African savanna-forest boundary dynamics: a 20-year study

Aida Cuni Sanchez; Lee J. T. White; Kim Calders; Kathryn J. Jeffery; Katharine Abernethy; Andrew Burt; Mathias Disney; Martin Gilpin; Jose L. Gomez-Dans; Simon L. Lewis

doi:10.1371/journal.pone.0156934

African savanna-forest boundary dynamics: a 20-year study

Aida Cuni Sanchez, Lee J. T. White, Kim Calders, Kathryn J. Jeffery, Katharine Abernethy, Andrew Burt, Mathias Disney, Martin Gilpin, Jose L. Gomez-Dans, Simon L. Lewis

30 Citationer (Scopus)

63 Downloads (Pure)

Abstract

Recent studies show widespread encroachment of forest into savannas with important consequences for the global carbon cycle and land-atmosphere interactions. However, little research has focused on in situ measurements of the successional sequence of savanna to forest in Africa. Using long-term inventory plots we quantify changes in vegetation structure, above-ground biomass (AGB) and biodiversity of trees ≥10 cm diameter over 20 years for five vegetation types: savanna; colonising forest (F1), monodominant Okoume forest (F2); young Marantaceae forest (F3); and mixed Marantaceae forest (F4) in Lopé National Park, central Gabon, plus novel 3D terrestrial laser scanning (TLS) measurements to assess forest structure differences. Over 20 years no plot changed to a new stage in the putative succession, but F1 forests strongly moved towards the structure, AGB and diversity of F2 forests. Overall, savanna plots showed no detectable change in structure, AGB or diversity using this method, with zero trees ≥10 cm diameter in 1993 and 2013. F1 and F2 forests increased in AGB, mainly as a result of adding recruited stems (F1) and increased Basal Area (F2), whereas F3 and F4 forests did not change substantially in structure, AGB or diversity. Critically, the stability of the F3 stage implies that this stage may be maintained for long periods. Soil carbon was low, and did not show a successional gradient as for AGB and diversity. TLS vertical plant profiles showed distinctive differences amongst the vegetation types, indicating that this technique can improve ecological understanding. We highlight two points: (i) as forest colonises, changes in biodiversity are much slower than changes in forest structure or AGB; and (ii) all forest types store substantial quantities of carbon. Multidecadal monitoring is likely to be required to assess the speed of transition between vegetation types.

Originalsprog	Engelsk
Artikelnummer	e0156934
Tidsskrift	P L o S One
Vol/bind	11
Udgave nummer	6
Antal sider	23
ISSN	1932-6203
DOI	https://doi.org/10.1371/journal.pone.0156934
Status	Udgivet - 2016

FN’s Verdensmål

Dette resultat bidrager til følgende verdensmål

Adgang til dokumentet

10.1371/journal.pone.0156934Licens: CC BY

Cuni-Sanchez_2016_African_Savanna-ForestForlagets udgivne version, 2,54 MBLicens: CC BY

Andre filer og links

Link to publication in Scopus

Citationsformater

@article{5307745760824f62abbaf80e7773af66,

title = "African savanna-forest boundary dynamics: a 20-year study",

abstract = "Recent studies show widespread encroachment of forest into savannas with important consequences for the global carbon cycle and land-atmosphere interactions. However, little research has focused on in situ measurements of the successional sequence of savanna to forest in Africa. Using long-term inventory plots we quantify changes in vegetation structure, above-ground biomass (AGB) and biodiversity of trees ≥10 cm diameter over 20 years for five vegetation types: savanna; colonising forest (F1), monodominant Okoume forest (F2); young Marantaceae forest (F3); and mixed Marantaceae forest (F4) in Lop{\'e} National Park, central Gabon, plus novel 3D terrestrial laser scanning (TLS) measurements to assess forest structure differences. Over 20 years no plot changed to a new stage in the putative succession, but F1 forests strongly moved towards the structure, AGB and diversity of F2 forests. Overall, savanna plots showed no detectable change in structure, AGB or diversity using this method, with zero trees ≥10 cm diameter in 1993 and 2013. F1 and F2 forests increased in AGB, mainly as a result of adding recruited stems (F1) and increased Basal Area (F2), whereas F3 and F4 forests did not change substantially in structure, AGB or diversity. Critically, the stability of the F3 stage implies that this stage may be maintained for long periods. Soil carbon was low, and did not show a successional gradient as for AGB and diversity. TLS vertical plant profiles showed distinctive differences amongst the vegetation types, indicating that this technique can improve ecological understanding. We highlight two points: (i) as forest colonises, changes in biodiversity are much slower than changes in forest structure or AGB; and (ii) all forest types store substantial quantities of carbon. Multidecadal monitoring is likely to be required to assess the speed of transition between vegetation types.",

author = "{Cuni Sanchez}, Aida and White, {Lee J. T.} and Kim Calders and Jeffery, {Kathryn J.} and Katharine Abernethy and Andrew Burt and Mathias Disney and Martin Gilpin and Gomez-Dans, {Jose L.} and Lewis, {Simon L.}",

year = "2016",

doi = "10.1371/journal.pone.0156934",

language = "English",

volume = "11",

journal = "PLoS Computational Biology",

issn = "1932-6203",

publisher = "Public Library of Science",

number = "6",

}

TY - JOUR

T1 - African savanna-forest boundary dynamics

T2 - a 20-year study

AU - Cuni Sanchez, Aida

AU - White, Lee J. T.

