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How Tall Can Your Amaranth Plant Grow? Factors That Affect Height

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Amaranth originated in South America and has been cultivated for centuries. It is grown as a high quality, gluten-free grain, and occasionally used as a leafy vegetable as well. While the seeds are sold as a grain, it is a broad-leaved plant and not a grass as are most grains. There are three species of amaranth normally grown in the United States: Amaranthus cruentus, A. caudatus and A. hypochondriacus. All are related to another amaranth species, redroot pigweed, but have not proven to be weeds where they are being grown.

Amaranth grain plants are large and bushy, often reaching over 6 feet in height. They have a thick central stem, large fleshy leaves and numerous small, tightly clustered, bright-colored flowers that grow in a large group on the tops of the stems. Flower color can range from bright burgundy to pink, yellow and green. The seeds are very small with approximately 850,000 seeds in a pound. This makes successfully planting amaranth a challenge.

They are annual, warm-season plants and not frost tolerant. As such, amaranth should be planted when soil temperatures exceed 60 degrees Fahrenheit and after the last expected frost.

Interest in non-gluten grains such as amaranth is increasing as more individuals are being diagnosed as gluten-intolerant. Individuals exhibiting gluten intolerance are considered to have Celiac disease and a 2012 study found that approximately 1 in 141 people in the United States suffer from this condition, with most going undiagnosed. Currently amaranth grain is used in more than 40 products in the U.S. Amaranth production in western Nevada was evaluated from 2008 through 2010 as part of Walker Basin project.

In late May 2008 “Plainsman” amaranth was seeded at two pounds pure live seed (PLS) per acre using a Truax seed drill with the seed being placed at approximately a quarter inch deep, in rows located 8 inches apart. Seeding rows were firmed by press wheels located behind each double disc opener on the seeder. The amaranth was seeded into plots 30 feet wide by 24 feet long. The amaranth was seeded in two adjacent sites with similar soils but differing in past production histories in the south end of Mason Valley, Nev. approximately 20 miles south of the city of Yerington. The 5-C site had not produced any crops or been subject to irrigation for at least 20 years. The Valley Vista (VV) site was an actively producing alfalfa field until the fall of 2007 when the alfalfa was killed using a glyphosate and dicamba herbicide combination. Both sites were prepared in a similar fashion by being disced, rototilled, leveled and rolled with a cultipacker.

Both sites were irrigated using Rainbird-type sprinklers. Irrigation treatments included 100 percent (4 acre-feet per acre), 75 percent (3 acre-feet per acre) and 50 percent (2 acre-feet per acre) of normal amount permitted in Mason Valley. Irrigation water amounts on the 5-C site were inadequate to meet the 75 and 100 percent levels planned in 2008. The planting and irrigation treatments were repeated in 2009 with both sites receiving all planned irrigation treatments. Irrigation was applied every seven days throughout the season.

Both sites were treated to reduce winter annual weeds with 2,4-D amine in April followed by rototilling in May 2008 and were weed-free when planted. All plots were treated by spot-spraying with glyphosate as necessary to reduce weed populations without harming the seeded plants. Continual hand-weeding occurred throughout the growing seasons each year. In 2009 one-half of each plot was treated with Poast® (sethoxydim 18 percent) in an attempt to control severe weed pressure from annual grasses especially a native lovegrass (Eragrostis mexicana).

Prior to seeding during the 2010 season, grass weed populations in the seeded plots were predicted to be a limiting factor. Therefore, a second seeding treatment was added. A heavy seeding rate treatment of 6 pounds per acre was added to the previous trial in an attempt to provide the seeded amaranth a competitive advantage over the existing grass weeds. Shortly after the seeded amaranth plants emerged in June 2010, it became obvious that neither seeding treatment (light or heavy) was adequate to reduce the grassy weeds growing in the plots on either site. The plots were then treated with Poast® or Select Plus® (clethodim) at recommended rates.

The plots were not fertilized in 2008. In 2009 and 2010 the plots were fertilized with 21-0-0 at a rate of 238 pounds per acre (50 pounds per acre/Nitrogen.

