6 - 8
Students determine corn anatomy and function of plant parts, identify stages of plant development in corn, and research how temperature plays a role in corn growth as they calculate growing degree units (GDUs) for a region. Grades 6-8
Three 45-minute activities
- Phenomenal Corn student handout, 1 copy per student or student group
- Corn Comparison image, digital display
- Explore an Ear of Corn student handout, 1 copy per student
- Corn plant to observe. Choose from the following:
- Mature corn plant from a garden or field
- Image of a mature corn plant
- Corn Dissection student handout, 1 copy per student or student group
- Heavy-duty sciessors (dissecting/kitchen shears) or utility knife
- Cutting boards/table protector
- Corn plants, 1 or 2 per student group
- Growing Degree Days student handout, 1 copy per student or student group
- Device with internet access
- Corn plant (from Activity 2)
commodity: a primary agricultural product that can be bought and sold
Growing Degree Units (GDUs): a measurement of the amount of heat needed for a corn plant to reach various stages of growth
husk: a dry outer covering of some fruit, seeds, or nuts
kernel: a softer, usually edible part of a nut, seed, or fruit stone contained within a hard shell
leaf: the flat or needlelike part of a plant where photosynthesis happens
node: the part of a plant stem from which one or more leaves emerge, often forming a slight swelling or knob
reproductive plant growth: the stage of plant growth where flowers and fruit are formed
root: the part of the plant that grows into the soil to anchor the plant and collect water and nutrients
silks: the female parts of the corn plant which are found in the shoot that will develop into the ear of corn
tassel: the male part of a corn plant that emerges from the top of the plant and bears many small flowers that release pollen grains
vegetative: a period of plant growth between germination and flowering
Did You Know? (Ag Facts)
- There is one silk for every kernal that grows in an ear of corn.1
- Corn is a ceral crop that is part of the grass family.1
- Corn can be used as a sweetener. A bushel of corn can sweeten 400 cans of soft drink.1
Background Agricultural Connections
Corn is a grass, native to the Americas. Evidence in central Mexico suggests corn was used there about 7000 years ago. Various Native American tribes shared their knowledge of corn, also known as maize, with early European settlers saving many from starvation. Early American colonists ground dried corn as meal for flour to use in porridge, cake and bread. Sweet corn, served as “corn on the cob,” was not developed until the 1700s.
Along with wheat and rice, corn is one of the world’s major grain crops and the largest grain crop grown in the US. About 9% of all corn is used to produce food for humans: corn meal, cooking oils, margarine, corn syrups, and sweeteners (fructose). About 64% of all corn is used as feed for livestock. Corn is harvested for either grain or silage with most of the grain going to dairies, animal feeding operations, and poultry operations. Corncobs have been used in the manufacturing of nylon fibers and as a source for producing degradable plastics. Ethanol, made from corn, is a renewable fuel used in today’s cars.
Corn is pollinated by wind and is typically planted in 30-inch rows. A single seed, or kernel, of corn may produce a plant which yields more than 600 kernels of corn per ear. Approximately 22,000 to 35,000 individual plants may be grown on an acre of land. Hybrid corn is developed to produce from one to two ears per plant. More than 80 million acres of the US heartland are planted in corn each year.
After the corn is harvested, the farmer begins to prepare the soil for the next season by mixing in nutrients, such as potassium and phosphorus, with some form of tillage (breaking up soil) to incorporate them. In the spring, the farmer will do a light tillage pass to create smooth bedding for planting. When the ground temperature is ready (50°F and expected to rise), the farmer will plant and add fertilizer 2 inches deeper and 2 inches to the side of the kernels to help the seeds get a healthy start. After the seed is planted, most farmers will spray a pre-emergent herbicide to prohibit weed growth. When seedlings emerge and grow, the farmer will inject the soil with some form of nitrogen fertilizer before the v8 (8th leaf development) stage. This spring fertilizer will allow for the plant to green up and establish good photosynthetic activity through harvest. The farmer will continue to scout the crop through maturity for any additional pests and will harvest the crop when it is ripe in the fall.
Corn Anatomy and Physiology
Corn growth and development for commodity agriculture is dependent upon our understanding of corn anatomy and functionality. To gain a good understanding of corn anatomy and functionality you can visit the University of Minnesota All About Corn E- learning modules and Ohio State University's Corn Growth and Development website.
Stages of Corn Development
Corn is an integral component to the success of agriculture. Throughout the growing season, the corn plant undergoes a series of developmental stages as it grows from a seed at planting to a tall plant with an ear at harvest. The development of the corn plant is determined by different Vegetative (V) and Reproductive (R) stages. Please see the attached Corn growth and development poster: bookstore.ksre.ksu.edu/pubs/MF3305.pdf for details on the Vegetative and Reproductive Stages a corn plant undergoes throughout its development. V stages are determined by the total number of leaves with visible collars (e.g., a plant with 3 visible leaf collars is at V3). A collar is the offwhite band at the base of the leaf blade where it extends away from the stalk. A new leaf appears every 3 to 4 days with good growing conditions until tasseling. As the plant grows, lower leaves are lost. These leaves must be counted; otherwise, the development stage will be misidentified.
Corn needs little fertilizer boost until V5, but requires a large nitrogen intake to increase yield from V8 until VT (tasseling). Farmers sidedress (inject between corn rows) nitrogen before the V8 stage. This allows the plant to maximize its photosynthetic potential. Ear length is determined between the V12 and VT vegetative stages. Tassel emergence occurs from V17 to V22 depending upon the corn variety.
