Abstract

The loss of organic matter from agricultural lands constrains our ability to sustainably feed a growing population and mitigate the impacts of climate change. Addressing these challenges requires land use activities that accumulate soil carbon (C) while contributing to food production. In a region of extensive soil degradation in the southeastern United States, we evaluated soil C accumulation for 3 years across a 7-year chronosequence of three farms converted to management-intensive grazing. Here we show that these farms accumulated C at 8.0 Mg ha−1 yr−1, increasing cation exchange and water holding capacity by 95% and 34%, respectively. Thus, within a decade of management-intensive grazing practices soil C levels returned to those of native forest soils, and likely decreased fertilizer and irrigation demands. Emerging land uses, such as management-intensive grazing, may offer a rare win–win strategy combining profitable food production with rapid improvement of soil quality and short-term climate mitigation through soil C-accumulation.

Introduction

Soils represent the largest terrestrial C reservoir, containing 2,300 Pg of soil organic carbon (SOC) down to 3 m (ref. 1). Agricultural cultivation has likely decreased soil C stocks by one-half to two-thirds, with a cumulative loss near 30–40 Mg C ha−1 (ref. 2) that has likely contributed 78±12 Pg of C to the atmosphere as carbon dioxide (CO2)3. Lower SOC abundance also has a direct impact on soil productivity. Soil organic matter (SOM) enhances soil nutrient-retention, water-holding capacity (WHC) and facilitates healthy microbial communities essential for sustaining high levels of food production4. Land-management strategies that sequester C and improve soil quality can potentially reverse soil degradation5; if they can also sustain food production then they deserve careful consideration.

The accumulation of C through land management has the potential to offset up to one-third the annual increase in atmospheric CO2 (ref. 3). The most rapid C accumulation is achieved in (sub)tropical aggrading forests or plantations, which have aboveground C accumulation rates as high as 30 Mg ha−1 yr−1 (ref. 6) that can be sustained through wood harvest and conversion to building materials. The highest rates of belowground C accumulation occur when land is converted to grassland ecosystems7,8,9,10,11. Grasses allocate substantial C belowground and can extend their root structures to great depths, leading to thick soil horizons rich in organic matter. Many studies have quantified SOM increases following conversion to grasslands, native prairies and through implementation of conservation tillage, cover crops or perennialization of agroecosystems3. Accumulating C in the soil has additional benefits of higher nutrient retention and water-use efficiency—hence improving the sustainability of soil-based agriculture and forestry.

Converting tilled cropland to grazed pasture can drive substantial SOC accumulation12,13 while providing food and economic return for a landowner. Intensive grazing systems, such as those studied here, have been tested and used extensively in temperate regions of Australia and New Zealand, and the increases in soil C content and benefits of higher soil nutrient status are well documented14,15,16,17. Optimizing either pasture fertilization, irrigation or grazing intensity can each improve C accumulation rates by up to 0.5 Mg C ha yr−1 (ref. 9). Intensive pasture management has yielded rates of C accumulation as high as 2.9 Mg C ha−1 yr−1 following the conversion from cropland13; the intensive management required is most economical for high-value end products, such as milk and dairy products.

The potential SOM and CO2-sequestration benefits of investing in pasture-based land management are likely greatest in highly degraded soils in warm subtropical climates that facilitate long pasture-growing seasons. Highly weathered soils of the subtropics are particularly sensitive to SOM amounts since they often lack minerals, such as 2:1 layer aluminosilicates, with high-nutrient-retention capacity18. A century of intensive tillage techniques has exacerbated SOM loss and soil erosion on the highly weathered subtropical soils in the southeastern United States19,20. However, the long-growing seasons, relatively inexpensive land, regional milk supply shortfalls and high return on investment have fuelled an expanding dairying farming boom21,22 with 4,000 ha of row crop converted to management-intensive grazing farms in Georgia alone since 2005 (co-author Hancock, personal communication). We sought to determine how fast and how much soil C accumulates following conversion of row crop agriculture to management-intensive grazed pastures in the southeastern United States.

