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Using Leaf Tissue Analysis for High Tunnel Tomato Nutrient Management

Growing tomatoes in high tunnels may require changing some of the management practices that you may employ when growing plants outdoors or in greenhouse environments.

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Updated:

November 18, 2024

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Figure 1. Elevated soil pH can limit the uptake of iron by tomatoes in high tunnels resulting in deficiency. Photo: Tom Ford, Penn State

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In this article, we will focus on using plant tissue analysis as part of your overall nutrient management plan or strategy. Nutrient management recommendations specifically for high tunnel tomatoes have not yet been developed and farmers will commonly adapt fertility recommendations that have been developed for outdoor growing.

Before planting, apply 30 to 60% of the nitrogen and all of the phosphorus and potassium recommended based on the crop and/or soil testing. Soon after planting, routinely submit leaf tissue for laboratory analysis. This can be done on a weekly or biweekly schedule. It may be tempting to wait until plants show symptoms of nutrient issues to submit tissue samples; however, when symptoms are seen, plant growth has already suffered. Proactive and routine tissue testing helps avoid deficiencies and toxicities.

Samples submitted for plant or tissue analysis should be composed of 25 to 100 leaves. Focus on collecting leaves that have recently expanded, also known as the most recently matured leaves. Avoid diseased or dead leaves and those damaged by insects or chemicals. Additionally, plant response to nutrient management varies by cultivar, stage of growth, and environmental conditions. The key is to collect a representative sample.

For example, if one area of the high tunnel stays wetter than another, collect samples from plants in that area separately from other areas. Or, if you are growing more than one cultivar in the tunnel, collect different samples for each cultivar being grown.

Place your sample in a paper bag and send it to a lab for analysis. A mistake that is sometimes made is putting the sample in a plastic bag. Doing this can cause moisture to accumulate around the sample, and it can start to degrade or rot. When this happens, the sample may not be usable. The leaf tissue analysis interpretation provided here is from Penn State University’s Agricultural Analytical Services Laboratory.

Example tissue analysis report — Figure 2. An example tissue analysis report from Penn State’s Agricultural Analytical Services Laboratory.

Nutrient concentrations are categorized as deficient, low, normal, high, or excessive.

Reports include nutrient concentration levels — Figure 3. Nutrient concentration categories are deficient, low, normal, high, and excessive.

Normal means that the tissue has a sufficient concentration of the nutrient and no corrective action is needed. A high concentration usually does not affect plant growth or yield but can lead to a problem if it reaches the excessive category. Monitor nutrient concentrations in the high category to avoid them moving into the excessive range. An excessive concentration means that the nutrient may have reached toxic levels where plant growth, yield, and quality are reduced. Review your nutrient management plan in this case and reduce the amount of the excessive nutrient applied. Deficient or low indicates that the nutrient is below sufficient concentrations and is likely limiting the crop’s potential. Concentrations in the deficient category mean that crop response to adding the nutrient is high and in the low category crop response to adding the nutrient is medium.

Tomato leaves deficient in magnesium — Figure 4. Magnesium deficiency is commonly observed on the lower leaves of tomatoes in high tunnels. Photo: Tom Ford, Penn State

The table below is from Plant Tissue Analysis and Interpretation for Vegetable Crops in Florida by G.J. Hochmuth, D. Maynard, C. Vavrina, E. Hanlon, and E. Simonne and provides a starting point for adding nutrients when tissue concentrations are in the deficient or low categories. Testing again in about 2 weeks can let you know if the actions you take now are working.

Table 1. The starting point for adding nutrients when tissue concentrations are in the deficient or low categories.
Nutrient	Fertilizer	Method of Application	Rate (nutrient; lb/acre)	Rate (nutrient; lb/1000 ft²)
Nitrogen (N)	Ammonium nitrate	Topdress, sidedress, fertigation	30–40	0.69–0.92
Nitrogen (N)	Calcium nitrate	Topdress, sidedress, fertigation	30–40	0.69–0.92
Phosphorus (P₂O₅)	Ammonium phosphates	Topdress, sidedress, fertigation	20	0.46
Phosphorus (P₂O₅)	Triple, normal	Topdress, sidedress	20	0.46
Phosphorus (P₂O₅)	Phosphoric acid	Sidedress, fertigation	20	0.46
Potassium (K₂O)	Potassium chloride	Topdress, sidedress, fertigation	30	0.69
Potassium (K₂O)	Potassium nitrate	Topdress, sidedress, fertigation	30	0.69
Calcium (Ca)	Calcium nitrate	Topdress, sidedress, fertigation	30	0.69
Calcium (Ca)	Calcium chloride	Fertigation	30	0.69
Magnesium (Mg)	Magnesium sulfate	Topdress, sidedress, fertigation	20	0.46
Magnesium (Mg)	Magnesium nitrate	Fertigation	20	0.46
Magnesium (Mg)	Potassium magnesium sulfate	Topdress, sidedress	10	0.23
Boron (B)	Borax	Fertigation, foliar	0.1–0.2	0.0023–0.0046
Copper (Cu)	Copper sulfate	Fertigation, foliar	0.1–0.3	0.0023–0.0046
Iron (Fe)	Ferrous sulfate	Fertigation, foliar	0.2–0.5	0.0046–0.11
Iron (Fe)	Chelated iron	Fertigation, foliar	0.2–0.6	0.0046–0.11
Manganese (Mn)	Manganous sulfate	Fertigation, foliar	0.5–1.0	0.11–0.023
Molybdenum (Mo)	Sodium molybdate	Fertigation, foliar	0.01–0.05	0.0023–0.011
Zinc (Zn)	Zinc sulfate	Fertigation, foliar	0.1–0.2	0.0023–0.0046
Zinc (Zn)	Chelated zinc	Fertigation, foliar	0.1–0.3	0.0023–0.0047