The growth rate of a corn plant is slow at the beginning of the season, but increases with the presence of each new leaf. Under non-stressful conditions, the time between new leaves will decrease as the season progresses. The plant is most vulnerable to stress during silking, when important pollination events are occurring. As the reproductive stages progress, the effect of stress on seed weight will decrease, while the effect on seed number will be minimal after R2. Highest yields will be achieved in areas where environmental conditions are favorable for these growth stages, especially R1. Unfavorable conditions early in the season will limit leaf size, which will decrease photosynthesis, while stress later in the season can affect pollination in the form of kernel size and number.
Growing Degree Days
Corn growth stage development can vary according to corn maturity. An early-maturing product may produce fewer leaves or develop through growth stages faster than a slower-paced, latematuring product. This is important to remember when staging corn in relation to accumulated Growing Degree Units (GDUs).
Corn development is directly correlated with air temperature. Therefore, development varies from year to year if calendar days are only used to track progress. However, development becomes predictable within and across growing seasons when evaluated using thermal time (degree units). The time required for corn to progress from one developmental stage to another is based on the amount of heat accumulated. Thermal time represents the length of time the crop spends within a defined temperature range considered optimum for that crop. For example, shoot emergence occurs approximately 125 Growing Degree Units (GDUs) accumulate after emergence. The GDU calculation assumes that corn development is consistent and linear within the defined temperature range of 50–86°F. For more information, visit Corn Growth Stages and Growing Degree Units.
Interest Approach - Engagement
- Display the Corn Comparison image for students to see.
- As students analyze the images, ask them to brainstorm individually or in groups possible scenarios that could produce the two different corn crops.
- Give each student or student group one copy of the Phenomenal Corn student handout to record their observations.
- If needed, use the following questions as prompts:
- What types of plants are depicted in each image?
- How is the environment different in each photograph?
- What is the difference between the plants in each image?
- Why is there a different population (total number) of plants in each image?
- What factors lead to productive corn growth?
- What factors lead to stunted corn growth?
- Pose the question, "How can we make food production less of a gamble?
- Help students recognize that climate, nutrition, and competition for resources play an important role in the growth of plants. They will be exploring how production practices can mitigate the effects of these factors in order to increase the health and yield of plants.
- Refer to the Phenomenal Corn—Teacher Key to find options for differentiation in the classroom, answers to the reflection questions, and a rubric to evaluate the assessment.
Activity 1: Explore an Ear of Corn
What do you know about this familiar plant? How do the parts of the corn plant work to produce an ear of corn?
- Give each student or student group a copy of the Explore an Ear of Corn student handout.
- Provide a mature corn plant or projected image of a corn plant for students to study.
- Ask students:
- What does a plant need to grow and develop?
- How does a corn plant produce and store energy?
- How does a corn plant transport water and nutrients throughout the plant?
- How does a corn plant reproduce?
- If needed, refer students to the Biology of Corn modules and/or Parts of a Corn Plant to complete their worksheets.
- Watch Corn Reproduction to help students understand the role each plant part plays in reproduction.
- Refer to the Explore an Ear of Corn—Teacher Key to find options for differentiation in the classroom, answers to the reflection questions, and a rubric to evaluate the assessment.
- Students should be able to summarize that the parts of the corn plant work together to produce an ear of corn.
Activity 2: Corn Dissection
What can the corn plant tell us? How can we tell what growth stage the corn plant is in?
- Prior to class, obtain corn plants from a garden or agricultural field the night before or morning of the dissection. Dig out the entire plant, including the roots. Wash the roots of the plant for student observation and dissection. Place plants in a bucket of water until the dissection.
- Give each student or student group a copy of the Corn Dissection student handout.
- Review the instructions, provide lab materials, and give safety instructions prior to allowing students to complete the lab.
- Refer to the Corn Dissection—Teacher Key to find options for differentiation in the classroom, answers to the reflection questions, and a rubric to evaluate the assessment.
- Students should be able to summarize that the plant's growth stage can be determined by observing the plant anatomy.
Activity 3: Growing Degree Days
What role does air temperature play in crop production?
- Ask students:
- What is our local climate?
- Do we have an average summer temperature range between 50° F and 86° F? (the minimum daily temperature (Tmin) and the maximum daily temperature (Tmax) for corn growth.)
- Assign students to research the annual average number of growing degree days for your area.
- Give each student one copy of the Growing Degree Days student handout.
- Review the instructions as a class and assign students to complete the handout.
- Refer to the Growing Degree Days—Teacher Key to find options for differentiation in the classroom, answers to the reflection questions, and a rubric to evaluate the assessment.
- Students should be able to summarize that corn growth stages are specific to regional climate and plant data and recognize that hybrid varieties are selected based upon regional growing degree units and yield.
Concept Elaboration and Evaluation
After conducting these activities, review and summarize the following key concepts:
- Corn is grown for human food, livestock feed, and ethanol.
- To harvest corn, the life cycle of the plant must be complete. This includes the vegetative and reproductive stages.
- Plants utilize energy from the sun through the process of photosynthesis.
Watch The History of the World According to Corn by Chris A. Kniesly.
Suggested Companion Resources
Nourish the Future
Nourish the Future