We quantified the magnitude and direction of SOC stocks by sampling across grazed pastures established in 2006, 2008 and 2009, defining a chronosequence of land-use change. These pastures were established on land farmed for cotton and peanuts using conventional tillage techniques for the last 50 years, resulting in a SOC content of 0.5% in the surface horizons (Supplementary Fig. 1). We sampled soil pits and replicated soil cores over 2 years across all pastures and measured soil C, δ13C, and soil bulk density.

Results

Rapid soil C accumulation

Here we report a rapid rate of soil C accumulation accompanying conversion of row crop agriculture land to intensively grazed pastures (Fig. 1) that is on par with the global record for soil C accumulation rate associated with tropical grasslands in Brazil23. Fisher, et al.23 illustrated that the introduction of deep-rooting African grasses to lowland savannas in tropical South America drives C accumulation rates of 7.1 Mg C ha−1 yr−1 and suggested that other fields may have rates as high as 13 Mg C ha−1 yr−1 (refs 23, 24, 25). In our pastures, we find that peak C accumulation occurs 2–6 years after pasture establishment with a gain of 8.0±0.85 Mg C ha−1 yr−1 (r2=0.88, P<0.0001) in the upper 30 cm of soil (Fig. 2). Following an apparent lag in the first 2 years, the most recently established farm (converted in 2009) accumulated C at 4.6 Mg C ha−1 yr−1(r2=0.79, P=0.0184), the middle-established farm (converted in 2008) accumulated C at an average rate of 9.0 Mg C ha−1 yr−1 (r2=0.80, P=0.0395), while the earliest-established farm (converted in 2006) accumulated C at 2.9 Mg C ha−1 yr−1 (r2=0.97, P=0.1125) before an apparent decline in the accumulation rate at 6.5 years following conversion. In all cases, detectable increases in C accumulation were limited to the upper 30 cm (Supplementary Figs 1 and 2), with variability below 30 cm yielding an integrated C accumulation rate of 7.1±2.7 Mg C ha−1 yr−1 in the top metre (Supplementary Fig. 3). This suggests that accumulation at depth may require a longer timeframe or a shift in management practices.

Figure 1: Land use shift from row crop to management-intensive grazing.

Figure 1

Aerial photographs of the Wrens Farm (Site ID: 2006) taken in 2006 (a) before conversion to management-intensive grazing system and (b) in 2013, 7 years after land conversion.

Figure 2: Soil carbon rapidly increases with conversion of row crop to intensive grazing.

Figure 2

Soil carbon (Mg C ha−1) content shown for the top 30 cm of farms converted in 2006 (green symbols), 2008 (blue symbols) and 2009 (black symbols) and a control farm currently in row crop (grey symbols). Samples from soil pits and soil cores are distinguished by circles and triangles, respectively; open versus closed black circles are from different locations on the 2009 farm. The linear regression (solid line: r2=0.88, P<0.0001) and 95% confidence intervals (dashed lines) are for data between 2 and 6 years since conversion only. The grey-shaded arrows represent our interpretation of soil carbon change in this system on the basis of current data.

Why we observe high rates of soil C accumulation

Soil δ13C values are an efficient tracer of this land-use change. The 50+ years of C3 cotton and peanut cultivation established soil δ13C values much lower than the major C inputs from grazed pasture grasses, including manure (δ13C=−14.88) and roots (δ13C=−20.03) from the C4 bermudagrass that comprises the bulk of warm season forage on these farms (Supplementary Fig. 4). Consistent with this, the farm exhibiting the highest C accumulation rate also exhibited large changes in δ13C, while the farm established in 2006 showed little to no change in δ13C over the 2-year study period. However, the farm established in 2006 had root mass abundance (standing stocks) two to three orders of magnitude higher than the more recently established farms (Supplementary Table 1), suggesting high belowground C cycling from root turnover.