All plots were harvested in October of each year following hard frosts. Most commercial amaranth fields are harvested by combines set up for harvesting very small seeds. Due to the small plot size and fear of seed loss due to shattering, all plots were harvested and cleaned by hand. No harvests were possible from the VV site in 2008 or either site in 2010 as weed competition reduced establishment and production of the amaranth plants to minimal levels.

The results were analysed using analysis of varience to determine significant differences at the 0.05 level of probability.

The 2008 harvest of amaranth on the 5-C site resulted in an average yield of 637 pounds per acre clean seed after receiving 2 acre feet of water per acre. The values are averaged across all plots because no differential irrigation treatments were possible due to insufficient amounts of irrigation water being available.

In 2009 amaranth was harvested from both sites and was subject to the planned irrigation treatments of 50, 75 and 100 percent of normal irrigation. Amaranth production was not statistically different between the two sites. However, yields increased with applications of additional water. Yields of amaranth grain were increased significantly when water applications were increased from 50 percent to 75 or 100 percent. However, there were no significant increases between the 75 or 100 percent water applications at either site.

Amaranth originated in South America and has been cultivated for centuries. It is grown as a high quality, gluten-free grain, and occasionally used as a leafy vegetable as well. While the seeds are sold as a grain, it is a broad-leaved plant and not a grass as are most grains. There are three species of amaranth normally grown in the United States: Amaranthus cruentus, A. caudatus and A. hypochondriacus. All are related to another amaranth species, redroot pigweed, but have not proven to be weeds where they are being grown.

Amaranth grain plants are large and bushy, often reaching over 6 feet in height. They have a thick central stem, large fleshy leaves and numerous small, tightly clustered, bright-colored flowers that grow in a large group on the tops of the stems. Flower color can range from bright burgundy to pink, yellow and green. The seeds are very small with approximately 850,000 seeds in a pound. This makes successfully planting amaranth a challenge.

They are annual, warm-season plants and not frost tolerant. As such, amaranth should be planted when soil temperatures exceed 60 degrees Fahrenheit and after the last expected frost.

Interest in non-gluten grains such as amaranth is increasing as more individuals are being diagnosed as gluten-intolerant. Individuals exhibiting gluten intolerance are considered to have Celiac disease and a 2012 study found that approximately 1 in 141 people in the United States suffer from this condition, with most going undiagnosed. Currently amaranth grain is used in more than 40 products in the U.S. Amaranth production in western Nevada was evaluated from 2008 through 2010 as part of Walker Basin project.

In late May 2008 “Plainsman” amaranth was seeded at two pounds pure live seed (PLS) per acre using a Truax seed drill with the seed being placed at approximately a quarter inch deep, in rows located 8 inches apart. Seeding rows were firmed by press wheels located behind each double disc opener on the seeder. The amaranth was seeded into plots 30 feet wide by 24 feet long. The amaranth was seeded in two adjacent sites with similar soils but differing in past production histories in the south end of Mason Valley, Nev. approximately 20 miles south of the city of Yerington. The 5-C site had not produced any crops or been subject to irrigation for at least 20 years. The Valley Vista (VV) site was an actively producing alfalfa field until the fall of 2007 when the alfalfa was killed using a glyphosate and dicamba herbicide combination. Both sites were prepared in a similar fashion by being disced, rototilled, leveled and rolled with a cultipacker.

Both sites were irrigated using Rainbird-type sprinklers. Irrigation treatments included 100 percent (4 acre-feet per acre), 75 percent (3 acre-feet per acre) and 50 percent (2 acre-feet per acre) of normal amount permitted in Mason Valley. Irrigation water amounts on the 5-C site were inadequate to meet the 75 and 100 percent levels planned in 2008. The planting and irrigation treatments were repeated in 2009 with both sites receiving all planned irrigation treatments. Irrigation was applied every seven days throughout the season.

Both sites were treated to reduce winter annual weeds with 2,4-D amine in April followed by rototilling in May 2008 and were weed-free when planted. All plots were treated by spot-spraying with glyphosate as necessary to reduce weed populations without harming the seeded plants. Continual hand-weeding occurred throughout the growing seasons each year. In 2009 one-half of each plot was treated with Poast® (sethoxydim 18 percent) in an attempt to control severe weed pressure from annual grasses especially a native lovegrass (Eragrostis mexicana).

