Soybean seeding rates and optimum plant populations

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Deciding on the right seeding rate is one of the most influential factors for increasing soybean profitability as seed cost is one of the most expensive inputs.

Soybean seeding recommendations, row spacing, and planting date are all tied together. The final number of seeds per linear foot of row decreases as row spacing narrows. For example, at a target population of 105,000 plants per acre and 85 percent germination, 30-inch rows will need twice the number of seeds per linear foot as 15-inch rows -- 6 vs. 3 seeds per linear foot (Table 1). Seeding rates will need to increase at later planting dates to compensate for the reduction in the growing season since more plants are needed to increase early light interception and biomass production.

The environment also exerts an influence on deciding the final seeding rate. Dry and hot conditions require fewer plants to maximize yields; while favorable environments need higher seeding rates to capture the maximum yield potential. Under high-yielding irrigated environments, the final seeding rate should be greater than 160,000 seeds per acre (assuming high % emergence) with a final plant population close to 150,000 plants per acre.

Table 1. Recommended soybean plant density and seed spacing.


Target plants per acre (x 1,000)









Seeds per acre (x 1,000; 85% emergence)









Row Spacing

Seeds per linear foot (assuming 85% field emergence)





































Summary of past seeding rate studies

In recent years, a summary of 21 on-farm strip trials and 5 replicated experiment station studies in Kansas prepared by Kraig Roozeboom, K-State Cropping Systems Agronomist, provided an opportunity to revisit current soybean recommendations. Most of the studies were performed in dryland environments (23 out of 26, with 3 studies under irrigation) and under no-till systems. All were in central and eastern Kansas counties: Butler, Harvey, Nemaha, Republic, Riley, Saline, and Shawnee.

As related to final field establishment, the current recommendations assume 80% emergence. Emergence in the studies ranged from less than 50% to 100%, illustrating the importance of knowing just how many dropped seeds will produce plants in each situation (Figure 1). Studies that have compared planters and drills indicate that the 80% estimate is not far off for planters, but emergence for drills is usually closer to 65%. There is tremendous variability around both of these averages, but it illustrates the need to drop more seed per acre if field emergence is less than the 80% assumed for the current recommendations.

Figure 1. Percentage of field establishment and final seeding rate.

The primary conclusion from the summary of soybean seeding rate studies was that the optimum number of seeds per acre seemed to be highly dependent on the yield level attained at each location. Table 2 depicts the soybean seeding rate summary stratified by yield range.

Table 2. Recommended soybean plant density and seed spacing


A) Low yielding environments (test average <30 bushels per acre):

Yields were maximized at plant populations of less than 75,000 plants per acre. Optimum final plant population was achieved around 70,000 to 75,000 plants per acre (Figure 2). Thus, if we assume 80% emergence (as presented in Figure 1), the optimum seeding rate for this environment will range from 85,000 to 90,000 seeds per acre.

Figure 2. Optimum plant population, final plants per acre, for “low” yielding environments across Kansas, less than 30 bushels per acre.

B) Medium-low yielding environments (average ranged from 30 to 40 bushels per acre):

Yields were maximized with final plant populations around 75,000 to 80,000 plants per acre, presenting an evident plateau in maximum yield as the number of plants per acre increases beyond 80,000 plants per acre (Figure 3). Seeding rates ranging from 90,000 to 95,000 plants per acre were required to achieve these final plant populations (assuming overall 80% emergence).

Figure 3. Optimum plant population, final plants per acre, for “medium-low” yielding environments across Kansas, ranging from 30 to 40 bushels per acre.

C) Medium-high yielding environments (average ranged from 40 to 50 bushels per acre):

Yields were usually maximized at populations of 105,000 to 120,000 plants per acre in this yield environment. The break-even point for the association between yield and plant population was set at around 120,000 plants per acre (Figure 4). Increasing the population above 130,000 plants per acre did not increase yields. Considering an average 80% field establishment, optimum seeding rate for this yield environment was 140,000 seeds per acre.

Figure 4. Optimum plant population, final plants per acre, for “medium-high” yielding environments across Kansas, ranging from 40 to 50 bushels per acre.

D) High yielding environments (test average above 50 bushels per acre):

The highest yields, under irrigation, were achieved with 105,000 plants per acre (or close to 130,000 seeds per acre with 80% emergence; Table 2). There were relatively few experiments with yields in this range, so this may not represent a typical response. However, it does illustrate the tremendous ability of soybean plants to adjust the number of pods (and seeds) per plant to available resources. Other studies have shown that, given favorable growing conditions, yields of 80 to 90 bushels per acre can be achieved with 100,000 to 120,000 plants per acre.

Seeding rates for high-yielding soybeans

Information gathered from the Kansas Soybean Yield contest shows that maximum yield (more than 90 bushels per acre) could be achieved with 120,000 seeds per acre, with yields tending to decrease from the maximum when seeding rates were above 180,000 seeds per acre (Figure 5). Maximum yield for soybeans did not seem to change for the seeding rate ranging from 120,000 to 150,000 seeds per acre. Before deciding your seeding rates, also take into consideration potential soil and weather conditions that could affect the success of your final stand establishment.

Figure 5. Yield versus seeding rate relationship for Kansas Soybean Yield contest data.


Always take into consideration the yield potential for each environment when deciding soybean seeding rates. Yield potential is primarily defined by the weather conditions (before and after planting), genetic potential, soil type and supplemental fertility program, and use of best management practices for producing the crop (proper weed, insect, and disease control from planting until harvest). Using seeding rates higher than those recommendations seldom reduced yield, but did increase seeding cost.

For more information, see Kansas Soybean Management 2018, MF-3154, available online at:

On-farm soybean seeding rate studies

During the 2016 growing season, several on-farm research studies were established in collaboration with Kansas Soybean, United Soybean Board (USB), and K-State Research and Extension. The experimental layout, field variability, and strip-trial position in the field for those studies are presented below.

Experimental layout

An example of the experimental design proposed for the 2016 soybean seeding rate trials is presented below. In this example, four seeding rate levels were investigated with four replications (completely randomized) in all 16 soybean strips.

Yield outcomes

In this example, four seeding rates were evaluated in an east central Kansas location (Figure 6). Maximum soybean yield (single strip, replication) was approximately 57 bushels per acre, with a narrow variability among all treatments of 53 to 57 bushels per acre. At this site, increasing seeding rates did not significantly promote an improvement in yields, with a yield difference of 0.6 bushel per acre between the seeding rates of 70,000 (55.8 bushels per acre) and 160 thousand (56.4 bushels per acre) seeds per acre.

Figure 6. 2016 on-farm soybean seeding rate study.

Similar soybean seeding rate studies were performed in 2016 in collaboration with Extension agents and producers, resulting in diverse soybean yield responses to seeding rates.

The example above is just one study and one site. Thus, one should be careful in interpreting the results. The goal of this information is to motivate producers to perform more on-farm research evaluations and to understand the complexity of our soybean farming systems. In addition to this, the on-farm data emphasizes the need for further site-specific, on-farm evaluations on the response of yields to seeding rates and how management practices interact with the environment.

For more information of previous studies and other states, please visit:





Ignacio Ciampitti, Crop Production and Cropping Systems Specialist