The transition from crop to pasture systems results in an average 19% increase in soil C stocks26. In our intensively grazed systems, we report an 75% increase in C stocks within 6 years of conversion. This high C accumulation rate stems from year round intensive forage/grazing management techniques on sandy soils with an initially low soil C content due to past conventional-till row crop agriculture. The pastures in this study are managed for maximum forage production; employing N fertilization, irrigation and selective rotational grazing designed to optimize forage digestibility and protein content. These forage-management techniques are precisely those suggested to increase SOM in pasture systems13 and when they are applied to soils with degraded SOC content, such as soils in the southeastern United States, rapid C accumulation ensues.

Consequences for soil quality

In addition, the establishment of intensively grazed pastures improved soil quality by increasing soil cation exchange capacity (CEC) and WHC during the 5 year of transition documented by our chronosequence (Fig. 3, Supplementary Figs 5 and 6 and Supplementary Table 2). CEC increased by 95% in the top 30 cm for an average rate of 44 meq g−1 yr−1, while WHC increased by 34%. These soil improvements should reduce the need for fertilizer and water inputs and may also mitigate nitrogen (N) losses from the agricultural system. In a companion study on the oldest chronosequence farm, only half of the 620 kg ha−1 of N inputs (silage, hay, grain and mineral fertilizer) were accounted for as N outputs (milk, N2O, NH3 and leached NO3) with the balance presumably sequestered in the SOM pool or lost via denitrification27.

Figure 3: The relationship between percent soil C and cation exchange capacity.

Figure 3

The relationship is shown at different soil depths along the chronosequence. Soil CEC increases with soil C accumulation. The dashed line is a linear regression of the data (P<0.001).

Six years after conversion, our data suggest that an apparent plateau in SOC accumulation occurs at ca. 38 Mg C ha−1 in the top 30 cm, which is consistent with peak SOC stocks in the region13,20,28. C stocks as high as 51 Mg C ha−1 (top 20 cm) have been measured in a bottomland Piedmont forest soil (ref. 20 and references within), suggesting that C may continue to accumulate in these intensively grazed pastures over the millennial scales at slower rates29. In New Zealand pastures, soil C stocks have been estimated as high as 109 and 138 Mg C ha−1 (refs 14, 17), and once these soils reach a higher SOC level they can become susceptible to C loss if management changes15. Total C stock will be determined by grass productivity, soil physical and biological attributes, and the degree of physical disturbance, which can all change with future management11,20,25.

Extrapolation of results

The C-accumulation benefits of adopting management-intensive grazing practices are notable. We estimate that if just 10% of the 9 million hectares30 of cropland in the southeastern United States (average C stock: 10 Mg C ha−1) were converted to management-intensive grazing land, 4.5 Tg of C would be accumulated per year. Assuming peak SOC stocks in the top 30 cm were reached at 40 Mg C ha−1, this accumulation would continue for a minimum of 6 years, reaching a regional accumulation of 27 Tg C. On the basis of a whole farm C-cycle analysis, C accumulation appears to offset methane emissions31 during the rapid soil C accumulation phase yielding net C-sequestration rates of 1.6 Mg C-CO2 equivalents ha−1 yr−1 or 5,805 kg CO2 equivalents ha−1 yr−1 (see Methods section for calculation details). As the C accumulation rate declines these farms will become net C-emitting—similar to all dairy production—because of ruminant methane emissions. However, the substantial soil-quality benefits of higher organic matter remain and will likely increase the sustainability of dairy production using management-intensive grazing.

Discussion

The expansion of this emerging land use practice on previously tilled, row crop land may improve soil quality regionally and could mitigate climate change via rapid increases in soil C. Two daunting challenges facing humanity are feeding a growing population and curtailing the impacts of climate change5. Alternative land use activities that reduce environmental degradation (for example, erosion, excess fertilizer and water demand) as well as provide economically viable food can provide a win–win scenario. There are considerable economic incentives for converting irrigated row crop land to grazed pastures used for dairy22, especially in warm climates where rainfall is sufficiently high. This practice could vastly improve soil quality4 and serve as a C sink; however, the magnitude of SOC changes will depend on farm inputs (fertilizer, irrigation and pasture species), pasture management techniques32 and specific soil conditions. Our results demonstrate that pasture-based intensively grazed dairy systems may provide a near-term solution for agricultural lands that have experienced soil-C loss from previous management practices. Emerging land uses, such as management-intensive grazing, offer profitable and sustainable solutions to our needs for pairing food production with soil restoration and C sequestration.

