|
Dr. Chad Lee
Extension Grain Crops
859.257.3203
cdlee2@uky.edu
Dr. Jim Herbek
Extension Grain Crops
270.365.7541 ext. 205
jherbek@uky.edu |
Chad Lee and James Herbek, University of Kentucky
Almost 40% of the corn
in Kentucky has been planted according to the April 12 Crop Weather
Report from the Kentucky Agricultural Statistics Service. The
five-year average for corn planting at this time is only 13%. Much
of this corn was planted before the spring frost free dates. The
early planting of corn increases the likelihood that some of this
corn will emerge and be exposed to freezing temperatures.
Factors Required for Damage
The severity of damage
to a corn plant from frost primarily depends on temperature and
growth stage of the plant. Length of exposure to freezing
temperatures is another factor. A couple hours of freezing
temperatures typically is required for damage to plant tissue.
Temperatures between 32 and 28 degrees F typically have little
effect on corn. Frost damage is usually limited to above ground
plant parts (leaf tissue). Corn easily recovers from this type of
damage early in its development. Temperatures at 28 degrees F or
less for a few hours can be lethal to the plant. The growing point
of a young corn plant can be injured or killed at these
temperatures.
Living plant cells
contains water. Temperatures below 28 degrees F cause ice crystals
to form in the plant cells. As the ice crystals form, they expand
and puncture cell walls. As the temperatures rise during daylight,
the ice crystals melt back to a liquid. The punctured cells lose
water and nutrients and die. Frost damaged plant tissue often has a
water-soaked appearance. This appearance is due to the loss of
liquid from the punctured cells.
Freezing temperatures
can destroy plant tissue but only have a minor impact on final
yields. The growing point of corn plants are typically below the
soil surface from emergence until about the V5 growth stage in most
hybrids. The V5 growth stage is defined as a corn plant with five
leaves that have visible collars. At this stage, the sixth leaf is
visible in the whorl, but its collar is not yet visible. The soil
and the plant typically protect growing point from a couple hours of
freezing temperatures. Corn plants at this stage of growth can
experience high levels of leaf damage and still yield comparably to
non-injured corn.
The growing point of
corn will move above ground at slightly different stages of growth
in different hybrids. In general, the growing point is usually above
the soil surface by the V6 growth stage. Temperatures of 28 degrees
F or less for a couple hours will kill V6 corn and may severely
injure younger corn plants. Although the growing point is reasonably
protected by the soil from emergence through the V4-V5 growth stage,
it can be injured or killed even if it is still below the soil
surface if temperatures below 28 degrees F occur for more than a few
hours.
Managing Frost-Damaged Corn
You need to wait three
to five days after the frost event to accurately access the extent
of damage and determine if the plant are capable of recovery. By
five days, new growth should be evident in the whorl of the corn
plant. If new growth is not evident, then corn plant is likely dead.
Warm days after a frost event will benefit recovery, while cooler
temperatures will delay recovery. Wet conditions after frost damage
can induce pathogenic infections of the dead, moist plant tissue and
inhibit recovery.
At times, the frost
damage leaves will fuse together near the whorl. This fusing can
impede the new growth of leaves. Some farmers have tried mowing the
corn plants to resolve the problem of fusing. Mowing provides
inconsistent results and is not recommended.
If 55 to 70% of the
leaves are defoliated on V4 corn, but new growth is observed, then
nothing should be done to these plants. In most cases, the damaged
corn will yield as well as non-damaged corn. If 100% of the leaves
are defoliated, then wait to see if recovery is beginning by five
days after the frost. If recovery is not evident, then replanting is
probably a good option.
Estimated stand of
surviving plants is the most important item to measure about 5 days
after the frost event. Frost damage is likely uneven across the
field, so multiple stand counts should be made in the field. Both
injured and non-injured areas of the field should be counted. Count
the number of surviving plants within a row. Use Table 1 to
determine how long of a row to count to estimate plant stand.
Compare the number obtained in Table 1 to the population numbers in
Table 2 to help determine maximum yield. The information in Table 2
was obtained and adapted from the National Corn Handbook,
NCH-30, "Guidelines for Making Corn Replanting Decisions” and is
Table 5 in ID-139, “A Comprehensive Guide to Corn Management in
Kentucky”.
Table 2 should be
viewed as a general guide rather than an absolute rule. Most of the
data in the table is averaged across the Midwest and may need
adjustment for your particular area. For example, mid- to late-April
plantings in western Kentucky are closer to optimum than plantings
after May 10. The optimum date range shifts to early to mid-May for
central and eastern Kentucky. Populations above 25,000 plants per
acre should provide yields comparable to stands at 25,000 plants per
acre based on Kentucky research. Therefore, populations above 25,000
plants per acre will not need to be replanted.
The average corn stand
and the date of replanting will both be factors in determining if
replanting corn is an option. Other factors involved in a replanting
decision include the cost of operation for removing the surviving
corn stand and replanting. Seed costs and availability of suitable
hybrid seed are other factors to consider. If replanting will occur
after June 5 in Kentucky, then an earlier maturing hybrid should be
selected. In addition, corn yields will drop about 1% per day when
corn is planted after May 10 – 15.
If you have questions
regarding the condition of your corn crop, contact your county
extension office.
|
Table 1.
Estimating Corn Stand. Determine the length of row to count.
Count the plants within that row. Multiply that number by 1,000.
The product is the estimated number of plants per acre. This
process should be repeated throughout the field in injured areas
and non-injured areas. |
|
Row Width |
Length of Row to Count |
Number of Plants in Row |
Multiplication Factor |
Estimated plants / acre |
|
38 inches |
13’ 9” |
|
x 1,000 |
|
|
36 inches |
14’ 6” |
|
x 1,000 |
|
|
30 inches |
17’ 5” |
|
x 1,000 |
|
|
20 inches |
26’ 2” |
|
x 1,000 |
|
|
15 inches |
34’ 10” |
|
x 1,000 |
|
|
Table 2.
Grain yields for various planting dates and population
rates, expressed as a percent of optimum planting date and
population rate (uniformly spaced within row). |
|
Planting date |
Plants per
acre at harvest |
|
12,000 |
14,000 |
16,000 |
18,000 |
20,000 |
22,500 |
25,000 |
|
|
(% of
optimum yield) |
|
April 15 |
70 |
76 |
81 |
85 |
88 |
91 |
93 |
|
April 20 |
72 |
78 |
83 |
87 |
90 |
93 |
95 |
|
April 25 |
75 |
81 |
86 |
90 |
93 |
96 |
98 |
|
May 1 |
77 |
83 |
88 |
92 |
95 |
98 |
100 |
|
May 6 |
78 |
83 |
88 |
92 |
95 |
98 |
100 |
|
May 11 |
77 |
83 |
88 |
92 |
95 |
98 |
99 |
|
May 16 |
75 |
81 |
86 |
90 |
93 |
96 |
98 |
|
May 21 |
73 |
78 |
83 |
87 |
91 |
94 |
95 |
|
May 26 |
69 |
75 |
80 |
84 |
87 |
90 |
92 |
|
May 31 |
64 |
70 |
75 |
79 |
82 |
85 |
87 |
|
June 5 |
59 |
64 |
69 |
73 |
77 |
80 |
81 |
|
June 10 |
52 |
58 |
63 |
67 |
70 |
73 |
75 |
Back to Grain Crops Main Page |
Report Archives |
