Publication Number 424-027, Posted April 1997
Nitrogen
Fertilizer Recommendations
Phosphorus
Fertilizer Recommendations
Corn must have adequate amounts of nitrogen (N) and phosphorus (P) for profitable production. Nitrogen and phosphorus are also the nutrients that produce excessive algae growth in surface waters when concentrations increase above certain critical levels. Profitable and environmentally sensitive corn production requires that N and P be managed in an efficient manner. Economic returns from the use of these nutrients can be maximized, while the potential for surface and groundwater enrichment with N and P can be minimized with the use of appropriate technology. Available technology includes soil testing to evaluate residual soil nutrient supplies, and the use of proper application rates, methods, and timings. The purpose of this publication is to summarize general corn fertilization principles and the most recent research-based recommendations on the use of N and P in Virginia corn production. Although the focus of this article is on N and P, a balanced fertility program including adequate amounts of potassium (K), sulfur (S), and micronutrients is necessary for efficient corn production.
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The corn plant grows and accumulates dry weight as shown in Figure 1 (Hanway, 1963). Nitrogen and P uptake follows the same general trend as plant growth. The maximum N uptake occurs during the month prior to tasseling and silking (Fig. 1). Significant amounts of N are transferred from leaf tissue to grain during the grain-fill process. Phosphorus uptake is more constant throughout the season and generally parallels dry weight increases (Fig. 2). The major objective of an efficient fertilization program is to be certain that adequate N and P are available during the growing season so that plant growth and yields are not limited by nutrient supplies.
The corn plant requires N and P soon after germination to initiate the
growth of stems, leaves and ear structures. Inadequate N availability during
the first two to six weeks after planting can result in reduced yield potentials
(Jones, 1985). However, the majority of N is needed during the period of
maximum growth (month prior to tasseling and silking,
Fig. 1). Sidedress
N fertilizer applications insure that N is available during this period
of highest need. Also, the potential for leaching losses is greatly reduced
with sidedress N applications because of high water uptake and transpiration
by the corn plant during this period of rapid growth. The warm temperatures
associated with rapid corn growth increase soil water evaporation and transpiration
rates which reduce nitrate leaching potentials.
Phosphorus availability is equally critical during the early stages of plant growth because the movement of P to plant roots is reduced with cold soil temperatures. Thus, P deficiencies are most often observed during the early part of the growing season. However, P moves very little in soils, and thus, available soil P levels can be built with P fertilizer applications, or applications of manures. Many Virginia agricultural soils have a history of P fertilization, and a recent survey estimates that 58% of Virginia soils test high to excessive in available P (Sharpley et. al., 1994). High plant-available P, as identified by soil testing, indicates that no crop yield response can be expected from additional P fertilizer applications. Excessive soil- available P may cause environmental problems when soil containing these excessive levels of available phosphorus erodes into surface waters.
Early-season nutrient availability is influenced by fertilizer placement.
Germination and emergence of the corn seedling usually occurs in six to
ten days with reasonable temperatures and moisture. The corn seedling can
be expected to develop two fully-expanded leaves and a primary root system
that obtains needed nutrients from the soil within seven days after emergence
(Aldrich et al., 1986). The supply of nutrients in the seed will be exhausted
by this time (seven days after emergence). The corn plant roots generally
do not reach the middle of the rows until the corn plant has eight fully
emerged leaves, which is about the time the corn is knee-high. Therefore,
during approximately the first six weeks after planting, nutrients that
are band-placed close to the corn row are more likely to be available for
corn-plant uptake than if the same amount of nutrients were broadcast over
the entire soil surface.
An example of enhanced N availability from starter-band placement is
shown in
Fig. 3. The percent N in whole corn plant tissue samples collected
six weeks after planting (knee-high) was approximately the same with either
a starter-band application of 30 lbs N/acre, or a surface broadcast application
of 60 lbs N/acre plus 10 lbs N/acre in a starter-band. The starter-band
applied N was more efficient in supplying N to the young corn plants.
In addition to enhanced availability with starter-band placement of fertilizer,
N placed on the soil surface is subject to several reactions that can result
in loss or limit its availability to the corn plant. First, urea forms
of N are subject to volatilization losses if the conversion of urea to
ammonium occurs while the fertilizer is on the soil surface. Losses can
be as high as 30% of the applied urea N if temperatures are warm and rainfall
to move the urea into the soil does not occur within three to four days
after application (Scharf and Alley, 1988). In addition, N applied to fields
with high levels of residue (i.e. no-till) is subject to utilization by
the microbes that are decomposing the residue. Finally, surface-applied
N fertilizers are subject to runoff losses when heavy rainfall occurs soon
after application. Band placement of N fertilizers below the soil surface
eliminates the potential for volatilization and runoff losses and removes
the N from the zone of highest microbial decomposition in no-till production.
