testing of leds for supplemental lighting of greenhouse-grown

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Testing of LEDs for Supplemental Lighting of Greenhouse-grown Tomatoes for a Northern Climate Celina Gómez and Cary A. Mitchell Department of Horticulture and Landscape Architecture

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Page 1: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Testing of LEDs for Supplemental Lighting of Greenhouse-grown Tomatoes for a Northern Climate

Celina Gómez and Cary A. Mitchell

Department of Horticulture and Landscape Architecture

Page 2: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

The greenhouse environment

• Semi-controlled environment for extensive production

• More affordable than completely controlled environments

• Take profit from natural solar radiation

Page 3: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Rationale

• Energy is second only to labor as the most expensive indirect costs of greenhouse production (Frantz et al., 2010).

• The industry wants:

• Cost effectiveness

• Energy efficiency

• High-intensity discharge (HID) lamps:

• High investment and installation costs

• Short life-span

• Problem for disposal (mercury and sodium vapors)

• Inefficient at converting electrical energy into photosynthetically active radiation (PAR)

Page 4: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Mutual shading…

Bushel Boy Farms, Owatonna, MN

Page 5: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Traditional overhead HPS lighting

Bushel Boy Farms, Owatonna, MN

Page 6: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Light-emitting Diodes (LEDs)

• Low wattage consumption

• Robust

• Long-lasting

• Narrow-band wavelengths

• Can be dimmed

• LEDs are being tested as supplemental lighting in

greenhouses in the US

Page 7: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

LEDs

Cool surface

Close to plant tissue

Adequate PPF

Low energy consumption

Lighting system built by ORBITEC, Madison, WI

Page 8: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Young tomato plants with LED lighting (temporarily positioned overhead) (experiment 2009/2010 at WUR) (Netherhoff 2010).

Page 9: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Objectives

• Compare year-round tomato production with no supplemental lighting vs. traditional overhead HPS lighting vs. overhead/side-/intracanopy-lighting arrays with high-intensity red and blue LEDs.

• Develop protocols for the use of LEDs arrays for greenhouses.

• Ultimately, enable US greenhouse growers to transition from HPS lighting sources to LED technologies.

Page 10: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

PRELIMINARY WORK TOMATO PROPAGATION

Objective 1. Compare transplant quality across seasons using LEDs vs. HPS as supplemental lighting.

Objective 2. Evaluate transplant production of different cultivars under LEDs vs. HPS vs. no supplemental lighting across seasons.

Page 11: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Hypothesis

Tomato seedlings grown under LEDs will achieve equal or greater transplant quality compared to those grown with HPS or no supplemental light while reducing electrical energy consumption in greenhouses.

Page 12: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Greenhouse tomatoes being tested (Indeterminate cultivars)

1. ‘Maxifort’- Rootstock

2. ‘Komeett’- generative scion

3. ‘Success’- vegetative scion

4. ‘Liberty’ - beef, scion

5. ‘Sheva-sheva’ - Roma, scion

6. ‘Felicity’- round cherry, scion

Page 13: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Supplemental lighting treatments

Treatments* Supplemental PPF

(µmol·m-2·s-1)

Photoperiod

(h/day)

Control, natural light 0 -

HPS (100 W) 61 23

LEDs 100% red 61 23

LEDs 95% red + 5% blue 61 23

LEDs 80% red + 20% blue 61 23

*DLI (5.05 mol·m-2·d-1).

Page 14: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

100 W HPS

Page 15: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Control

95% red- 5% blue

Lighting system built by ORBITEC, Madison, WI

Page 16: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

100% red- 0% blue

80% red- 20% blue

Lighting system built by ORBITEC, Madison, WI

Page 17: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Growing conditions

• Plants are propagated and grown in a glass-glazed greenhouse.

• Cumulative DLI is collected for each lighting treatment using LI-COR 190 SB quantum sensors interfaced to a Campbell Sci. CR1000 datalogger.

• The experiment is being repeated monthly for 21 days (expected start and end dates: ~5th and ~26th of each month, respectively) for at least 12 months.

Page 18: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Data collected

• Hypocotyl and epicotyl length (cm)

• Hypocotyl and epicotyl caliper (mm)

• Node number

• Leaf span (cm)

• Leaf area (cm2)

• Shoot DW (g)

• Shoot biomass per kWh of energy consumed is compared for the different treatments.

Page 19: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Jan. Feb.

March Apr.

May June

Results obtained with ORBITEC’s overhead, open-bar LED arrays

Page 20: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Preliminary Results

• Supplemental lighting is needed for adequate transplant growth during light-limited times of year.

• Blue light addition may be beneficial for plant growth in light-limited climates.

Page 21: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

GROW-OUT STAGE

Page 22: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Hypothesis

Tomatoes grown with side/intracanopy LED lighting will achieve equal or higher yields than plants grown with HPS or no supplemental light while reducing electrical energy consumption in greenhouses.

Page 23: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

LEDs Control

HPS

LED lighting system built by ORBITEC, Madison, WI

Page 24: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

LEDs

Lighting system built by ORBITEC, Madison, WI

Page 25: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

HPS

Control

Page 26: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Crop-response metrics to be measured

• Yield/productivity metrics: • Fruit number • Fruit weight • Stem growth (diameter/length) • Leaf length • Shoot dry weight

• Physiological metrics :

• Chlorophyll (SPAD) • Chlorophyll fluorescence • Leaf/fruit temperature • Leaf photosynthetic rates

• Fruit quality metrics: • Organoleptic

• Sweetness • Acidity • Texture • Color

• Physico/chemical: • Total soluble solids • Titratable acidity • Lycopene content • Antioxidant content

Page 27: Testing of LEDs for Supplemental Lighting of Greenhouse-grown

Plant responses to…

• Light source

• Cultivar

• Season

• Position of leaves in the plant canopy