Grow light

Dual spectrum compact fluorescent grow light. Actual length is about 40 cm (16 in)

A grow light or plant light is an artificial light source, generally an electric light, designed to stimulate plant growth by emitting an electromagnetic spectrum appropriate for photosynthesis. Grow lights are used in applications where there is either no naturally occurring light, or where supplemental light is required. For example, in the winter months when the available hours of daylight may be insufficient for the desired plant growth, grow lights are used to extend the amount of time the plants receive light.

Grow lights either attempt to provide a light spectrum similar to that of the sun, or to provide a spectrum that is more tailored to the needs of the plants being cultivated. Outdoor conditions are mimicked with varying colour temperatures and spectral outputs from the grow light, as well as varying the lumen output (intensity) of the lamps. Depending on the type of plant being cultivated, the stage of cultivation (e.g., the germination/vegetative phase or the flowering/fruiting phase), and the photoperiod required by the plants, specific ranges of spectrum, luminous efficacy and colour temperature are desirable for use with specific plants and time periods.

Typical usage

Grow lights are used for horticulture, indoor gardening, plant propagation and food production, including indoor hydroponics and aquatic plants. Although most grow lights are used on an industrial level, they can also be used in households.

According to the inverse-square law, the intensity of light radiating from a point source (in this case a bulb) that reaches a surface is inversely proportional to the square of the surface's distance from the source (if an object is twice as far away, it receives only a quarter the light) which is a serious hurdle for indoor growers, and many techniques are employed to use light as efficiently as possible. Reflectors are thus often used in the lights to maximize light efficiency. Plants or lights are moved as close together as possible so that they receive equal lighting and that all light coming from the lights falls on the plants rather than on the surrounding area.

A range of bulb types can be used as grow lights, such as incandescents, fluorescent lights, high-intensity discharge lamps, and LEDs. Today, the most widely used lights for professional use are HIDs and fluorescents. Indoor flower and vegetable growers typically use high pressure sodium (HPS/SON) and metal halide (MH) HID lights, but fluorescents are replacing metal halides due to their efficiency and economy.

Metal halide lights are sometimes used for the first (or vegetative) phase of growth as they have some blue light; however, they have peak intensity around yellow spectrum.

Blue spectrum light may trigger a greater vegetative response in plants.^{[citation needed]}

High pressure sodium lights are used for the second (or reproductive) phase of growth as they have a reddish light.

Red spectrum light may trigger a greater flowering response in plants. If high pressure sodium lights are used for the vegetative phase, plants grow slightly more quickly, but will have longer internodes, and may be longer overall.

Also, MH bulbs with added reddish spectrum and HPS bulbs with added bluish spectrum are also available for fuller spectrum and added flexibility during both vegetative and flowering phases.

In recent years LED technology has been introduced into the grow light market. By designing an indoor grow light using diodes, the exact wavelengths necessary for photosynthesis are used to create LED grow lights that are used for both the first (or vegetative) phase and the second (or reproductive) phase of growth. NASA has tested LED grow lights for their high efficiency in growing food in space for extraterrestrial colonization.

Light spectra used

Natural daylight has a high color temperature (approximately 5000 K). Visible light color varies according to the weather and the angle of the Sun, and specific quantities of light (measured in lumens) stimulate photosynthesis. Distance from the sun has little effect on seasonal changes in the quality and quantity of light and the resulting plant behavior during those seasons. The axis of the Earth is not perpendicular to the plane of its orbit around the sun. During half of the year the north pole is tilted towards sun so the northern hemisphere gets nearly direct sunlight and the southern hemisphere gets oblique sunlight that must travel through more atmosphere before it reaches the Earth's surface. In the other half of the year, this is reversed. The color spectrum of light that the sun emits does not change, only the quantity (more during the summer and less in winter) and quality of overall light reaching the Earth's surface. The color rendering index allows comparison of how closely the light matches the natural color of regular sunlight.

The light spectra of different grow lights

Different stages of plant growth require different spectra. The initial vegetative stage requires a blue spectrum of light, whereas the later "flowering" stage is usually promoted with red–orange spectra.

