Steven D. Allison, Ph.D.
Affiliations: | 2005 | Stanford University, Palo Alto, CA |
Area:
Ecology Biology, BiogeochemistryGoogle:
"Steven Allison"Parents
Sign in to add mentor| Peter Morrison Vitousek | grad student | 2005 | Stanford | |
| (Microbial allocation to soil enzyme production: A mechanism for carbon and nutrient cycling.) | ||||
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Publications
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| Abs E, Chase AB, Manzoni S, et al. (2024) Microbial evolution-An under-appreciated driver of soil carbon cycling. Global Change Biology. 30: e17268 |
| Piton G, Allison SD, Bahram M, et al. (2023) Life history strategies of soil bacterial communities across global terrestrial biomes. Nature Microbiology |
| Allison SD. (2023) Microbial drought resistance may destabilize soil carbon. Trends in Microbiology |
| Martiny JBH, Martiny AC, Brodie E, et al. (2023) Investigating the eco-evolutionary response of microbiomes to environmental change. Ecology Letters |
| Abs E, Chase AB, Allison SD. (2022) Burning Questions: How do soil microbes shape ecosystem biogeochemistry in the context of global change? Environmental Microbiology |
| Püspök JF, Zhao S, Calma AD, et al. (2022) Effects of experimental nitrogen deposition on soil organic carbon storage in Southern California drylands. Global Change Biology |
| Alster CJ, Allison SD, Johnson NG, et al. (2021) Phenotypic plasticity of fungal traits in response to moisture and temperature. Isme Communications. 1: 43 |
| Alster CJ, Allison SD, Glassman SI, et al. (2021) Exploring Trait Trade-Offs for Fungal Decomposers in a Southern California Grassland. Frontiers in Microbiology. 12: 655987 |
| Malik AA, Swenson T, Weihe C, et al. (2020) Drought and plant litter chemistry alter microbial gene expression and metabolite production. The Isme Journal |
| Alster CJ, von Fischer JC, Allison SD, et al. (2020) Embracing a new paradigm for temperature sensitivity of soil microbes. Global Change Biology |