AU - Calders, Kim

AU - Jeffery, Kathryn J.

AU - Abernethy, Katharine

AU - Burt, Andrew

AU - Disney, Mathias

AU - Gilpin, Martin

AU - Gomez-Dans, Jose L.

AU - Lewis, Simon L.

PY - 2016

Y1 - 2016

N2 - Recent studies show widespread encroachment of forest into savannas with important consequences for the global carbon cycle and land-atmosphere interactions. However, little research has focused on in situ measurements of the successional sequence of savanna to forest in Africa. Using long-term inventory plots we quantify changes in vegetation structure, above-ground biomass (AGB) and biodiversity of trees ≥10 cm diameter over 20 years for five vegetation types: savanna; colonising forest (F1), monodominant Okoume forest (F2); young Marantaceae forest (F3); and mixed Marantaceae forest (F4) in Lopé National Park, central Gabon, plus novel 3D terrestrial laser scanning (TLS) measurements to assess forest structure differences. Over 20 years no plot changed to a new stage in the putative succession, but F1 forests strongly moved towards the structure, AGB and diversity of F2 forests. Overall, savanna plots showed no detectable change in structure, AGB or diversity using this method, with zero trees ≥10 cm diameter in 1993 and 2013. F1 and F2 forests increased in AGB, mainly as a result of adding recruited stems (F1) and increased Basal Area (F2), whereas F3 and F4 forests did not change substantially in structure, AGB or diversity. Critically, the stability of the F3 stage implies that this stage may be maintained for long periods. Soil carbon was low, and did not show a successional gradient as for AGB and diversity. TLS vertical plant profiles showed distinctive differences amongst the vegetation types, indicating that this technique can improve ecological understanding. We highlight two points: (i) as forest colonises, changes in biodiversity are much slower than changes in forest structure or AGB; and (ii) all forest types store substantial quantities of carbon. Multidecadal monitoring is likely to be required to assess the speed of transition between vegetation types.

AB - Recent studies show widespread encroachment of forest into savannas with important consequences for the global carbon cycle and land-atmosphere interactions. However, little research has focused on in situ measurements of the successional sequence of savanna to forest in Africa. Using long-term inventory plots we quantify changes in vegetation structure, above-ground biomass (AGB) and biodiversity of trees ≥10 cm diameter over 20 years for five vegetation types: savanna; colonising forest (F1), monodominant Okoume forest (F2); young Marantaceae forest (F3); and mixed Marantaceae forest (F4) in Lopé National Park, central Gabon, plus novel 3D terrestrial laser scanning (TLS) measurements to assess forest structure differences. Over 20 years no plot changed to a new stage in the putative succession, but F1 forests strongly moved towards the structure, AGB and diversity of F2 forests. Overall, savanna plots showed no detectable change in structure, AGB or diversity using this method, with zero trees ≥10 cm diameter in 1993 and 2013. F1 and F2 forests increased in AGB, mainly as a result of adding recruited stems (F1) and increased Basal Area (F2), whereas F3 and F4 forests did not change substantially in structure, AGB or diversity. Critically, the stability of the F3 stage implies that this stage may be maintained for long periods. Soil carbon was low, and did not show a successional gradient as for AGB and diversity. TLS vertical plant profiles showed distinctive differences amongst the vegetation types, indicating that this technique can improve ecological understanding. We highlight two points: (i) as forest colonises, changes in biodiversity are much slower than changes in forest structure or AGB; and (ii) all forest types store substantial quantities of carbon. Multidecadal monitoring is likely to be required to assess the speed of transition between vegetation types.

UR - http://www.scopus.com/inward/record.url?scp=84976641641&partnerID=8YFLogxK

U2 - 10.1371/journal.pone.0156934

DO - 10.1371/journal.pone.0156934

M3 - Journal article

C2 - 27336632

AN - SCOPUS:84976641641

SN - 1932-6203

VL - 11

JO - PLoS Computational Biology

JF - PLoS Computational Biology

IS - 6

M1 - e0156934

ER -

African savanna-forest boundary dynamics: a 20-year study

Abstract

FN’s Verdensmål

Adgang til dokumentet

Andre filer og links

Fingeraftryk

Citationsformater