Prior to seeding during the 2010 season, grass weed populations in the seeded plots were predicted to be a limiting factor. Therefore, a second seeding treatment was added. A heavy seeding rate treatment of 6 pounds per acre was added to the previous trial in an attempt to provide the seeded amaranth a competitive advantage over the existing grass weeds. Shortly after the seeded amaranth plants emerged in June 2010, it became obvious that neither seeding treatment (light or heavy) was adequate to reduce the grassy weeds growing in the plots on either site. The plots were then treated with Poast® or Select Plus® (clethodim) at recommended rates.

The plots were not fertilized in 2008. In 2009 and 2010 the plots were fertilized with 21-0-0 at a rate of 238 pounds per acre (50 pounds per acre/Nitrogen.

All plots were harvested in October of each year following hard frosts. Most commercial amaranth fields are harvested by combines set up for harvesting very small seeds. Due to the small plot size and fear of seed loss due to shattering, all plots were harvested and cleaned by hand. No harvests were possible from the VV site in 2008 or either site in 2010 as weed competition reduced establishment and production of the amaranth plants to minimal levels.

The results were analysed using analysis of varience to determine significant differences at the 0.05 level of probability.

The 2008 harvest of amaranth on the 5-C site resulted in an average yield of 637 pounds per acre clean seed after receiving 2 acre feet of water per acre. The values are averaged across all plots because no differential irrigation treatments were possible due to insufficient amounts of irrigation water being available.

In 2009 amaranth was harvested from both sites and was subject to the planned irrigation treatments of 50, 75 and 100 percent of normal irrigation. Amaranth production was not statistically different between the two sites. However, yields increased with applications of additional water. Yields of amaranth grain were increased significantly when water applications were increased from 50 percent to 75 or 100 percent. However, there were no significant increases between the 75 or 100 percent water applications at either site.

Amaranth is an ancient pseudocereal that has been cultivated for thousands of years. This hardy plant can reach towering heights in the right conditions. But how tall can amaranth grow? And what factors affect its maximum height? In this article, we’ll explore everything you need to know to help your amaranth reach its full stature.

Typical Height Range of Amaranth Plants

Most amaranth varieties grow to about 3 to 5 feet tall (90 – 150 cm) Some dwarf varieties may only reach 1 – 2 feet (30 – 60 cm), while others can tower over 8 feet (243 cm)!

The most common grain amaranth grown in the U.S. is Amaranthus hypochondriacus. The popular variety ‘Plainsman’ reaches 5 to 6 feet tall (150 – 180 cm) in ideal conditions.

Factors That Influence Amaranth Height

Many different factors affect how tall your amaranth will grow. Here are some of the most important ones:

Genetics

Genetics play a huge role in determining height potential. As mentioned, dwarf varieties max out under 3 feet, while giant amaranth can grow over 8 feet tall! Selecting the right variety for your needs is key.

Soil Quality

Rich, fertile soil causes amaranth to thrive. The plant prefers well-draining loam with a neutral pH around 6.5. Adding compost or manure creates ideal growing conditions. Poor soil stunts growth.

Sun Exposure

Amaranth needs at least 6 hours of direct sunlight daily. With more sunlight the plant grows taller as it fuels growth through photosynthesis. Insufficient light leads to shorter plants.

Water

Too much water encourages fungal diseases and root rot. But too little water also stunts growth. Amaranth thrives with about 1 inch of water per week. Consistent moisture maximizes height potential.

Temperature

Temperatures between 70°F – 85°F (21°C – 29°C) enable amaranth to reach its full height. Cooler or hotter temperatures will restrict vertical growth.

Nutrients

Amaranth responds well to moderate nitrogen, around 40-80 lb per acre. Excess nitrogen can hinder growth and seed production. Phosphorus also aids development.

Plant Spacing

Wider row spacing reduces competition between plants, enabling larger, more vigorous plants. Spacings around 30 inches are ideal. Narrower spacing of under 1 foot results in short, stunted plants.

Planting Date

Earlier planting dates allow amaranth more time to grow tall before flowering. Mid-June is optimal in most regions. Later plantings won’t reach full height before the first frost.

