Pregled bibliografske jedinice broj: 1219648
Soil C:N stoichiometry controls carbon sink partitioning between above-ground tree biomass and soil organic matter in high fertility forests
Soil C:N stoichiometry controls carbon sink partitioning between above-ground tree biomass and soil organic matter in high fertility forests // iForest - Biogeosciences and Forestry, 8 (2015), 2; 195-206 doi:10.3832/ifor1196-008 (međunarodna recenzija, članak, znanstveni)
CROSBI ID: 1219648 Za ispravke kontaktirajte CROSBI podršku putem web obrasca
Naslov
Soil C:N stoichiometry controls carbon sink partitioning between above-ground tree biomass and soil organic matter in high fertility forests
Autori
Alberti, G ; Vicca, S ; Inglima, I ; Belelli-Marchesini, L ; Genesio, L ; Miglietta, F ; Marjanović, H ; Martinez, C ; Matteucci, G ; D’Andrea, E ; Peressotti, A ; Petrella, F ; Rodeghiero, M ; Cotrufo, MF
Izvornik
IForest - Biogeosciences and Forestry (1971-7458) 8
(2015), 2;
195-206
Vrsta, podvrsta i kategorija rada
Radovi u časopisima, članak, znanstveni
Ključne riječi
Net Root-derived Carbon ; Ingrowth Cores ; Soil C:N ; Carbon Sequestration ; Carbon Partitioning ; Isotopes
Sažetak
The release of organic compounds from roots is a key process influencing soil carbon (C) dynamics and nutrient availability in terrestrial ecosystems. Through this process, plants stimulate microbial activity and soil organic matter (SOM) mineralization thus releasing nitrogen (N) that sustains gross and net primary production (GPP and NPP, respectively). Root inputs also contribute to SOM formation. In this study, we quantified the annual net root-derived C input to soil (Net-Croot) across six high fertility forests using an in-growth core isotope technique. On the basis of Net-Croot, wood and coarse root biomass changes, and eddy covariance data, we quantified net belowground C sequestration. Belowground C accumulation and GPP were inversely related to soil C:N, but not to climate or stand age. Soil C content and C:N were also related to soil texture. At these high fertility sites, biomass growth did not change with soil C:N ; however, biomass growth-to-GPP ratio significantly increased with increasing soil C:N. This was true for both our six forest sites and for another 23 high fertility sites selected at a global scale. We suggest that, at high fertility sites, plant N demand interacts with soil C:N stoichiometry and microbial activity, resulting in higher allocation of C to above ground tree biomass with increasing soil C:N ratio. When C:N is high, microbes have a low C use efficiency, respire more of the fresh C inputs by roots and prime SOM decomposition, thereby increasing N availability for tree uptake. Soil C sequestration would therefore decrease, whereas the extra N released during SOM decomposition can promote tree growth and ecosystem C sink allocation in aboveground biomass. Conversely, C is sequestered in soil when low soil C:N promotes microbial C use efficiency and new SOM formation and stabilization on clay particles.
Izvorni jezik
Engleski
Znanstvena područja
Biologija, Geofizika, Šumarstvo, Interdisciplinarne biotehničke znanosti
POVEZANOST RADA
Ustanove:
Hrvatski šumarski institut, Jastrebarsko
Profili:
Hrvoje Marjanović
(autor)
Citiraj ovu publikaciju:
Časopis indeksira:
- Current Contents Connect (CCC)
- Web of Science Core Collection (WoSCC)
- Science Citation Index Expanded (SCI-EXP)
- SCI-EXP, SSCI i/ili A&HCI
- Scopus