Methods

Site description

The three farms used in this study were within 40 km of each other on the eastern coastal plain in Burke and Jefferson Counties, Georgia, USA. Soils in this region are deep, well-drained, fine or fine-loamy Kandiudults formed on Coastal Plain sediments and are common to the geographic region. The average annual temperature in this region is 17 °C and annual precipitation is 1,224 mm yr−1 (University of GA Environmental Monitoring Network, 1915–2003). From April to November, evapotranspiration exceeds rainfall and farms irrigate with high-quality aquifer water to meet pasture needs. Forage species in the pasture systems include a hybrid of bermudagrass and stargrass (Cynodon dactylon (L.) Pers. × C. nlemfuensis Vanderyst; cv. ‘Tifton 85’) as a perennial forage base (grown May through October) that is over-seeded in the fall with annual ryegrass (Lolium multiflorum Lam.; cv. ‘Big Boss’, ‘Marshall’ and/or ‘Feast’). Individual paddocks received stock densities ranging from 75 to 150 animal units per hectare during any given 12-h period. Dairy cattle were rotated among 45–60 paddocks (depending on farm layout) twice daily, completing a cycle of grazing all paddocks within 15–45 days, depending on time of year, growth rate and quality of the forage, and the nutritional needs of the herd.

Soil characteristics and sampling procedures

Soils are classified in the Orangeburg (Fine-loamy, kaolinitic, thermic Typic Kandiudults), Dothan (Fine-loamy, kaolinitic, thermic Plinthic Kandiudults) or Faceville (Fine, kaolinitic, thermic Typic Kandiudults) series and the dominant soil minerals are kaolinite, hematite and quartz. Soils were sampled in April, August and December 2011 and December 2012 by genetic horizon from 1 m pits for soil analyses and bulk density (Supplementary Tables 2–4). Soils were sampled from the bottom of the pit to the top to reduce contaminating subsurface horizons with surface litter. Stainless steel cores were pushed horizontally into pit horizons, removed and dried at 105 °C to determine bulk density. CEC and WHC were determined on pit sample horizons within the top 30 cm. To assess spatial variability, replicate soil cores (five cores composited and replicated six times) were sampled (0–30 cm) at each site on December 2011 and December 2012 (Supplementary Fig. 7, Supplementary Table 5). A row crop (for example, cotton, corn and peanut rotations) farm on similar soil to grazing dairies was sampled to approximate pre-conversion soils. The row crop farm used in this study was adjacent to the middle-aged (2008) farm and representative of row crop practices in the region.

