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Grassland Fertilization | Part 5: Native Grass Plantings (Case Study 4)

Apr 13, 2015

By Pete Bauman

Parts three and four of the Grassland Fertilization Series highlighted N fertilization effects on native grassland communities. This article addresses N effects on planted native grasses in various situations.

Nitrogen fertilization of planted grasslands can have substantial impacts to overall plant community production. However, the overall impact of N application to the plant community is largely dependent on the composition of the grass field. Further, management goals and objectives of the planted grassland are an important driver in the consideration of whether artificial N applications will be beneficial or harmful. Here we will discuss various plant communities and the implications of fertilization on each.\

High-diversity native grass plantings

Photo 1: An example of a healthy high diversity native grass and forb planting being managed with grazing. This is an example of a plant community where artificial N would be harmful as it would stimulate competition from exotic grass species

There are several planted grass communities and a variety of management objectives associated with each. The first general category is high diversity planted grasslands that are often established and managed by conservation organizations or agencies and are often planted for the overall benefit of the ecosystem. These high diversity plantings often lie in close proximity to existing diverse native prairie and are managed as a complimentary habitat component. These plantings may consist of dozens of native grasses and forbs established at a considerable cost and thus are often managed with tools and techniques tailored specifically for the propagation of the native species and against non-native invasive grasses and broadleaf plants. Common tools may consist of fire, herbicides, grazing, clipping, or haying (photo 1). Recently several agency-managed private land programs have promoted high diversity native plantings, as the benefits to pollinator species such as bees and butterflies have been realized.

Nitrogen applications to high-diversity grass plantings

In healthy native grass plantings with only limited invasion of non-native grasses, nitrogen fertilization will likely bolster the competitive advantage of the undesirable invasive grasses. This in turn will have a negative impact on the plant community likely leading to reductions and possibly elimination of native plants from the system over time. Native plantings are often dominated by large and robust native grasses that can impact forb establishment through competition for light and litter accumulation. Adding N to this system will likely only increase overall biomass production through stimulation of the non-native grasses, thus further reducing the ability of the planted forbs to establish. In addition, once the invasive species gain a competitive advantage, they will likely continue to self-propagate and gain dominance in the community, leading to additional reductions in native plant diversity and richness.

Low-diversity native grass plantings

Grasslands enrolled in the Conservation Reserve Program (CRP) are a good example of low-diversity native grass plantings. These fields are often planted to fairly robust commercial cultivars of a handful of native grass species such as big bluestem, switch grass, Indian grass, little bluestem, side oats grama, and other common warm season species. In most cases, these grasses are complimented with a variety of native flowering broadleaf forbs. Due to program regulations, management or disturbance actions in these grass fields often only occur on a 3-5 year basis after initial establishment, which can lead to the accumulation of heavy litter or thatch. While this litter can at times be beneficial for wildlife needs such as nesting, it can be limiting to the movement of young chicks or to the recruitment of seedlings.

Nitrogen applications to low-diversity native grass plantings

In many cases, site preparation of these fields fails to completely eliminate invasive non-native grasses or broadleaf weed seeds from the soil, thus invasion of these species is often prevalent fairly early during the establishment of these grass plantings and can persist throughout the life of the planting. Nitrogen additions to these fields can propagate undesirable species such as smooth bromegrass and Canada thistle, likely increasing shading and competition for light and adding to the annual accumulation of litter and reduced recruitment of desirable plants.

Case Study 4, Florence Area, Codington County:

2013 Nitrogen effects on production of CRP fields planted to native warm season grasses (Bauman and Hernandez)

In this study the landowner had historic CRP fields that were planted primarily to big bluestem and Indiangrass. The fields were enrolled into a permanent grassland conservation easement and it was the intention of the landowner to maintain the grass in a high quality native stand. The landowner leased the fields to a neighboring producer who harvested an annual hay crop. The renter was interested in maximizing hay production and proposed N fertilization as a means of improving yield.

Three fields were included in this small study. Approximately 1-acre plots in each of the three fields were fertilized with 97 lbs./acre N applied on May 2, 2013. Bulk N (46-0-0) was applied at an actual rate of 210.8 lbs./acre and a cost of $545/ton. After application fees, N application costs were $63.20/acre.

SDSU Extension field staff was invited to conduct yield and soils assessments at the site, and samples were collected on August 7, 2013 at near peak production of the native grasses. Clipping was conducted utilizing standardized methods with a 0.96 ft2 clipping ring, dried in a drying oven at SDSU, and weighed on a digital gram scale. Average production of the N-fertilized plots (n=3) was 6,150 lbs./acre and was significantly higher than the unfertilized plots (n=6) which averaged 2,838 lbs./acre (p=0.01). The average difference in yield between fertilized and unfertilized was 3,312 lbs./acre.

Three soil core sub-samples were collected along with the vegetation samples from each of the sample areas listed above utilizing a 12” soil probe. Soil samples were analyzed for N and carbon content at the SDSU soil lab. Soil carbon averaged 42.7% in the fertilized plots. While not significantly higher than the 41.5% soil carbon level in the unfertilized plots, statistical analysis indicated a possible trend in higher soil carbon in the fertilized plots that might have been realized if more samples had been collected (p=0.07). Soil N content was 0.86% in the fertilized plots and was not significantly different than the 0.82% soil N recorded in the unfertilized plots (p=0.32).
 

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