Light sources

Different types of bulbs may be used, including metal halide, fluorescent, incandescent, high-pressure sodium, and LED lights.

Metal halide (MH)

Metal halide bulbs emit a blue spectrum of light and are a good representation of spring and summer sunlight filled with bright blue skies.

Incandescent

Bare incandescent lights generally have a red-yellowish tone and low color temperature (approx. 2700 K). They are sometimes used to highlight indoor plant groupings but not as a true plant "growing" light. Some incandescent bulbs specifically marketed as "grow lights" come with a blue filter coating which reduces the amount of red light the bulb gives off— this does almost nothing for the plants themselves, however, and only serves to make the bulb produce less light overall by cutting off the red portion of the spectrum. Such "grow lights" have a brief life expectancy of about 750 hours and are extremely energy inefficient, producing much more heat than usable light.

Fluorescent

Today, fluorescent lights are available in any desired color temperature in the range from 2700 K to 7800 K. Standard fluorescents are usually used for growing vegetables and herbs indoors or for starting seedlings to get a jump start on spring plantings. Standard fluorescents produce twice as many lumens per watt of energy consumed as incandescents and have an average usable life span of up to 20,000 hours. Cool white fluorescent lights are sometimes used as grow lights. These offer slightly lower performance, a white light, and lower purchase cost.

High-output fluorescent lights produce twice as much light as standard fluorescent lights. A HO fluorescent fixture has a very thin profile, making it extremely useful in vertically limited areas. High-output fluorescents produce about 5,000 lumens per 54 watt bulb and are available in warm (2700 K) and cool (6500 K) versions. Usable life span for high-output fluorescent lights is about 10,000 hours.

Compact Fluorescent lights are smaller versions of fluorescent lights used for propagation, as well as for growing larger plants. Compact fluorescents work in specially designed reflectors that direct light to plants, much like HID lights. Compact fluorescent bulbs are also available in warm/red (2700 K), full spectrum or daylight (5000 K) and cool/blue (6500 K) versions. Usable life span for compact fluorescent grow lights is about 10,000 hours.

High-output fluorescent/high-intensity discharge hybrids combine cool operation with the penetration of high intensity discharge technology. The primary advantages to these fixtures is their blend of light colors and broad even coverage and reduced electric requirements.

High-pressure sodium (HPS)

High-pressure sodium lights yield yellow lighting (2200 K) and have a very poor color rendering index of 22. They are used for the second (or reproductive) phase of the growth. If high-pressure sodium lights are used for the vegetative phase, plants will usually grow slightly more quickly. The major drawback to growing under high-pressure sodium alone is that the plants tend to be taller and leggier, with a longer internodal length than plants grown under metal halide bulbs. High-pressure sodium lights enhance the fruiting and flowering process in plants. Plants use the orange/red spectrum HPS in their reproductive processes, which produces larger harvests of higher quality herbs, vegetables, fruits or flowers. Sometimes the plants grown under these lights do not appear healthy due to the poor color rendering of high-pressure sodium, which makes the plants look pale, washed out or nitrogen starved.

High-pressure sodium lights have a long usable bulb life and six times more light output per watt of energy consumed than a standard incandescent grow light. Due to their high efficiency and the fact that plants grown in greenhouses get all the blue light they need naturally, these lights are the preferred supplemental greenhouse lights. But, in the higher latitudes, there are periods of the year where sunlight is scarce, and additional sources of light are indicated for proper growth. HPS lights may cause distinctive infrared and optical signatures, which can attract insects or other species of pests; these may in turn threaten the plants being grown. High-pressure sodium lights emit a lot of heat, which can cause leggier growth, although this can be controlled by using special air-cooled bulb reflectors or enclosures.

Combination metal halide (MH) and HPS

Combination HPS/MH lights combine a metal halide bulb and a high pressure sodium bulb in the same reflector, either with a single integrated ballast assembly or two separate ballast assemblies. The combination of blue metal halide light and red high pressure sodium light is said by manufacturers to create an ideal spectral blend and extremely high outputs, but in reality it is a compromise on both situations. These types of lights cost more than a standard light and have a shorter life span. Also because they use two smaller lights rather than one larger light the distance that the light penetrates is significantly shorter, in comparison to a regular HID bulb, due to the inverse-square law of light.

