Abstract
Despite the fact that phosphorus (P) is critical for plant biomass production in many ecosystems, the implications of soil organic carbon (OC) sequestration for the P cycle have hardly been discussed yet. Thus, the aims of this study are, first, to synthesize results about the relationship between C and P in soil organic matter (SOM) and organic matter inputs to soils, second, to review processes that affect the C:P ratio of SOM, and third, to discuss implications of OC storage in terrestrial ecosystems for P sequestration. The study shows that the storage of OC in mineral soils leads to the sequestration of large amounts of organic phosphorus (OP) since SOM in mineral soils is very rich in P. The reasons for the strong enrichment of OP with respect to OC in soils are the mineralization of OC and the formation of microbial necromass that is P-rich as well as the strong sorption of OP to mineral surfaces that prevents OP mineralization. In particular, the formation of mineral-associated SOM that is favorable for storing OC in soil over decadal to centennial timescales sequesters large amounts of OP. Storage of 1,000kg C in the clay size fraction in the topsoils of croplands sequesters 13.1kg P. In contrast, the OC:OP ratios of wood and of peatlands are much larger than the ones in cropland soils. Thus, storage of C in wood in peatlands sequesters much less P than the storage of OC in mineral soils. In order to increase the C stocks in terrestrial ecosystems and to lock up as little P as possible, it would be more reasonable to protect and restore peatlands and to produce and preserve wood than to store OC in mineral soils.
Highlights
Both the carbon (C) cycle and the phosphorus (P) cycle have been strongly affected by human activities during the last two centuries, leading to massive changes in the global distribution of C and P across different pools
The reasons for the enrichment of organic phosphorus (OP) over organic carbon (OC) in soil are (a) the mineralization of OC, and (b) the formation of microbial necromass that is rich in P as well as (c) the strong sorption of OP to mineral surfaces in soil that stabilizes OP compounds against mineralization
Since P is a macronutrient that limits primary production in many ecosystems, it is desirable that the removal of C from the atmosphere does not lock up large amounts of P
Summary
Both the carbon (C) cycle and the phosphorus (P) cycle have been strongly affected by human activities during the last two centuries, leading to massive changes in the global distribution of C and P across different pools. While large amounts of C have been moved from fossil reservoirs to the atmosphere (IPCC, 2013), large quantities of P have been transported from phosphate rock to aquatic ecosystems and sewage sludge dumps (Chen & Graedel, 2016; Cordell, Drangert, & White, 2009; Elser & Bennett, 2011) as well as to plant-unavailable. While the growing concentration of C in the form of carbon dioxide (CO2) in the atmosphere leads to fast changes in Earth's climate, the exploitation of rock phosphate and the movement of P to aquatic ecosystems causes eutrophication (Elser & Bennett, 2011). Solutions that lead to a more favorable distribution of C and P across global pools and a more sustainable use of P are urgently needed
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