Typical Growth Rate of Amaranth

On average, amaranth grows about 1 foot (30 cm) per month, or 3 inches (8 cm) per week. The growth rate varies depending on the stage of development:

  • Germination & Seedling Stage: 1-2 inches (3-5 cm) per week
  • Vegetative Growth Stage: Up to 1 foot (30 cm) per month
  • Budding & Flowering Stage: Over 1 foot (30 cm) per month

From planting to maturity, amaranth reaches its maximum height in about 3 months, just before the onset of flowering. Some giant varieties may take over 4 months to max out.

Maximize Amaranth Height in Your Garden

Follow these tips to help your amaranth reach its full stature potential:

  • Select a tall, vigorous variety suited to your region
  • Prepare soil with compost and pH of 6.5 prior to planting
  • Ensure full sun exposure of at least 6 hours daily
  • Maintain consistent moisture around 1 inch per week
  • Use row spacing of 30 inches or wider
  • Apply a moderate nitrogen fertilizer prior to planting
  • Plant in early summer to maximize growth duration

With the right variety choice, care, and conditions, you can grow towering amaranth plants over 8 feet tall! Monitor growth factors closely to help your plants reach their full height potential.

how tall can your amaranth plant grow factors that affect height

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Amaranth originated in South America and has been cultivated for centuries. It is grown as a high quality, gluten-free grain, and occasionally used as a leafy vegetable as well. While the seeds are sold as a grain, it is a broad-leaved plant and not a grass as are most grains. There are three species of amaranth normally grown in the United States: Amaranthus cruentus, A. caudatus and A. hypochondriacus. All are related to another amaranth species, redroot pigweed, but have not proven to be weeds where they are being grown.

Amaranth grain plants are large and bushy, often reaching over 6 feet in height. They have a thick central stem, large fleshy leaves and numerous small, tightly clustered, bright-colored flowers that grow in a large group on the tops of the stems. Flower color can range from bright burgundy to pink, yellow and green. The seeds are very small with approximately 850,000 seeds in a pound. This makes successfully planting amaranth a challenge.

They are annual, warm-season plants and not frost tolerant. As such, amaranth should be planted when soil temperatures exceed 60 degrees Fahrenheit and after the last expected frost.

Interest in non-gluten grains such as amaranth is increasing as more individuals are being diagnosed as gluten-intolerant. Individuals exhibiting gluten intolerance are considered to have Celiac disease and a 2012 study found that approximately 1 in 141 people in the United States suffer from this condition, with most going undiagnosed. Currently amaranth grain is used in more than 40 products in the U.S. Amaranth production in western Nevada was evaluated from 2008 through 2010 as part of Walker Basin project.

In late May 2008 “Plainsman” amaranth was seeded at two pounds pure live seed (PLS) per acre using a Truax seed drill with the seed being placed at approximately a quarter inch deep, in rows located 8 inches apart. Seeding rows were firmed by press wheels located behind each double disc opener on the seeder. The amaranth was seeded into plots 30 feet wide by 24 feet long. The amaranth was seeded in two adjacent sites with similar soils but differing in past production histories in the south end of Mason Valley, Nev. approximately 20 miles south of the city of Yerington. The 5-C site had not produced any crops or been subject to irrigation for at least 20 years. The Valley Vista (VV) site was an actively producing alfalfa field until the fall of 2007 when the alfalfa was killed using a glyphosate and dicamba herbicide combination. Both sites were prepared in a similar fashion by being disced, rototilled, leveled and rolled with a cultipacker.

Both sites were irrigated using Rainbird-type sprinklers. Irrigation treatments included 100 percent (4 acre-feet per acre), 75 percent (3 acre-feet per acre) and 50 percent (2 acre-feet per acre) of normal amount permitted in Mason Valley. Irrigation water amounts on the 5-C site were inadequate to meet the 75 and 100 percent levels planned in 2008. The planting and irrigation treatments were repeated in 2009 with both sites receiving all planned irrigation treatments. Irrigation was applied every seven days throughout the season.