Soil analyses

Soils were sieved (2 mm) and fine roots and plant material that passed through the sieve were handpicked and static electricity was used to remove abundant fine roots in the 0–5 cm horizon. Soil C and δ13C was assessed by finely grinding samples with a zirconium mortar and pestle and analysed with a coupled continuous-flow elemental analyser—isotope ratio mass spectrometer (Carlo-Erba 1108 EA interfaced to a Thermo-Finnigan Delta Plus XP IRMS). Percent carbon was calculated to an areal basis using bulk density measurements. Bulk density was determined on soils collected in August 2011, December 2012 and July 2013 (youngest farm only) using open-core steel rings (7.5 cm depth × 7.5 cm diameter). For the April 2011 sampling, bulk density was collected using 3.4 cm depth × 8.5 cm diameter cores with one end sealed, which gave abnormally high values in some horizons. Because of this, for the middle-aged farm and the youngest farm, we used the August 2011 bulk density values in our April 2011 calculations (Supplementary Table 3). A homogenized soil sample (air-dried and 2-mm sieved) was sent to the University of Georgia Soil, Plant, and Water Laboratory for chemical analysis. For each sample, P, K, Ca, Mg, Mn, Fe and Zn were extracted using the Mehlich I procedure33,34,35 and simultaneously determined using an Inductively Coupled Plasma (Thermo Jarrell-Ash Enviro I ICAP, Fraklin, MA). Soil pH was measured in a 1:1 soil:CaCl2 (0.01 M) suspension. Particle size analysis was performed using the rapid hexametaphosphate method36. Briefly, 3% hexametaphosphate was added to air-dried soils (2-mm sieved) and used as a dispersal agent, followed by fractionation and quantification of each particle size by sieving. CEC was measured using a modified, unbuffered salt extraction method37, and exchanged NH4+ was analysed colorimetrically (Alpkem RFA-303)38. WHC was measured by applying the appropriate pressure for field capacity (0.1 bar) and wilting point (15 bar) for sandy soil textures39.

Belowground root standing stock estimates

Coarse roots were defined as those that were greater than 2 mm and fine roots were less than 2 mm. All coarse roots were handpicked from >2 mm sample, washed in DI water, lyophilized and quantified by mass. This value was then divided by the total mass of soil it was sieved from and reported on a per 100-g soil basis. Fine roots were handpicked from a 100-g subsample for no more than 45 min, with static electricity and flotation on DI water used to remove abundant fine roots in the 0- to 5-cm horizons at the termination of the time period. All samples were then washed, lyophilized and massed. Values of coarse and fine roots were combined to give a total root mass per 100-g soil sample.

Whole farm C sequestration calculation

Belflower et al.31 compared the whole-farm C-cycle balance between a Georgia conventional dairy farm and one of the intensively grazed dairies used in our study (Farm Site ID-2008 reported here) using the Integrated Farm System Model. They reported an emission rate of 2,350,700 kg CO2 equivalents per year for this farm. By factoring in our estimates of soil C accumulation (8.0 Mg C ha−1 yr−1), we calculate a net soil sequestration rate of 1.58 Mg C-CO2 equivalents ha−1 yr−1 or 5,805 kg CO2 equivalents ha−1 yr−1. Further, we estimate that a soil C accumulation rate of 6.4 Mg C ha−1 yr−1 or higher is required for these systems to serve as a net C sink. While such a high rate cannot be maintained indefinitely following conversion, intensively grazed pasture does meet this criterion for at least an initial 5-year period following land use change.

Statistics

Linear regression models were performed in JMP 10.0 (SAS Institute, Cary, NC). An alpha level of 0.05 was used to determine significant effects.

Additional information

How to cite this article: Machmuller, B. M. et al. Emerging land use practices rapidly increase soil organic matter. Nat. Commun. 6:6995 doi: 10.1038/ncomms7995 (2015).

References

  1. 1.

    Jobbágy, E. G. & Jackson, R. B. The vertical distribution of soil organic carbon and its relation to climate and vegetation. Ecol. Appl. 10, 423–436 (2000).

  2. 2.

    Le Quéré, C., Raupach, M. R., Canadell, J. G. & Marland, G. Trends in the sources and sinks of carbon dioxide. Nat. Geosci. 2, 831–836 (2009).

  3. 3.

    Lal, R. Soil carbon sequestration to mitigate climate change. Geoderma 123, 1–22 (2004).

  4. 4.

    Gregorich, E. G., Carter, M. R., Angers, D. A., Monreal, C. M. & Ellert, B. H. Towards a minimum data set to assess soil organic-matter quality in agricultural soils. Can. J. Soil Sci. 74, 367–385 (1994).

  5. 5.

    Smith, P. et al. How much land-based greenhouse gas mitigation can be achieved without compromising food security and environmental goals? Glob. Change Biol. 19, 2285–2302 (2013).

  6. 6.