However, a major concern with band placement of fertilizer near the germinating
seedling is salt injury. Standard starter-band placement is 2 inches to
the side and 2 inches below the seed (2 x 2 placement). The band must be
properly placed to avoid salt injury, especially at high rates of starter
band fertilizer. Nitrogen and K are the two nutrients that can cause "salt
injury." A general rule for application rate is that the starter-band
should contain no more than a total 80 lbs per acre of N plus K2O. Growers
must be certain that the fertilizer placement attachment on the planter
is properly positioned, and all openers are placing the fertilizer band
at least 2 inches from the seed and approximately 2 inches below the seed.
Any error in placement must be farther from the seed rather than closer
than 2 x 2 in order to prevent damage to the emerging seedlings.
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Total N fertilizer applications are governed by the yield potential of individual soil series. Soils that enable deeper rooting depths and have high water-holding capacities will produce greater corn yields than soils with physical properties that restrict root growth, or soils that have sandy textures with low water-holding capacities. Crops grown on soils with higher yield potentials can efficiently utilize higher N fertilizer applications than crops grown on soils with lower yield potentials. Fertilizer N rates should vary with the soil series yield potential, which is mainly a function of plant-available water supplying capacity. General guidelines for corn production potentials for individual soil series can be found in the Virginia Land Use Evaluation System (Simpson et al., 1993). However, grower yield records, whenever available, should be used to establish yield potentials for individual soils and fields.
Research has shown that when efficiently applied, total N rates of 1.0 to 1.25 lb N per bushel of yield potential are adequate to optimize yields. However, obtaining a high N-use efficiency of 1.0 lb N per bushel of corn yield generally requires splitting the N between a starter-band application and a side-dress application.
Starter-band N Rates
Recent research in Virginia that studied starter-band N rates ranging from 10 to 70 lbs N/acre placed in a 2 x 2 band produced the data shown in Table 1. Optimum starter-band rates were determined by analyzing corn yield increases versus the cost of the N required to obtain the yield increase. The average optimum N rate ranged from 27 to 70 lbs of N per acre with the optimum N rate for the nine experiments over two years averaging 60 lbs N/acre. The N rates utilized in these studies were higher than rates evaluated in past experiments because the previous starter-band research had focused on optimizing P rates. Earlier studies used fertilizer materials such as 10-34-0 (ammonium polyphosphate solution) or 18-46-0 (diammonium phosphate). Our research used blends of urea-ammonium nitrate (30% N) solution as the N source, and 10-34-0 as the P source. Dry granular blends of urea and 18-46-0 (DAP) or 10-51-0 monammonium phosphate (MAP) would be expected to produce the same crop responses as the liquids used in these studies. Research in Indiana and Kentucky supports the concept that N is the most important ingredient in starter fertilizers for no-till corn production on soils testing high in plant-available P (Mengel, 1990; L. W. Murdock, Univ. of KY, 1997, personal communication).
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Table 1. Optimum starter-band (2 x 2) and sidedress N rate combinations for 9 no-till corn experiments conducted over two growing seasons.
Detailed analysis of the starter-band placement data (data not shown)
demonstrated that essentially all the yield advantage for the higher starter-band
N treatments could be obtained with a 50 lb N/acre starter-band application.
The 50 lb N/acre starter-band application reduces the potential for salt
injury compared with a 60 lb N/acre application, and it produces almost
all of the yield increase associated with the average 60 lb N/acre optimum
found in these experiments
Therefore, the general recommendation for starter-band N application is
to apply 50 lbs N/acre placed in a 2 x 2 band at planting. This placement
minimizes N losses due to volatilization, microbial fixation, and runoff,
and provides ample supplies of N in close proximity to the young corn root
system. Also, a 50 lbs N/acre starter-band application provides adequate
N to the corn plant for a longer period of time should field conditions
delay side-dressing. It is extremely important that the starter-band
fertilizer be placed at least 2 inches from the seed to avoid potential
salt injury.
