2018-12-14

Authors: Romulo Lollato, Mary Knapp

Compared to the historical sowing pattern for Kansas, about 65% of the wheat crop was sown late. Additionally, many acres intended for wheat were not sown, particularly those acres which were intended to follow a soybean crop. Excessive moisture from September through early November is the reason for both the delayed sowing and potential reduction in wheat acres. In the majority of the cases, this moisture led to a very good stand establishment which is extremely important in setting the crop’s yield potential. However, some locations had excess moisture, resulting in flooding of newly emerged fields. Also, large rainfall events led to soil crusting and decreased stands in many conventional tilled fields. In fact, a large portion of the wheat growing region in Kansas (central Kansas) has received more than 11 inches of precipitation since September 1. To provide a historical perspective, this results in anywhere from – 4.5 to +12.5 inches departure from normal (Figure1).

Figure 1. Planting season precipitation (left) and departure from normal (right) for Sep. 1 – Nov. 30 across Kansas.
Figure 2. Total precipitation (left) and departure from normal (right) for November 2018 across Kansas.

Late sowing and cool fall implications

The late sowing coupled cooler-than-normal temperatures in a large portion of the Kansas wheat growing region might bring challenges to the wheat crop, especially for winter survival (Figure 3). Cool temperatures and saturated soils may reduce root development, which would render the crop less winter-hardy.

Figure 3. Percent soil saturation as of November 16, 2018. Source: Kansas Mesonet

In most regions of Kansas where wheat sowing was delayed due to excess precipitation, wheat development is lagging compared to the historical average. Many wheat fields in central and north central Kansas were delayed even further as producers finished summer crop harvest after the rainfall events. In these situations, it was not uncommon for producers to sow wheat after the first of November. This may not have provided the crop enough time to tiller during the fall. One example of such case is shown in Figure 4, where there is a comparison of fields planted late September, late October, and early November. All photos were taken in nearby fields near Hutchison. The better development of the late September sown fields is apparent when compared to the fields sown later. Wheat needs at least 4-5 leaves and 1-2 tillers prior to winter dormancy for maximum cold tolerance. Wheat that has fewer tillers and leaves, such as the later-sown crop, will be more susceptible to winter kill (Figure 5).

Figure 4. Late September (left) versus late October (center) versus early November (right) sowing dates and their effect on canopy development. Photos taken December 10 2018 in Hutchinson by Leonardo Molssato, Assistant Scientist, K-State Wheat and Forages Production Group.
Figure 5. Differences in wheat growth and development as affected by planting date. Wheat planted late October showing no primary tillers (left), while wheat planted early October has started to tiller (right). Both crops still need significant fall growth to properly prepare for winter dormancy. Photo taken at the Agronomy North Farm, Manhattan, Romulo Lollato, K-State Research and Extension.

What should producers look for?

Producers can assess the status of their wheat crop going into the winter in a few different ways. One important way is looking at the top-growth and counting leaves and tillers. As mentioned previously, wheat needs at least 4-5 leaves and 1-2 tillers prior to winter dormancy for maximum cold tolerance. Wheat that has fewer tillers and leaves will be more susceptible to winter kill (Figure 5).

It is important to also look at the root system development (Figure 5). Roots coming out from the seed are called seminal roots and are used to take up water and nutrients throughout the entire growing season. There are not very many of these roots so their contribution to overall water and nutrient uptake is limited. Crown roots are illustrated in Figure 6, right panel. Crown roots are the two white protrusions coming out of the white area about an inch above the seed in the right photo. These roots take up most of the water and nutrients needed by the plant, and they are very important for the plant to survive the winter. If a cow were grazing on this wheat, she would probably pull the plant out of the ground as there are not many roots holding the plant in the soil yet. Consequently, this wheat crop still needs considerable fall growth prior to grazing or winter dormancy.

Figure 6. Seminal and crown roots development in wheat as affected by planting date. Both rooting systems are developed enough to be grazed, and may be susceptible to nutrient deficiencies or desiccation damage over the winter if the crown roots develop further. Photos taken at the Agronomy North Farm, Manhattan, Romulo Lollato, K-State Research and Extension.

The photos below illustrate various degrees of what you would like to see when you examine your wheat this fall. As expected, there is better canopy coverage with early-planted wheat for dual purpose (mid-September planting) as compared to wheat planted at the optimal planting time for grain only (mid-October planting). This does not necessarily mean the early-planted wheat is in better condition for winter. As long as the wheat planted in mid-October has 1-2 tillers and good crown root development (Figure 8B), the plants will have adequate growth going into winter. In addition to having adequate top-growth and root development, factors such as the extent of the plants’ cold hardening, variety differences in winter hardiness, soil moisture and temperature, and snow or plant residue protection on the soil surface will ultimately have an impact on winter survival.

Figure 7. Fall growth and development of wheat as affected by planting date. Photos by Romulo Lollato, K-State Research and Extension.
Figure 8. (A) Some of the crown roots are over one-inch long. For this plant, a couple additional weeks of mild weather would allow for more root growth which would be desirable. (B) Ideal wheat above- and below-ground development before winter dormancy, with crown roots fully developed and able to provide water and nutrients to the plant. With this amount of crown root development, wheat plants should be well anchored. If cattle were grazing this wheat, they couldn’t pull the plants out of the ground. Photos by Jim Shroyer, professor emeritus, K-State Research and Extension.

Stay tuned to future issues of the eUpdate for more information on the status of the wheat crop this year.

Romulo Lollato, Wheat and Forages Specialist
lollato@ksu.edu

Mary Knapp, Assistant Climatologist and Weather Data Library
mknapp@ksu.edu