    Lugo, A. E., Brown, S. & Chapman, J. An analytical review of production rates and stemwood biomass of tropical forest plantations. Forest Ecol. Manage. 23, 179–200 (1988).

  7. 7.

    Schlesinger, W. H. Carbon balance in terrestrial detritus. Annu. Rev. Ecol. Syst. 8, 51–81 (1977).

  8. 8.

    Silver, W. L., Ryals, R. & Eviner, V. Soil carbon pools in California’s annual grassland ecosystems. Rangeland Ecol. Manage. 63, 128–136 (2010).

  9. 9.

    Conant, R. T., Paustian, K. & Elliott, E. T. Grassland management and conversion into grassland: effects on soil carbon. Ecol. Appl.11, 343–355 (2001).

  10. 10.

    Follett, R. F. & Kimble, J. M. The Potential of US Grazing Lands to Sequester Carbon and Mitigate the Greenhouse Effect CRC Press (2002).

  11. 11.

    McSherry, M. E. & Ritchie, M. E. Effects of grazing on grassland soil carbon: a global review. Glob. Change Biol. 19, 1347–1357 (2013).

  12. 12.

    Franzluebbers, A. J., Stuedemann, J. A. & Wilkinson, S. R.Bermudagrass management in the Southern Piedmont USA. Soil Sci. Soc. Am. J. 65, 834–841 (2001).

  13. 13.

    Conant, R., Six, J. & Paustian, K. Land use effects on soil carbon fractions in the southeastern United States. I. Management-intensive versus extensive grazing. Biol. Fertility Soils 38, 386–392 (2003).

  14. 14.

    Beare, M. et al. Estimating the organic carbon stabilisation capacity and saturation deficit of soils: a New Zealand case study. Biogeochemistry 120, 71–87 (2014).

  15. 15.

    Schipper, L. et al. Soil order and grazing management effects on changes in soil C and N in New Zealand pastures. Agric. Ecosyst. Environ. 184, 67–75 (2014).

  16. 16.

    Schipper, L. A. & Sparling, G. P. Accumulation of soil organic C and change in C: N ratio after establishment of pastures on reverted scrubland in New Zealand. Biogeochemistry 104, 49–58 (2011).

  17. 17.

    Tate, K. et al. Soil organic carbon stocks and flows in New Zealand: system development, measurement and modelling. Can. J. Soil Sci. 85, 481–489 (2005).

  18. 18.

    Sposito, G. The Chemistry of Soils Oxford university press (2008).

  19. 19.

    Trimble, S. W. Man-induced soil erosion on the southern Piedmont. Soil Conservation Society of America (1974).

  20. 20.

    Hendrix, P. F., Franzluebbers, A. J. & McCracken, D. V.Management effects on C accumulation and loss in soils of the southern Appalachian Piedmont of Georgia. Soil and Tillage Res.47, 245–251 (1998).

  21. 21.

    White, S., Benson, G., Washburn, S. & Green, J. Jr Milk production and economic measures in confinement or pasture systems using seasonally calved Holstein and Jersey cows. J. Dairy Sci. 85, 95–104 (2002).

  22. 22.

    Soder, K. & Rotz, C. Economic and environmental impact of four levels of concentrate supplementation in grazing dairy herds. J. Dairy Sci. 84, 2560–2572 (2001).

  23. 23.

    Fisher, M. J. et al. Carbon storage by introduced deep-rooted grasses in the South American savannas. Nature 371, 236–238 (1994).

  24. 24.

    Fisher, M. J. et al. Another dimension to grazing systems: soil carbon. Trop. Grassl. 41, 65 (2007).

  25. 25.

    Post, W. M. & Kwon, K. C. Soil carbon sequestration and land‐use change: processes and potential. Glob. Change Biol. 6, 317–327 (2000).

  26. 26.

    Guo, L. B. & Gifford, R. M. Soil carbon stocks and land use change: a meta analysis. Global Change Biol. 8, 345–360 (2002).

  27. 27.

