Date 8/27/92

Title of Project Floriculture Environmental and Modeling Research at Michigan State University

Institution where work is being conducted NUchigan State University

Amount of Endowment Grant $ 21,000
Covering Period 1/92 to 12/92

Anticipated Date of Project Completion/Final Report 12/92 (6/93)

Individual(s) Conducting Project:

(List Project Leader First)

Dr. John A. Biernbaum - Title Associate Professor

Telephone Number 517/353-7728

Dr. Royal D. Heins - Title Professor

Mark V. Yelanich - Title Graduate Assistant

Floriculture Environmental and Modeling Research at Michigan State University

John A. Biernbaum, Royal D. Heins, and Mark V. Yelanich

Michigan State University

Progress Report to the American Floral Endowment, 8/27/92

A. Project Objectives:

1. Develop fertilization and irrigation strategies to minimize use and runoff of water and fertilizers.

2. Investigate root media nutrient analysis methods and interpretation guidelines.

3. Identify root media properties to maximize water and fertilizer efficiency.

B. Summary of Work Conducted:

With recirculated solution subirrigation methods of potted plants, water and fertilizer use can be

dramatically reduced compared to topwatering with no loss in plant quality. With traditional watering methods

as much as 40% or more of water and fertilizer is wasted in some instances. Recirculation of water does not

lead to plant death from the rapid transfer of Pythium from inoculated to non inoculated plants although some

transfer can occur. The relationship between leaching and fertilizer concentration determines media nutrient

levels. The amount applied and wasted varies over 10 fold with different techniques. Water quality has

significant effects on root media pH, foliar residue and rooting of poinsettia cuttings. High pH and soluble salts

from alkaline water decreases rooting compared to rain water or reverse osmosis treated water. Fertilization

rates well below those currently recommended can be used to produce poinsettia stock plants of the same or

better quality than those grown with fertilizer rates recommended by fertilizer companies. The number of

irrigations required to maintain impatiens hanging baskets in an outdoor area can vary by a factor of two

depending on the water holding capacity of the root media. Stopping evaporation of water from the root media

surface significantly reduces water and fertilizer use by 20 to 40% during production of Easter lily and

poinsettias. The vertical movement of nutrients to the surface layer of the root media with subirrigation and

topwatering which decreases nutrient availability and increases fertilizer requirements can be reduced or stopped

with an evaporation barrier. Post production water loss in a simulated consumer environment can be reduced

by as much as 50% for poinsettia and Easter lily with pot covers to reduce water evaporation from the media.

Fertilization rates necessary for production and long term garden performance of flowering plants in ten inch

hanging baskets have been determined. Ten commercial root media and baskets from ten producers varied little

in their performance and water holding ability. Fertilizer requirements from June 1 to October 1 were met with

resin coated fertilizer so no additional water soluble fertilizer was needed.

C. New Information Since the March 1992 Report:

The effect of root media fertilizer amendments on the pH of freshly mixed peat-based media was

determined and nearly all those tested had an acidifying effect. Production of a 55 minute video on pH

management was produced in cooperation with the Professional Plant Growers Association. Bedding plants flats

were finished in 14 to 28 days from transplanting plugs using six methods of fertilization with four water soluble

fertilizers applied with no leaching. There was little effect of fertilizer or method of application on time to

flower or plant size. Transpiration and media evaporative water loss for chrysanthemums started at one week

intervals for eight consecutive weeks were monitored on an hourly basis for three consecutive days to determine

the relative rates of water use at each weekly stage of development and as a function of plant leaf area. A

review of the literature covering water and nutrient efficiency of peat-based media was completed.

D. Future Plans Covered by the Endowment Grant:

Work to study current root roedia analysis methods and development of improved methods and

recommendations will continue. An experiment with six methods of fertilizing poinsettias with high verses low

alkalinity water and no leaching is in progress and will run for the next four months. Root media chemical

properties and recovery of nitrogen from rockwool and peat-based media will also be investigated this fall.

E. Anticipated Benefits for Floral Industry:

One of the most important challenges facing the floral industry is educating greenhouse operators how

to irrigate and fertilize greenhouse crops with minimal water and fertilizer runoff. This research is developing

specific information needed for the transition to methods that are environmentally and economically sound.

