Sandramere Seed & Supply

Corn Planting Depth: Soil Temperature and Moisture Flux in the Furrow

Key Findings

  • Shallow planting shortened the time to the start of corn emergence, but lengthened the duration of emergence.
  • Soil moisture was lower and more variable closer to the soil surface, which likely contributed to the less-uniform emergence with shallower planting.
  • Planting depth affected yield in a higher organic matter field, but had no effect in a lower organic matter field. 

Objectives

  • A three-year field study was conducted to assess effects of soil temperature and moisture flux on emergence of corn planted in fields with varying soil classifications and characteristics, and to determine the impact of planting depth on emergence and yield.
  • This research was conducted by Dr. Peter Thomison and Dr. Alex Lindsey, Ohio State University, as a part of the Pioneer Crop Management Research Awards (CMRA) Program.

Study Description

  • Years: 2017 to 2019
  • Location: South Charleston, Ohio
    • Field 1: Strawn-Crosby silt loam (2.0-3.1% organic matter)
    • Field 2: Kokomo loam (3.8-4.6% organic matter)
    • Research fields were within 0.5 miles of each other, so were subject to similar weather conditions
  • Planting Dates:
    • May 16 (2017), May 11 (2018), June 4 (2019)
  • Previous Crop: Soybean (all years)
  • Nitrogen Fertility Program:
    • 2017-2018: 180 lbs N/acre applied as anhydrous ammonia
      (82-0-0) prior to planting
    • 2019: 180 lbs N/acre applied as UAN (28-0-0) at V6 (program changed due to excessive spring rain in 2019)
  • Seeding Rate: 35,300 seeds/acre
  • Hybrid/Brand¹: P1197AM™(AM, LL, RR2)
  • Experimental Design: Randomized complete block design with four replications of planting depth treatments; plots were 10 x 150 ft (four 30-inch rows)
  • Planting Depth (Targeted):
    • 1 inch, 2 inches, 3 inches

Data Collection and Analysis

  • A combination soil moisture and soil temperature sensor (CS655, Campbell Scientific) was installed at seeding depth in each plot. Once installed, the sensors were connected to a datalogger and continuously recorded average temperature and soil moisture every twenty minutes until the V3 growth stage.
  • Soil moisture data was adjusted to plant available water content (AWC) for each field using field-specific calibrations (AWC of 100% = field capacity; AWC of 0% = permanent wilting point).
  • Emergence curves were modeled using a sigmoid function:

    Illustration - Corn plant emergence curve equation.

  • where Emerget (emergence at point t) is the dependent variable, x is days after planting (DAP) or soil accumulated growing degree days (GDDs, 50 F base), and a, b, c, d were the model parameters used to best fit the equation.

Results

  • Actual planting depths for the 2 and 3 inch treatments were slightly less than the targeted depths in both fields (Table 1).
  • Emergence in the higher organic matter field was delayed slightly compared to the lower organic matter field.
  • The time to 50% emerged for all depths was within 0.8 days and 5.8 GDDs for the low organic matter field, and within 0.6 days and 11.0 GDDs for the high organic matter field.

Table 1. Actual depth to seed, time to 50% emergence (T50) and the time from 10% emergence (T10) to 90% emergence (T90) as measured in calendar days and soil accumulated growing degree days for each planting depth treatment and field.

  • In both fields, the patterns of emergence differed with planting depth. Emergence commenced earliest with the shallowest planting depth, but also had the longest emergence window (time from 10% to 90% emerged). 

Line Graph - Cumulative corn plant daily emergence and available water content for 1, 2, and 3-in planting depths in low organic matter and high organic matter fields.

Figure 1. Cumulative daily emergence and available water content for the 1, 2, and 3-in planting depths in the Crosby (low organic matter) and Kokomo (high organic matter) fields. Models were built for data collected from 2017-2019.

Line Graph - Cumulative emergence and available water content for 1, 2, and 3-in planting depths in low organic matter and high organic matter fields as influenced by soil growing degree day accumulation.

Figure 2. Cumulative emergence and available water content for the 1, 2, and 3-in planting depths in the Crosby (low organic matter) and Kokomo (high organic matter) fields as influenced by soil growing degree day accumulation. Models were built for data collected from 2017-2019.

  • The longer emergence window with shallow planting can be seen in the flatness of the sigmoidal curves in Figure 1, where model parameters b and c were significantly different (P < 0.05) between the 1-in and 3-in emergence curves in both fields.
  • The longer emergence window with shallower planting may have been due to differences in available water content at planting, where AWC was 20-25% less at the shallowest depth.
  • Soil water increased after approximately 3 days in the trials due to timely rainfall (Figure 1).
  • Emergence began latest with 3-inch planting depth in both fields (Figure 1), but exhibited the shortest T10-T90 interval (Table 2).
  • When evaluating emergence as driven by soil accumulated GDDs, the patterns changed from calendar dates slightly (Figure 2).
  • The difference between emergence curves for the 1-inch and 3-in depths were no longer evident in the low organic matter field, but were still evident in the high organic matter field.
  • This was also reflected in the T10-T90 values, where the low organic matter field differed by 2.7 GDDs between depths but the high organic matter field differed by 38.6 GDDs (Table 1).