    Eason, N. P. Nitrogen Dynamics on Grazing Dairy Farms in Georgia. MS Thesis, Univ. Georgia, 62 (2010).

  28. 28.

    Post, W. M., Pastor, J., Zinke, P. J. & Stangenberger, A. G. Global patterns of soil nitrogen storage. Nature 317, 613–616 (1985).

  29. 29.

    Smith, P. Do grasslands act as a perpetual sink for carbon? Glob. Change Biol. 20, 2708–2711 (2014).

  30. 30.

    King, G. M. & Garey, M. A. Ferric iron reduction by bacteria associated with the roots off freshwater and marine macrophytes. Appl. Environ. Microbiol. 65, 4393–4398 (1999).

  31. 31.

    Belflower, J. B. et al. A case study of the potential environmental impacts of different dairy production systems in Georgia. Agric. Syst. 108, 84–93 (2012).

  32. 32.

    McSherry, M. E. & Ritchie, M. E. Effects of grazing on grassland soil carbon: a global review. Global Change Biol. 19, 1347–1357 (2013).

  33. 33.

    Mehlich, A. Determination of P, Ca, Mg, K, Na, and NH4. North Carolina Soil Test Division, Publication no. 1–53, Raleigh, NC (1953).

  34. 34.

    Nelson, W., Mehlich, A. & Winters, E. The development, evaluation, and use of soil tests for phosphorus availability. Agronomy 4, 153–188 (1953).

  35. 35.

    Perkins, H. F. A rapid method of evaluating the zinc status of coastal plain soils 1. Commun. Soil Sci. Plant Anal. 1, 35–42 (1970).

  36. 36.

    Kettler, T. A., Doran, J. W. & Gilbert, T. L. Simplified method for soil particle-size determination to accompany soil-quality analyses. Soil Science Society of America Journal 65, 849–852 (2001).

  37. 37.

    Grove, J. H., Fowler, C. S. & Sumner, M. E. Determination of the charge character of selected acid soils. Soil Sci. Soc. Am. J. 46, 32–38 (1982).

  38. 38.

    Nelson, D. W. Determination of ammonium in KCl extracts of soils by the salicylate method 1. Commun. Soil Sci. Plant Anal. 14, 1051–1062 (1983).

  39. 39.

    Radcliffe, D. E. & Šimůnek, J. Soil Physics with HYDRUS: Modeling and Applications CRC press (2010).

Download references

Acknowledgements

We thank Dr Richard Watson (Girard and Seven Oaks farms) and Alan Titschmarsh (Greenstone farm) for their continued cooperation and access to their farmland. We also thank Payton and Pam Sapp for their assistance coordinating with farmer Jimmy Mobley and assisting us in selecting appropriate row crop fields. This study was funded by the US Department of Agriculture’s, National Institute of Food and Agriculture (NIFA; Grant no. 2011-57003-30366) through the joint USDA-NASA-DOE Carbon Cycle Science Program.

Author information

Affiliations

  1. Odum School of Ecology, University of Georgia, Athens, Georgia, USA

    • Megan B. Machmuller
    •  & Aaron Thompson
  2. Soil and Water Science, University of Florida Gainesville, Florida, USA

    • Marc G. Kramer
  3. Crop and Soil Sciences, University of Georgia, Athens, Georgia, USA

    • Taylor K. Cyle
    • , Nick Hill
    • , Dennis Hancock
    •  & Aaron Thompson

Contributions

N.H., M.G.K. and A.T. conceived of the project, with A.T. coordinating project efforts. N.H. and D.H. performed initial site selection and facilitated collaboration with extension agents and farmers. T.K.C., M.B.M, M.G.K., N.H. and A.T. performed the field sampling. T.C. and M.B.M. performed the laboratory analyses, and M.G.K. performed the measurements of C isotopes and abundance. M.B.M led the data analysis and manuscript preparation, to which all other authors contributed.

Competing interests

The authors declare no competing financial interests.

Corresponding author

Correspondence to Aaron Thompson.