Well-designed multi-species grassland mixtures enhance both soil carbon inputs and aboveground productivity
Esben Øster Mortensen, Diego Ábalos, Jim Rasmussen
Abstract
Increasing species diversity in managed grasslands may serve multiple environmental purposes, especially when legumes are included. Yet, how to design such legume-based grassland mixtures to increase soil C inputs remains unclear. This is particularly true for C inputs into deep soil layers, and via rhizodeposition. This field study investigated the effects of mixture design on root C and net-rhizodeposition to 1 m depth in managed grasslands with the aim to combine high soil C inputs with high aboveground productivity. Net-rhizodeposition was defined as accumulated C lost from roots, which remained in the soil at the end of the growing season. We used multiple-pulse isotopic labelling with 13 C-CO 2 to quantify the soil C inputs from roots and rhizodeposition in a range of species mixtures fertilized with 75 kg N ha −1 , and in pure stand perennial ryegrass with different N fertilizer rates (75 vs 300 kg N ha −1 ). Mixtures comprised productive legumes ( Trifolium repens, Trifolium pratense ) with non-legumes (grasses: Lolium perenne , Festuca arundinacea ; forbs: Cichorium intybus , Plantago lanceolata ) in 2-species mixtures and in a 6-species mixture, and an 18-species mixture with additional species from the three functional groups. Our results showed increased belowground C input with species richness up to six without compromising aboveground yield, but when species richness increased further, root C was substantially reduced. Total net-rhizodeposition measured to 1 m depth was reduced with higher N availability (fertilizer or legume inclusion) independently of increasing root biomass. Within mixtures, the 2-species mixtures with red clover had lower rhizodeposition compared to white clover. Overall, the 6-species mixture represented the best option to balance both high root C with rhizodeposited C, as well as maintaining a high and stable aboveground yield similar to the high-fertilized pure stand grass. This study shows how species design of legume-based mixtures – not species richness per se – can increase belowground C input to depth in intensively managed grasslands without compromising aboveground productivity. Thus, our results reveal an agronomic option to steer soil C storage via rhizodeposition and root C, providing quantitative evidence to better understand the relevance of these pools for C cycling. Above- and belowground Carbon (C) allocation in grassland mixtures. Aboveground C includes stubble, and belowground C pools are measured to 1 m depth. Treatments with 1 species are perennial ryegrass, 2-species mixtures with different aboveground yield are perennial ryegrass with white clover (Tr: Trifolium repens ) or red clover (Tp: Trifolium pratense ), and multispecies mixtures contain 3 functional groups (grass, legume and forb). • Higher soil N availability reduced rhizodeposition in managed grasslands. • Combining species with complementary traits ensured high root and rhizodeposited C. • Increasing from six to 18 species reduced root C input but not rhizodeposited C. • Perennial ryegrass, plantain and white clover increased total net-rhizodeposited C. • Correlation between rhizodeposited C and root C depends on mixture.