Optimum side-dress N rates varied from 0 to 125 lbs N/acre in the experiments
reported in
Table 1. This wide range of optimum side-dress N rates is typical
of Virginia conditions and is the result of two factors. First, large amounts
of N can be released from sources such as manures or previous legume crop
residues. Nitrogen release from organic materials (mineralization) increases
with increased microbial activity at higher soil temperatures. When fields
have a history of manure utilization, or the corn crop is following a legume
such as alfalfa, the pre-side-dress soil nitrate test (PSNT) (Evanylo and
Alley, 1996) should be used to assess the release of mineral N from the
organic residues. The PSNT procedure has been shown to be effective in
Virginia and surrounding states for identifying fields that do not need
additional N fertilization at side-dress. Thus, a starter-band N application
of 50 lbs N/acre can be used to get the corn crop started, and the PSNT
can be used to determine if side-dress N is needed. Soil samples for the
PSNT must not be taken from the soil where the starter-band has been placed.
The second and most important factor that causes widely varying optimum
side-dress N rates for corn grown in Virginia is drought stress during
silking and tasseling. Drought stress cannot be predicted in any specific
season, but long-term, realistic yields for the specific soil series are
currently the best way to determine side-dress N rates. Although the realistic
yield may not always be achieved, the combination of starter-band and side-dress
N is the most effective means of insuring that N does not limit crop yields,
and that the applied N is utilized efficiently.
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Phosphorus fertilizer recommendations are based on plant-available soil test P levels that have been established for many years. The use of soil tests such as the Mehlich I and Bray P1 tests is based on P being relatively immobile in soil, and on crop response to applied P fertilizer being related to the soil test P level. Tests such as the Mehlich I and the Bray P1 have been used successfully for many years. However, there is a legitimate concern that as corn yield levels increase, the soil test levels necessary to insure adequate P availability may need to be increased. We recently conducted several experiments to determine responses to P fertilization at Mehlich I soil test levels typical of Virginia soils.
Data from nine experiments are shown in Table 2. These experiments involved the application of starter-band P at rates of 0, 20, 40, and 60 lbs P2O5/acre with optimization of all other production factors to achieve highest possible yields. Mehlich I soil test levels ranged from 8 to 60 ppm available P. There was only one grain yield response to applied P in these experiments in which grain yield levels were reasonably high for the specific growing seasons. The conclusion from these data is that the current soil test calibration levels for plant-available P are adequate and do not need to be revised.
In summary, soil test P levels are adequate indicators of corn grain yield response to applied P. The calibration of soil tests is such that no grain yield responses will be expected when soil test P levels are in the high (H) to very high (VH) range. All fields should be tested for plant-available P and applications made according to soil test levels.
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Available P |
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Test Yield bu/acre |
| Pamunkey sil | 7 | M+ | No | 87 |
| Slagle sil | 41 | H | No | 149 |
| Pamunkey fsl | 22 | H- | No | 142 |
| Slagle sl | 16 | M+ | No | 147 |
| Turbeville sl | 49 | H+ | No | 95 |
| Cullen l | 8 | M- | No | 116 |
| Eubanks sil | 60 | VH | No | 110 |
| Ross l | 17 | M+ | Yes | *** |
| Pamunkey sil | 12 | M | No | 143 |
Table 2. Corn grain yield response to starter-band applied phosphorus.*
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Aldrich, Samuel R., Walter O. Scott, and Robert G. Hoeft. 1986. Modern
Corn Production. 3rd edition. A & L Publications, Inc., Champaign,
IL.
Evanylo, G. K. and M. M. Alley. 1996. Nitrogen soil testing for corn in
Virginia. Virginia Cooperative Extension Publication
418-016. Virginia
Tech, Blacksburg, VA.
Hanway, J. J. 1963. Growth stages of corn (Zea mays, L.). Agron. J. 55:487-492.
Jones, C. A. 1985. C4 grasses and cereals: growth, development, and stress
response. John Wiley & Sons, Inc., New York.
Mengel, D. B. 1990. Fertilizing corn grown using conservation tillage.
Agronomy Guide, AY-268. Purdue Univ. Coop. Ext. Service. West Lafayette,
IN.
Scharf, Peter C. and M. M. Alley. 1988. Nitrogen loss pathways and nitrogen
loss inhibitors: A review. J. of Fertilizer Issues 5:109-125.
Sharpley, A. N., S. C. Chapra, R. Wedepohl, J. T. Sims, T. C. Daniel, and
K. R. Reddy. 1994. Managing agricultural phosphorus for protection of surface
waters: issues and options. J. Environ. Qual. 23:437-451.
Simpson, T. W., S. J. Donohue, G. W. Hawkins, Margaret M. Monnett, and
J. C. Baker. 1993. The development and implementation of the Virginia Agronomic
Land Use Evaluation System. Dept. of Crop and Soil Environmental Sciences,
Virginia Tech, Blacksburg, VA, 83 pgs.
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