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Long-term soil warming decreases microbial phosphorus utilization by increasing abiotic phosphorus sorption and phosphorus losses.
Published in:
Nature Communications, 2023, v. 14, n. 1, p. 1, doi. 10.1038/s41467-023-36527-8
By:
- Tian, Ye;
- Shi, Chupei;
- Malo, Carolina Urbina;
- Kwatcho Kengdo, Steve;
- Heinzle, Jakob;
- Inselsbacher, Erich;
- Ottner, Franz;
- Borken, Werner;
- Michel, Kerstin;
- Schindlbacher, Andreas;
- Wanek, Wolfgang
Publication type:
Article
Long‐term soil warming changes the profile of primary metabolites in fine roots of Norway spruce in a temperate montane forest.
Published in:
Plant, Cell & Environment, 2024, v. 47, n. 11, p. 4212, doi. 10.1111/pce.15019
By:
- Liu, Xiaofei;
- Heinzle, Jakob;
- Tian, Ye;
- Salas, Erika;
- Kwatcho Kengdo, Steve;
- Borken, Werner;
- Schindlbacher, Andreas;
- Wanek, Wolfgang
Publication type:
Article
Management Intensity Controls Nitrogen-Use-Efficiency and Flows in Grasslands—A 15N Tracing Experiment.
Published in:
Agronomy, 2020, v. 10, n. 4, p. 606, doi. 10.3390/agronomy10040606
By:
- Zistl-Schlingmann, Marcus;
- Kwatcho Kengdo, Steve;
- Kiese, Ralf;
- Dannenmann, Michael
Publication type:
Article
Long‐term soil warming decreases soil microbial necromass carbon by adversely affecting its production and decomposition.
Published in:
Global Change Biology, 2024, v. 30, n. 6, p. 1, doi. 10.1111/gcb.17379
By:
- Liu, Xiaofei;
- Tian, Ye;
- Heinzle, Jakob;
- Salas, Erika;
- Kwatcho‐Kengdo, Steve;
- Borken, Werner;
- Schindlbacher, Andreas;
- Wanek, Wolfgang
Publication type:
Article
Does long‐term soil warming affect microbial element limitation? A test by short‐term assays of microbial growth responses to labile C, N and P additions.
Published in:
Global Change Biology, 2023, v. 29, n. 8, p. 2188, doi. 10.1111/gcb.16591
By:
- Shi, Chupei;
- Urbina‐Malo, Carolina;
- Tian, Ye;
- Heinzle, Jakob;
- Kwatcho Kengdo, Steve;
- Inselsbacher, Erich;
- Borken, Werner;
- Schindlbacher, Andreas;
- Wanek, Wolfgang
Publication type:
Article
Long‐term soil warming alters fine root dynamics and morphology, and their ectomycorrhizal fungal community in a temperate forest soil.
Published in:
Global Change Biology, 2022, v. 28, n. 10, p. 3441, doi. 10.1111/gcb.16155
By:
- Kwatcho Kengdo, Steve;
- Peršoh, Derek;
- Schindlbacher, Andreas;
- Heinzle, Jakob;
- Tian, Ye;
- Wanek, Wolfgang;
- Borken, Werner
Publication type:
Article

Found: 6

Long-term soil warming decreases microbial phosphorus utilization by increasing abiotic phosphorus sorption and phosphorus losses.

Long‐term soil warming changes the profile of primary metabolites in fine roots of Norway spruce in a temperate montane forest.

Management Intensity Controls Nitrogen-Use-Efficiency and Flows in Grasslands—A 15N Tracing Experiment.

Long‐term soil warming decreases soil microbial necromass carbon by adversely affecting its production and decomposition.

Does long‐term soil warming affect microbial element limitation? A test by short‐term assays of microbial growth responses to labile C, N and P additions.

Long‐term soil warming alters fine root dynamics and morphology, and their ectomycorrhizal fungal community in a temperate forest soil.