Photo - Installation of soil moisture and temperature sensor in corn row furrow in 2017.

Installation of the soil moisture and temperature sensor in furrow in 2017.

  • Planting depth did not affect plant biomass at the V3 growth stage, dominant ear leaf number, total leaf number, percent of runt plants, or stalk strength (data not shown).
  • Planting depth did impact kernel per ear and had a marginal effect on total kernel dry weight per plant (Table 2), where the greatest values were observed at the 3-in depth.
  • Basal emptiness was greatest with 1-inch planting depth.
  • The difference in total kernel number may have been driven by improved pollination or decreased kernel abortion leading to marginally greater kernel numbers per row (data not shown).
  • Across years, there was a significant (P = 0.030) planting depth by field interaction for corn yield (Table 3).
    • Yields were similar across planting depths in the low organic matter field (ranging from 213 to 217 bu/acre).
    • In the high organic matter field, corn yield was significantly lower with the 1-inch planting depth compared to the 2-inch and 3-inch depths.
    • Lower yield with shallow planting may have been a result of the longer emergence window (T10-T90) as shown in Table 1.

Table 2. Ear yield components as impacted by planting depth across fields. There were no significant field or depth by field interactions for any yield component. Data were combined across 2017-2019 for analysis.

Table - Corn ear yield components as impacted by planting depth across fields.

Table 3. Grain yield as affected by planting depth across years. Letters denote differences for the interaction of field by planting depth.

Table - Corn grain yield as affected by planting depth across years.

Conclusions

  • Planting depth impacted emergence patterns in both a higher and lower organic matter field.
  • In each field, the emergence was most uniform at the 2-inch and 3-inch planting depth settings, which resulted in actual depths of 1.7-2.1 and 2.5-2.7 inches on average, respectively.
  • Although first emergence was delayed in the 3-inch depth treatment compared to the 1-inch depth, the final emergence was reached more rapidly at the 3-inch depth compared to the 1-inch depth.
  • Less uniform emergence with shallow planting was likely driven by lower and more variable soil moisture in combination with faster temperature accumulation.

Authors: Alex Lindsey and Peter Thomison
April 2020

Research conducted by Dr. Peter Thomison and Dr. Alex Lindsey, Ohio State University, as a part of the Pioneer Crop Management Research Awards (CMRA) Program. This program provides funds for agronomic and precision farming studies by university and USDA cooperators throughout North America. The awards extend for up to four years and address crop management information needs of Pioneer agronomists, sales professionals and customers.

Optimum AcreMax
Herculex I
LibertyLink
Roundup Ready Corn 2
YieldGard Corn Borer


AM - Optimum® AcreMax® Insect® Protection system with YGCB, HX1, LL, RR2. Contains a single-bag integrated refuge solution for above-ground insects. In EPA-designated cotton growing counties, a 20% separate corn borer refuge must be planted with Optimum AcreMax products. YGCB - The YieldGard® Corn Borer gene offers a high level of resistance to European corn borer, southwestern corn borer and southern cornstalk borer; moderate resistance to corn earworm and common stalk borer; and above average resistance to fall armyworm. HX1 - Contains the Herculex® I Insect Protection gene which provides protection against European corn borer, southwestern corn borer, black cutworm, fall armyworm, lesser corn stalk borer, southern corn stalk borer, and sugarcane borer; and suppresses corn earworm. LL - Contains the LibertyLink® gene for resistance to Liberty® herbicide. RR2 - Contains the Roundup Ready® Corn 2 trait that provides crop safety for over-the-top applications of labeled glyphosate herbicides when applied according to label directions. Herculex® I Insect Protection technology by Dow AgroSciences and Pioneer Hi-Bred. Herculex® and the HX logo are registered trademarks of Dow AgroSciences LLC. Liberty®, LibertyLink® and the Water Droplet Design are registered trademarks of BASF. Roundup Ready® is a registered trademark used under license from Monsanto Company.

The foregoing is provided for informational use only. Please contact your Pioneer sales professional for information and suggestions specific to your operation. 2017-2019 data are based on average of all comparisons made in two locations through Dec. 1, 2019. Multi-year and multi-location is a better predictor of future performance. Do not use these or any other data from a limited number of trials as a significant factor in product selection. Product responses are variable and subject to a variety of environmental, disease, and pest pressures.  Individual results may vary. Pioneer® brand products are provided subject to the terms and conditions of purchase which are part of the labeling and purchase documents. ¹All Pioneer products are hybrids unless designated with AM1, AM, AML, AMT, AMRW, AMX, AMXT, and Q in which case they are brands.