TY - JOUR
T1 - Responses of particulate and mineral-associated organic carbon to temperature changes and their mineral protection mechanisms
T2 - A soil translocation experiment
AU - Li, Jingjing
AU - He, Liyuan
AU - Wang, Jieying
AU - Zhao, Xue
AU - Chen, Ji
AU - Ren, Chengjie
AU - Wang, Jun
AU - Guo, Yaoxin
AU - Zhao, Fazhu
N1 - Publisher Copyright:
© 2024 Elsevier B.V.
PY - 2024/10/20
Y1 - 2024/10/20
N2 - Mineral protection mechanisms are important in determining the response of particulate organic carbon (POC) and mineral-associated organic carbon (MAOC) to temperature changes. However, the underlying mechanisms for how POC and MAOC respond to temperature changes are remain unclear. By translocating soils across 1304 m, 1425 m and 2202 m elevation gradient in a temperate forest, simulate nine months of warming (with soil temperature change of +1.41 °C and +3.91 °C) and cooling (with soil temperature change of −1.86 °C and −4.20 °C), we found that warming translocation significantly decreased POC by an average of 10.84 %, but increased MAOC by an average of 4.25 %. Conversely, cooling translocation led to an average increase of 8.64 % in POC and 13.48 % in MAOC. Exchangeable calcium (Caexe) had a significant positive correlation with POC and MAOC during temperature changes, and Fe/Al-(hydr)oxides had no significant correlation or a significant negative correlation with POC and MAOC. Our results showed that POC was more sensitive than MAOC to temperature changes. Caexe mediated the stability of POC and MAOC under temperature changes, and Fe/Al-(hydr)oxides had no obvious protective effect on POC and MAOC. Our results support the role of mineral protection in the stabilization mechanism of POC and MAOC in response to climate change and are critical for understanding the consequences of global change on soil organic carbon (SOC) dynamics.
AB - Mineral protection mechanisms are important in determining the response of particulate organic carbon (POC) and mineral-associated organic carbon (MAOC) to temperature changes. However, the underlying mechanisms for how POC and MAOC respond to temperature changes are remain unclear. By translocating soils across 1304 m, 1425 m and 2202 m elevation gradient in a temperate forest, simulate nine months of warming (with soil temperature change of +1.41 °C and +3.91 °C) and cooling (with soil temperature change of −1.86 °C and −4.20 °C), we found that warming translocation significantly decreased POC by an average of 10.84 %, but increased MAOC by an average of 4.25 %. Conversely, cooling translocation led to an average increase of 8.64 % in POC and 13.48 % in MAOC. Exchangeable calcium (Caexe) had a significant positive correlation with POC and MAOC during temperature changes, and Fe/Al-(hydr)oxides had no significant correlation or a significant negative correlation with POC and MAOC. Our results showed that POC was more sensitive than MAOC to temperature changes. Caexe mediated the stability of POC and MAOC under temperature changes, and Fe/Al-(hydr)oxides had no obvious protective effect on POC and MAOC. Our results support the role of mineral protection in the stabilization mechanism of POC and MAOC in response to climate change and are critical for understanding the consequences of global change on soil organic carbon (SOC) dynamics.
KW - Mineral protection
KW - Mineral-associated organic carbon
KW - Particulate organic carbon
KW - Soil translocation
KW - Temperate forests
UR - http://www.scopus.com/inward/record.url?scp=85199004624&partnerID=8YFLogxK
U2 - 10.1016/j.scitotenv.2024.174689
DO - 10.1016/j.scitotenv.2024.174689
M3 - Article
C2 - 38992385
AN - SCOPUS:85199004624
SN - 0048-9697
VL - 948
JO - Science of the Total Environment
JF - Science of the Total Environment
M1 - 174689
ER -