The nitrogen, carbon and greenhouse gas budget of a grazed, cut and fertilised temperate grassland

Stephanie Jones ,Klaus Kaiser,Claire Campbell,Reimo Kindler,Chiara Di Marco,Cairistiona F E Topp,Jan Siemens,Mark A Sutton,Carole Helfter,Netty Van Dijk,Eiko Nemitz,Mhairi Coyle,Margaret Anderson,Marion Schrumpf,Robert M Rees,Ralf Kiese,Peter Levy ,D Famulari ,Y.s Tang ,U Skiba

doi:10.5194/bg-14-2069-2017

Abstract

Abstract. Intensively managed grazed grasslands in temperate climates are globally important environments for the exchange of the greenhouse gases (GHGs) carbon dioxide (CO2), nitrous oxide (N2O) and methane (CH4). We assessed the N and C budget of a mostly grazed and occasionally cut and fertilised grassland in SE Scotland by measuring or modelling all relevant imports and exports to the field as well as changes in soil C and N stocks over time. The N budget was dominated by import from inorganic and organic fertilisers (21.9 g N m−2 a−1) and losses from leaching (5.3 g N m−2 a−1), N2 emissions (2.9 g N m−2 a−1), and NOx and NH3 volatilisation (3.9 g N m−2 a−1), while N2O emission was only 0.6 g N m−2 a−1. The efficiency of N use by animal products (meat and wool) averaged 9.9 % of total N input over only-grazed years (2004–2010). On average over 9 years (2002–2010), the balance of N fluxes suggested that 6.0 ± 5.9 g N m−2 a−1 (mean ± confidence interval at p > 0.95) were stored in the soil. The largest component of the C budget was the net ecosystem exchange of CO2 (NEE), at an average uptake rate of 218 ± 155 g C m−2 a−1 over the 9 years. This sink strength was offset by carbon export from the field mainly as grass offtake for silage (48.9 g C m−2 a−1) and leaching (16.4 g C m−2 a−1). The other export terms, CH4 emissions from the soil, manure applications and enteric fermentation, were negligible and only contributed to 0.02–4.2 % of the total C losses. Only a small fraction of C was incorporated into the body of the grazing animals. Inclusion of these C losses in the budget resulted in a C sink strength of 163 ± 140 g C m−2 a−1. By contrast, soil stock measurements taken in May 2004 and May 2011 indicated that the grassland sequestered N in the 0–60 cm soil layer at 4.51 ± 2.64 g N m−2 a−1 and lost C at a rate of 29.08 ± 38.19 g C m−2 a−1. Potential reasons for the discrepancy between these estimates are probably an underestimation of C losses, especially from leaching fluxes as well as from animal respiration. The average greenhouse gas (GHG) balance of the grassland was −366 ± 601 g CO2 eq. m−2 yr−1 and was strongly affected by CH4 and N2O emissions. The GHG sink strength of the NEE was reduced by 54 % by CH4 and N2O emissions. Estimated enteric fermentation from ruminating sheep proved to be an important CH4 source, exceeding the contribution of N2O to the GHG budget in some years.

Highlights

Managed grasslands cover an estimated 26 % of earth’s land surface (FAOstat, 2008)
Soil N storage assessed from soil measurements from a cut grassland close to our field, where plots were treated with cattle slurry, stored N over 6 years at a rate of −2.17 g N m−2 a−1 in the top 10 cm, while, in the same experiment, an N loss was observed from mineral N and urea treatments (4.5 and 8.3 g N m−1 a−1, respectively; Jones et al, 2007)
Smith (2014) examined evidence from repeated soil surveys, long-term grassland experiments and simple mass balance calculations and concluded that, grasslands can act as C sinks, they cannot act as a perpetual C sink and could not be used as an offset for greenhouse gases (GHGs) emissions

Summary

Introduction

Managed grasslands cover an estimated 26 % of earth’s land surface (FAOstat, 2008). The impact of reactive nitrogen (Nr) losses, carbon (C) sequestration and greenhouse gas (GHG) emissions (CO2, CH4 and N2O) from these grasslands is of global importance and will become even more relevant in the future as increased standards of living in developing countries are expected to result in a rapid growth of livestock farming (Caro et al, 2014). Carbon and N cycles in grasslands are intricately linked and tightly coupled in extensively managed low-N grasslands, with sinks and sources in equilibrium. Converting such systems to intensively managed N-fertilised grasslands in the short term may increase the soil organic carbon (SOC) pool from decomposed plant litter and root material as well as through rhizodeposition (Rees et al, 2005) until a new equilibrium is reached (Soussana and Lemaire, 2014). Exports through biomass harvesting, the addition of organic manures (from organic fertiliser additions and animal excretion) as well as CO2 and CH4 losses from animal respiration and enteric fermentation can make significant contributions to the C budget

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Discussion

Conclusion