Koestel, Johannes
- Institutionen för mark och miljö, Sveriges lantbruksuniversitet
Sammanfattning
Increasing the potential of soil to store carbon (C) is an acknowledged and emphasized strategy for capturing atmospheric CO2. Well-recognized approaches for soil C accretion include reducing soil disturbance, increasing plant biomass inputs, and enhancing plant diversity. Yet experimental evidence often fails to support anticipated C gains, suggesting that our integrated understanding of soil C accretion remains insufficient. Here we use a unique combination of X-ray micro-tomography and micro-scale enzyme mapping to demonstrate for the first time that plant-stimulated soil pore formation appears to be a major, hitherto unrecognized, determinant of whether new C inputs are stored or lost to the atmosphere. Unlike monocultures, diverse plant communities favor the development of 30-150 mu m pores. Such pores are the micro-environments associated with higher enzyme activities, and greater abundance of such pores translates into a greater spatial footprint that microorganisms make on the soil and consequently soil C storage capacity.
Publicerad i
Nature Communications
2019, volym: 10, artikelnummer: 3121
Utgivare: NATURE PUBLISHING GROUP
SLU författare
Globala målen (SDG)
SDG15 Ekosystem och biologisk mångfald
UKÄ forskningsämne
Markvetenskap
More information
Correction in: Nature Communications, 2019, Volume: 10, Article Number 4103, DOI 10.1038/s41467-019-12000-3
Publikationens identifierare
- DOI: https://doi.org/10.1038/s41467-019-11057-4
Permanent länk till denna sida (URI)
https://res.slu.se/id/publ/101057