Details
| Originalsprache | Englisch |
|---|---|
| Seiten (von - bis) | 167-189 |
| Seitenumfang | 23 |
| Fachzeitschrift | BIOGEOCHEMISTRY |
| Jahrgang | 136 |
| Ausgabenummer | 2 |
| Frühes Online-Datum | 12 Okt. 2017 |
| Publikationsstatus | Veröffentlicht - Nov. 2017 |
Abstract
To assess the susceptibility of the base metal budget of a remote tropical montane forest in Ecuador to environmental change, we determined the extent of biological control of base metal fluxes and explored the impact of atmospheric inputs and precipitation, considered as potential drivers of ecosystem change, on the base metal fluxes. We quantified all major base metal fluxes in a ca. 9.1 ha forested catchment from 1998 to 2013. Mean (±s.d.) annual flux to the soil via throughfall + stemflow + litterfall was 13800 ± 1500 mg m −2 Ca, 19000 ± 1510 mg m −2 K, 4690 ± 619 mg m −2 Mg and 846 ± 592 mg m −2 Na of which 22 ± 6, 45 ± 16, 39 ± 10 and 84 ± 33%, respectively, were leached to below the organic layer. The mineral soil retained 79–94% of this Ca, K and Mg, while Na was released. Weathering rates estimated with three different approaches ranged from not detected (ND) to 504 mg m −2 year −1 Ca, ND-1770 mg m −2 year −1 K, 287–597 mg m −2 year −1 Mg and 403–540 mg m −2 year −1 Na. The size of mainly biologically controlled aboveground fluxes of Ca, K and Mg was 1–2 orders of magnitude larger than that of mainly geochemically controlled fluxes (sorption to soil and weathering). The elemental catchment budgets (total deposition − streamflow) were positive for Ca (574 ± 893 mg m −2) and K (1330 ± 773 mg m −2), negative for Na (−370 ± 1300 mg m −2) and neutral for Mg (1.89 ± 304 mg m −2). Our results demonstrate that biological processes controlled element retention for Ca, K and Mg in the biological part of the ecosystem. This was different for Na, which was mainly released by weathering from the study catchment, while the biological part of the ecosystem was Na-poor. The deposition of base metals was the strongest driver of their budgets suggesting that the base metal cycling of the study ecosystem is susceptible to changing deposition.
ASJC Scopus Sachgebiete
- Umweltwissenschaften (insg.)
- Umweltchemie
- Umweltwissenschaften (insg.)
- Gewässerkunde und -technologie
- Erdkunde und Planetologie (insg.)
- Erdoberflächenprozesse
Zitieren
- Standard
- Harvard
- Apa
- Vancouver
- BibTex
- RIS
in: BIOGEOCHEMISTRY, Jahrgang 136, Nr. 2, 11.2017, S. 167-189.
Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review
}
TY - JOUR
T1 - Biological versus geochemical control and environmental change drivers of the base metal budgets of a tropical montane forest in Ecuador during 15 years
AU - Wilcke, Wolfgang
AU - Velescu, Andre
AU - Leimer, Sophia
AU - Bigalke, Moritz
AU - Boy, Jens
AU - Valarezo, Carlos
N1 - Funding information: We thank E. Beck, K. Müller-Hohenstein, M. Richter and W. Zech for co-initiating the long-term study; K. Fleischbein, R. Goller, M. Meyer-Grünefeldt, M. Sequeira, H. Wullaert, S. Yasin and numerous undergraduate students for data acquisition during parts of the observation period; W. Schädler for providing RFA data of soil macro element concentrations; Thomas Bartsch and Alexander Hermann for drawing Fig. 1; the Ecuadorian Environmental Ministry for the research permits; Naturaleza y Cultura Internacional (NCI) in Loja for providing the study area and the research station and the Deutsche Forschungsgemeinschaft (DFG) for funding (FOR 402 and 816). Furthermore, we thank two anonymous reviewers for their valuable comments, which helped us to improve the paper considerably.