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Floriculture Environmental and Modeling Research at Michigan State University

Royal D. Heins, John A. Biernbaum, and Mark V. Yelanich

Michigan State University

Progress Report to the American Floral Endowment, 8/27/92

A. Project Objectives:

1. Investigate the control of stem elongation by day and night temperature.

2. Model the growth and development of poinsettia.

3. Model the growth and development of the Easter lily.

4. Model the growth of other floricultural plants.

5. Develop grower management tools from the above research.

6. Develop information necessary for the storage of seedlings and flowering plants.

B. Summary of Work Conducted:

Research in this project has resulted in the following information and concepts. Stem elongation, flower initiation, and

rate of plant development are all influenced by temperature. Stem elongation increases as the difference (DIF) between

day and night temperature increases. In contrast to stem elongation, flower initiation in most plants is influenced by

temperature during either part or the entire day. Non-optimal temperatures during the night (e.g. the poinsettia), the

day (e.g. the fuchsia), or both the day and night (e.g. the chrysanthemum) delay or inhibit flower initiation. Rate of

plant development is controlled by instantaneous temperature. Total time to unfold a leaf or develop a flower is the

summation of instantaneous rates of development. Models relating plant or flower development rate to temperature can

accurately predict accumulated plant development using hourly temperature averages or daily average temperatures when

temperatures are not excessively low or high. Comparing actual or predicted development with required development

over time can be used as a tool for precise timing and production of plants using a grower management tool called

graphical tracking.

C. Results to Date:

1. Poinsettia leaf unfolding, and therefore vegetative development, can be accurately predicted using the temperature

based leaf unfolding model:

Leaves per hour = -0.01446 + 0.001917 * Temperature - 0.000039042 * Temperature^2

This model has been validated in greenhouse trials and shown to accurately predict leaf unfolding within a half

leaf over a three week period after pinching under varying greenhouse conditions.

2. Time to flower of Thanksgiving cacti (Schlumbergera truncate) flower buds can accurately be described by the

following temperature based model.

Days to flower = (4.25 - ln(bud length))/(0.0596 + 0.008125 * Temperature)

3. Impatiens, pansy, petunia, geranium, marigold, ageratum, salvia, and fibrous begonia seedling plugs have been

stored without continued plant development in coolers under low temperatures for up to 6 weeks without plant

loss and subsequent delay in plant development and flowering after transplanting.

4. The graphical tracking model for stem elongation and height control in poinsettia has been combined with an

expert system program to develop an expert system to assist growers in making height control management

decisions (DIF and growth retardants). This computer program was tested in nine commercial greenhouses

representing over one million poinsettia plants during the 1991 poinsettia season.

5. Leveling of Thanksgiving cacti (Schlumbergera truncate) for more uniform plant height should only be conducted

after flower induction is complete to avoid vegetative pad formation. This means plants should not be leveled

until they have received at least five short days.

6. Time to flower in African violet can be predicted at time of plug transplant based on light and temperature. A

phenology model, based on inflorescence stalk stage, was developed and allows prediction of time to flower at

a particular temperature or required temperature for flowering to occur on a particular date.

7. Temperature and light combinations necessary for storage of alyssum, vinca, tuberous begonia, New Guinea

Impatiens, and tomato plugs have been determined. Vinca, tuberous begonia, New Guinea Impatiens, and tomato

were all sensitive to chilling injury at temperatures lower than 50′C. Storage temperatures for alyssum should be

less than 50′C. All species stored better with the addition of 1 umol*m-2*s-1 irradiance.

D. Future Plans Covered by the Endowment Grant:

The poinsettia expert system program will be tested in 8 greenhouses during the upcoming poinsettia season.

Quantitative data relating stem elongation to cultivar, growth retardant all, spacing, and DIF will be collected on

poinsettia plants to improve the predictive model associated with the stem elongation model in the expert system.

E. Anticipated Benefits for Floral Industry:

Markets, whether florist or mass markets, require plants with the correct morphological characteristics (height, flower

number, etc.) at the correct time. Delivery of plants with the right characteristics at the right time with minimal

chemical input is profitable to both growers and retailers. This research is designed to assist growers reliably produce

product at the right time within buyer specifications by developing models into grower management tools.

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