Both sites were treated to reduce winter annual weeds with 2,4-D amine in April followed by rototilling in May 2008 and were weed-free when planted. All plots were treated by spot-spraying with glyphosate as necessary to reduce weed populations without harming the seeded plants. Continual hand-weeding occurred throughout the growing seasons each year. In 2009 one-half of each plot was treated with Poast® (sethoxydim 18 percent) in an attempt to control severe weed pressure from annual grasses especially a native lovegrass (Eragrostis mexicana).

Prior to seeding during the 2010 season, grass weed populations in the seeded plots were predicted to be a limiting factor. Therefore, a second seeding treatment was added. A heavy seeding rate treatment of 6 pounds per acre was added to the previous trial in an attempt to provide the seeded amaranth a competitive advantage over the existing grass weeds. Shortly after the seeded amaranth plants emerged in June 2010, it became obvious that neither seeding treatment (light or heavy) was adequate to reduce the grassy weeds growing in the plots on either site. The plots were then treated with Poast® or Select Plus® (clethodim) at recommended rates.

The plots were not fertilized in 2008. In 2009 and 2010 the plots were fertilized with 21-0-0 at a rate of 238 pounds per acre (50 pounds per acre/Nitrogen.

All plots were harvested in October of each year following hard frosts. Most commercial amaranth fields are harvested by combines set up for harvesting very small seeds. Due to the small plot size and fear of seed loss due to shattering, all plots were harvested and cleaned by hand. No harvests were possible from the VV site in 2008 or either site in 2010 as weed competition reduced establishment and production of the amaranth plants to minimal levels.

The results were analysed using analysis of varience to determine significant differences at the 0.05 level of probability.

The 2008 harvest of amaranth on the 5-C site resulted in an average yield of 637 pounds per acre clean seed after receiving 2 acre feet of water per acre. The values are averaged across all plots because no differential irrigation treatments were possible due to insufficient amounts of irrigation water being available.

In 2009 amaranth was harvested from both sites and was subject to the planned irrigation treatments of 50, 75 and 100 percent of normal irrigation. Amaranth production was not statistically different between the two sites. However, yields increased with applications of additional water. Yields of amaranth grain were increased significantly when water applications were increased from 50 percent to 75 or 100 percent. However, there were no significant increases between the 75 or 100 percent water applications at either site.

Amaranth (lbs/acre) 5-C 2009

During the 2010 growing season, no weed control treatments were successful and the amaranth seedings failed to produce enough plants to sample and estimate yields.

While demand in the U.S. continues to grow for non-gluten grains, producing them in commercial quantities is a challenge. The majority of these non-gluten grain-producing plants, including amaranth, are grown on very limited acreages and have no pest management chemicals registered for their use. This limits pest management strategies such as weed control to mechanical techniques such as cultivation or hand-weeding. Unfortunately, field crops such as amaranth do not produce enough income to support large-scale hand-weeding projects, and mechanical tillage betwen rows as was employed in this project was only marginally effective, especially against grassy weeds such as occurred on these project sites.

A second limitation experienced in this project was the need to produce amaranth at the same location for three consecutive years. Because amaranth is harvested relatively late in the fall, existing annual weeds such as lovegrass, barnyardgrass, pigweed, lambsquarter and others are able to produce fully mature seeds before the crop is harvested. As a result, annual weed populations in the plots continued to increase every year of the project, in spite of each plot being completely weed-free at the time of seeding. After three years, the weed populations increased to the point that they prevented successful establishment of the amaranth plants regardless of the weed control efforts. The available literature supports this result, with most publications concerning amaranth production indicating that weed control is the primary challenge to successful production.

The differences in production between the selected sites during the first two years were due primarily to the additional weed pressures experienced on the VV site. The VV site was a producing alfalfa field prior to the amaranth seeding, while the 5-C site had not been irrigated or produced any crops for at least 20 years. Weed seed populations in the soil were undoubtedly higher on the actively irrigated alfalfa field found on the VV site.

This evaluation resulted in amaranth production levels comparable to other amaranth-producing regions in the U.S. during the first two production years. This indicates that the climate/soils of western Nevada are not limiting. It appears that the application of three feet of irrigation water is desirable but additional irrigation amounts result in minimal yield increases of amaranth grain.