PY - 2017/11
Y1 - 2017/11
N2 - To assess the susceptibility of the base metal budget of a remote tropical montane forest in Ecuador to environmental change, we determined the extent of biological control of base metal fluxes and explored the impact of atmospheric inputs and precipitation, considered as potential drivers of ecosystem change, on the base metal fluxes. We quantified all major base metal fluxes in a ca. 9.1 ha forested catchment from 1998 to 2013. Mean (±s.d.) annual flux to the soil via throughfall + stemflow + litterfall was 13800 ± 1500 mg m −2 Ca, 19000 ± 1510 mg m −2 K, 4690 ± 619 mg m −2 Mg and 846 ± 592 mg m −2 Na of which 22 ± 6, 45 ± 16, 39 ± 10 and 84 ± 33%, respectively, were leached to below the organic layer. The mineral soil retained 79–94% of this Ca, K and Mg, while Na was released. Weathering rates estimated with three different approaches ranged from not detected (ND) to 504 mg m −2 year −1 Ca, ND-1770 mg m −2 year −1 K, 287–597 mg m −2 year −1 Mg and 403–540 mg m −2 year −1 Na. The size of mainly biologically controlled aboveground fluxes of Ca, K and Mg was 1–2 orders of magnitude larger than that of mainly geochemically controlled fluxes (sorption to soil and weathering). The elemental catchment budgets (total deposition − streamflow) were positive for Ca (574 ± 893 mg m −2) and K (1330 ± 773 mg m −2), negative for Na (−370 ± 1300 mg m −2) and neutral for Mg (1.89 ± 304 mg m −2). Our results demonstrate that biological processes controlled element retention for Ca, K and Mg in the biological part of the ecosystem. This was different for Na, which was mainly released by weathering from the study catchment, while the biological part of the ecosystem was Na-poor. The deposition of base metals was the strongest driver of their budgets suggesting that the base metal cycling of the study ecosystem is susceptible to changing deposition.
AB - To assess the susceptibility of the base metal budget of a remote tropical montane forest in Ecuador to environmental change, we determined the extent of biological control of base metal fluxes and explored the impact of atmospheric inputs and precipitation, considered as potential drivers of ecosystem change, on the base metal fluxes. We quantified all major base metal fluxes in a ca. 9.1 ha forested catchment from 1998 to 2013. Mean (±s.d.) annual flux to the soil via throughfall + stemflow + litterfall was 13800 ± 1500 mg m −2 Ca, 19000 ± 1510 mg m −2 K, 4690 ± 619 mg m −2 Mg and 846 ± 592 mg m −2 Na of which 22 ± 6, 45 ± 16, 39 ± 10 and 84 ± 33%, respectively, were leached to below the organic layer. The mineral soil retained 79–94% of this Ca, K and Mg, while Na was released. Weathering rates estimated with three different approaches ranged from not detected (ND) to 504 mg m −2 year −1 Ca, ND-1770 mg m −2 year −1 K, 287–597 mg m −2 year −1 Mg and 403–540 mg m −2 year −1 Na. The size of mainly biologically controlled aboveground fluxes of Ca, K and Mg was 1–2 orders of magnitude larger than that of mainly geochemically controlled fluxes (sorption to soil and weathering). The elemental catchment budgets (total deposition − streamflow) were positive for Ca (574 ± 893 mg m −2) and K (1330 ± 773 mg m −2), negative for Na (−370 ± 1300 mg m −2) and neutral for Mg (1.89 ± 304 mg m −2). Our results demonstrate that biological processes controlled element retention for Ca, K and Mg in the biological part of the ecosystem. This was different for Na, which was mainly released by weathering from the study catchment, while the biological part of the ecosystem was Na-poor. The deposition of base metals was the strongest driver of their budgets suggesting that the base metal cycling of the study ecosystem is susceptible to changing deposition.
KW - Acid deposition
KW - Alkaline dust deposition
KW - Catchment budget
KW - Litterfall
KW - Stemflow
KW - Streamflow
KW - Throughfall
KW - Weathering rates
UR - http://www.scopus.com/inward/record.url?scp=85031429215&partnerID=8YFLogxK
U2 - 10.1007/s10533-017-0386-x
DO - 10.1007/s10533-017-0386-x
M3 - Article
VL - 136
SP - 167
EP - 189
JO - BIOGEOCHEMISTRY
JF - BIOGEOCHEMISTRY
SN - 0168-2563
IS - 2
ER -