Plan a soil sampling strategy that is best for your operation

Ag Source

VERONA - Each year, growers take special care selecting the best seed varieties and planning out fertilizer and chemical applications. But have you taken time to consider which soil sampling strategy is best for your farm? Soil testing is the foundation for a well-planned fertilizer management program, but can you plan a soil sampling method that is best for your operation?

“Soil testing is the basis for developing a plan to control input costs by managing nutrient applications,” says James Friedericks, Outreach & Education Advisor, AgSource Laboratories. “The challenge is finding what sampling method works best for you and tells you what you need to know, and then sticking with it.”

AgSource Laboratories receives samples from all sizes of operations and from growers who produce crops ranging from corn and soybeans to wheat and alfalfa. There are a few things to remember about soil variability and soil testing that can help you choose the strategy most suitable for your farm and help you manage nutrients wisely for greater profitability.

Select a Strategy that Fits

There are different ways to sample a field, but it’s most helpful to understand why you picked one strategy, and then use it to your advantage. There are two common sampling strategies: Grid and Zone.

Smaller grid sizes produce more detailed maps of the variability of the field.

Grid Sampling – Commercial soil samplers offer sampling densities, or grid sizes, from 1 sample per 5 acres to 1 sample every acre. The smaller grid sizes produce more detailed maps of the variability of the field.

“It’s like pixels in a picture” says Casey Robinson, AgSource Sales Representative for Iowa, “the smaller the pixel the better the picture.”

If the variability of a field is not known, such as on newly rented land, then the smaller grids offer the resolution you need to create useful maps for nutrient management.

There are two common sampling strategies: Grid and Zone.

Research from fields in Illinois showed that 1.25 and 2.5 acre grids generated maps that are similar to those produced from 0.1 acre grids. But larger grid sizes (five or 10 acres) tend to mask, or blur, the variability and can lead to over application of fertilizer in parts of the field. When the field is known to be fairly uniform, or if there is a known management history of the field, then the larger grids provide enough detail for adequate management. The larger grids will also be able to reveal changes in nutrient levels within the field over time. A typical grid sampling strategy is to collect sample cores from a specific point within each grid cell.

Zone Sampling – With the availability of other spatially indexed field data including topography, soil series, aerial imagery and yield maps, this information can be used to identify zones in the field that can be grouped under the same management strategy. Sampling of these areas under a “zone”, or directed soil sampling plan, has the objective of getting an average soil test value for the area being sampled. In this case the variability of the field is organized as a mapped zone that will be managed as a single unit.

Examples of zone sampling.

Considerations when creating zones and a zone sampling plan:

  • Segment your field into management areas based on specific field characteristics such as terraces, elevation, or management history.
  • Identify zones with similar characteristics in each area of the field. Similar zones may be located in separate areas.
  • Other data such as EC mapping or manure application history can be used to identify zones.
  • If zones are larger than 20 acres then subdivide the zone for soil sampling. The results from these samples can be averaged for a uniform treatment.

Take a Representative Sample

To accurately determine the nutrient content or soil test parameter of a given area you need a representative sample. As the number of soil cores combined to create a sample increases from five to 10 the probability of finding the ‘true’ value of the sampled area increases from 70 percent to 80 percent. Increasing from 10 to 15 cores brings it to almost 85 percent chance of finding the ‘true’ value. Therefore, 10 to 15 cores is recommended as the minimum number of cores per sample needed for reliable results, as illustrated for soil phosphorus in the figure below.

Be Precise

Soil sample depth, placement relative to the row, and the consistency of pulling that same quality of sample each time is imperative.

“There can be a lot of questions about the correct sampling technique to use in a field,” notes Jacob Niewohner, AgSource Laboratories Sales Representative for Nebraska. “But the key is to be consistent when sampling a field so that it when it is resampled in the future, the information can be used in the same way.”

Here are some considerations to keep in mind for a consistent sampling practice.

  • Avoid any “outliers” or any significantly different field areas, such as terraces, field depressions, headlands, field entries or eroded spots during sample collection. These can generate results that are not representative of the rest of the area.
  • Collect the same length of core at the same angle every time, and remember to combine and mix the cores before filling a soil sample bag with your representative sample. Typical cores are 6 or 8 inches long.
  • Collect cores from at least eight locations relative to the visible rows in a field. If fertilizer has been banded, then collect one core for every two inches of row spacing and only one core in the row. This pattern should be followed even when the cores to be mixed together for one sample are collected from different rows and throughout a zone. Mechanical sampling equipment has the advantage over manual sampling because the core is collected in the same manner each time. But making sure the cores are pulled with an adequate distribution across the rows is more difficult with the automated equipment.

Careful planning and consistent practices will generate the kind of information you can confidently use to get the right soil management practice onto the right place for better crop growth.