Based on the current evaluation results, amaranth can only be recommended for production in fields with a history of minimal weed pressures and production limited to one season. Also, a producer must have access to an appropriate combine, and seed cleaner and be willing to market their grain directly to consumers or retailers, or food cooperatives. Additional work is planned with this crop in the future, and this fact sheet will be updated as other results become available.

Baltensperger, D., Lyon, D., Nelson, L., and A. Corr. 1995. Amaranth Grain Production in Nebraska. NF91-35. University of Nebraska, Lincoln, NE.

Lee, C. 2011. 2011. Grain Amaranth. Crop Diversification & Biofule Research Eucation Center. Cooperative Extension Service, University of Kentucky. Lexington KY.

Putnam, D. H., Oplinger, E.S., Doll, J D.., and E.M. Schulte. 1989. Amaranth. Center for Alternative Plant and Animal Products. Minnesota Extension Service, University of Minnesota. St. Paul MN.

Sullivan, P. 2003. Amaranth Production. ATTRA Pub #CT152. AMARANTH PRODUCTION Accessed 10/29/2008.

Thomas Jefferson Agricultural Institute. 2012. Grain Amaranth A Lost Crop of the Americas. Thomas Jefferson Agricultural Institute Columbia, MO. Grain Amaranth A Lost Crop of the Americas Accessed 10/29/2008.

Weber, E. 1987. Amaranth production Guide 1987. Rodale Press Inc. Rodale Research Center. Kutztown PA.

USDA-NRCS PLANTS Database / Britton, N.L., and A. Brown. 1913. An illustrated flora of the northern United States, Canada and the British Possessions. 3 vols. Charles Scribners Sons, New

How tall can a tree grow? – Valentin Hammoudi

FAQ

How tall can amaranth grow?

Amaranth grows to 4 to 6 feet (1.2 – 2 m) tall, and tall varieties may need staking to hold them upright when they become top-heavy with maturing seed clusters. Varieties with light-colored seeds usually have the best flavor.

What is the growth habit of Amaranthus?

Description and Identification
Common and Scientific Name
Growth Habit
Powell Amaranth Amaranthus powellii
Erect, branched, 2–6 ft
Spiny Amaranth Amaranthus spinosus
Erect to bushy 1–4 ft
Waterhemp Amaranthus rudis or A. tuberculatus***
Erect, tall 3–10 ft
Prostrate Pigweed Amaranthus blitoides
Prostrate mat to 3 ft across

Does amaranth regrow after cutting?

If you’re cutting a single large head, I recommend cutting it back to about to two feet from the ground so that it can grow a few smaller, shorter heads (you can do this alternatively instead of pinching it back). If you’re cutting a single, smaller stem, just cut it back to the main trunk of the plant.

Can you cut back amaranth?

To pinch Amaranth, cut back the center bud/stem when plants are about knee high. This will signal the plant to produce multiple stems that are smaller and easier to use.

How tall does amaranth grow?

Amaranth is a tall plant and can get up to 8-feet tall depending on the variety and conditions. Amaranth is flexible when it comes to soil but prefers well-drained earth with a pH between 6.0 to 7.5, so spread some cottonseed meal or coffee grounds in the row where you are going to plant.

Why does my amaranth grow small?

If your crops are in the shade or densely planted, you will notice that your amaranth will be smaller. Adjust the available sunlight if other plants are shading your amaranth or thin out the plants to 18 inches apart to provide proper air circulation. Temperature may also be a factor in growing issues.

When is amaranth planted?

A warm-season plant, amaranth is planted after final spring frosts. Learn how to plant, grow, and care for amaranth. Amaranth plants are members of the genus Amaranthus, of which there are about 75 species. Amaranths are often grown for ornamental purposes, and some varieties make stunning additions to cut flower arrangements or fall wreaths.

How long does amaranth take to grow?

Once planted, amaranth seeds will germinate in less than two weeks. Seedlings will appear to grow slowly. When the plant reaches a foot tall, it will start to grow rapidly and produce beautiful flowers. The grains will be ready to harvest in the fall once the flowers are brown and dry. The flowers of amaranth can be used to make colorful dyes.

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