-019-10174-4

eISSN

2041-1723

Ausgabe der Veröffentlichung

1

Zeitschrift

Nature Communications

Sprache

en

Artikelnummer

2171

Online publication date

2019

Status

Published online

Herausgeber

Springer Science and Business Media LLC

Herausgeber URL

http://dx.doi.org/10.1038/s41467-019-10174-4

Datum der Datenerfassung

2022

Titel

Limited capacity of tree growth to mitigate the global greenhouse effect under predicted warming

Ausgabe der Zeitschrift

10

Datenquelle: Crossref

Abstract

It is generally accepted that animal heartbeat and lifespan are often inversely correlated, however, the relationship between productivity and longevity has not yet been described for trees growing under industrial and pre-industrial climates. Using 1768 annually resolved and absolutely dated ring width measurement series from living and dead conifers that grew in undisturbed, high-elevation sites in the Spanish Pyrenees and the Russian Altai over the past 2000 years, we test the hypothesis of grow fast-die young. We find maximum tree ages are significantly correlated with slow juvenile growth rates. We conclude, the interdependence between higher stem productivity, faster tree turnover, and shorter carbon residence time, reduces the capacity of forest ecosystems to store carbon under a climate warming-induced stimulation of tree growth at policy-relevant timescales.

Addresses

Department of Geography, University of Cambridge, Cambridge, CB2 3EN, UK. ulf.buentgen@geog.cam.ac.uk.

Autoren

Ulf Büntgen
Paul J Krusic
Alma Piermattei
David A Coomes
Jan Esper
Vladimir S Myglan
Alexander V Kirdyanov
J Julio Camarero
Alan Crivellaro
Christian Körner

DOI

10.1038/s41467-019-10174-4

eISSN

2041-1723

Externe Identifier

PubMed Identifier: 31092831
PubMed Central ID: PMC6520339

Open access

true

ISSN

2041-1723

Ausgabe der Veröffentlichung

1

Zeitschrift

Nature communications

Sprache

eng

Medium

Electronic

Online publication date

2019

Open access status

Open Access

Paginierung

2171

Datum der Veröffentlichung

2019

Status

Published

Publisher licence

CC BY

Datum der Datenerfassung

2019

Titel

Limited capacity of tree growth to mitigate the global greenhouse effect under predicted warming.

Sub types

Research Support, Non-U.S. Gov't
research-article
Journal Article

Ausgabe der Zeitschrift

10

Files

https://www.nature.com/articles/s41467-019-10174-4.pdf https://europepmc.org/articles/PMC6520339?pdf=render

Datenquelle: Europe PubMed Central

Abstract

It is generally accepted that animal heartbeat and lifespan are often inversely correlated, however, the relationship between productivity and longevity has not yet been described for trees growing under industrial and pre-industrial climates. Using 1768 annually resolved and absolutely dated ring width measurement series from living and dead conifers that grew in undisturbed, high-elevation sites in the Spanish Pyrenees and the Russian Altai over the past 2000 years, we test the hypothesis of grow fast-die young. We find maximum tree ages are significantly correlated with slow juvenile growth rates. We conclude, the interdependence between higher stem productivity, faster tree turnover, and shorter carbon residence time, reduces the capacity of forest ecosystems to store carbon under a climate warming-induced stimulation of tree growth at policy-relevant timescales.

Date of acceptance

2019

Autoren

Ulf Büntgen
Paul J Krusic
Alma Piermattei
David A Coomes
Jan Esper
Vladimir S Myglan
Alexander V Kirdyanov
J Julio Camarero
Alan Crivellaro
Christian Körner

Autoren-URL

https://www.ncbi.nlm.nih.gov/pubmed/31092831

DOI

10.1038/s41467-019-10174-4

eISSN

2041-1723

Externe Identifier

PubMed Central ID: PMC6520339

Ausgabe der Veröffentlichung

1

Zeitschrift

Nat Commun

Sprache

eng

Country

England

Paginierung

2171

PII

10.1038/s41467-019-10174-4

Datum der Veröffentlichung

2019

Status

Published online

Titel

Limited capacity of tree growth to mitigate the global greenhouse effect under predicted warming.

Sub types

Journal Article
Research Support, Non-U.S. Gov't

Ausgabe der Zeitschrift

10

Datenquelle: PubMed

Limited capacity of tree growth to mitigate the global greenhouse effect under predicted warming

Files

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