Switchable, convertible, and two-way

Switchable, two-way and convertible lights burn either a metal halide bulb or an equivalent wattage high pressure sodium bulb in the same fixture, but not at the same time. Growers use these fixtures for propagating and vegetatively growing plants under the metal halide, then switching to a high pressure sodium bulb for the fruiting or flowering stage of plant growth. To change between the lights, only the bulb needs changing and a switch needs to be set to the appropriate setting. These are commonly known as conversion bulbs and usually a metal halide conversion bulb will be used in an HPS ballast since the MH conversion bulbs are more common.

LED

LED panel light source used in an experiment on potato plant growth by NASA

Recent advancements in LEDs allow production of relatively inexpensive, bright, and long-lasting grow lights that emit only the wavelengths of light corresponding to the absorption peaks of a plant's typical photochemical processes. Compared to other types of grow lights, LEDs for indoor plants are attractive because they consume much less electrical power, do not require ballasts, and produce considerably less heat than incandescent or fluorescent lights^{[citation needed]}. This allows LEDs to be placed closer to the plant canopy than other lights. Also, plants under LEDs transpire less, as a result of the reduction in heat, and thus the time between watering cycles is longer.^{[citation needed]}

There are multiple absorption peaks for chlorophyll and carotenoids, and LED grow-lights may use one or more LED colors overlapping these peaks.

Recommendations for optimal LED designs vary widely. According to one source, to maximize plant growth and health using available and affordable LEDs, U.S. patent #6921182 from July 2005 claims that "the proportion of twelve red 660 nm LEDs, plus six orange 612 nm LEDs and one blue 470 nm LED was optimal", such that the ratio of blue light to red & orange light is 6-8%.^[1]

It is also often published that for vegetative growth, blue LEDs are preferred, where the light has a wavelength somewhere in the mid-400 nm (nanometers). For growing fruits or flowers, a greater proportion of deep-red LEDs is considered preferable, with light very near 660 nm, the exact number this wavelength being much more critical than for the blue LED. Further research has shown that infrared and ultraviolet diodes give a full spectrum needed for flowering plants to effectively grow and flower.^{[1][citation needed]}

Early LED grow lights used hundreds of fractional-watt LEDs and were often not bright enough and/or efficient enough to be effective replacements for HID lights.^{[citation needed]} Newer advanced LED grow lights may use high-brightness multiple-watt LEDs, with growing results similar to HID lights.^{[citation needed]}

Grow light LEDs are increasing in power consumption resulting in increased effectiveness of the technology. LEDs used in previous designs were 1 watt in power. However, 3-watt and even 5-watt LEDs are now commonly used in LED grow lights. LED grow lights are now being produced which exceed 600 watts.^{[citation needed]}

Luminous efficiency

The following table lists luminous efficiency of a source and efficiency for various light sources:

Category	Type	Overall luminous efficacy (lm/W)	Overall luminous efficiency[2]
Combustion	candle	0.3[3]	0.04%
	gas mantle	1–2[4]	0.15–0.3%
Incandescent	100–200 W tungsten incandescent (230 V)	13.8[5]–15.2[6]	2.0–2.2%
	100–200–500 W tungsten glass halogen (230 V)	16.7[7]–17.6[6]–19.8[6]	2.4–2.6–2.9%
	5–40–100 W tungsten incandescent (120 V)	5–12.6[8]–17.5[8]	0.7–1.8–2.6%
	2.6 W tungsten glass halogen (5.2 V)	19.2[9]	2.8%
	tungsten quartz halogen (12–24 V)	24	3.5%
	photographic and projection lights	35[10]	5.1%
Light-emitting diode	white LED (raw, without power supply)	4.5–150 [11][12][13]	0.66–22.0%
	4.1 W LED screw base light (120 V)	58.5–82.9[14]	8.6–12.1%
	6.9 W LED screw base light (120 V)	55.1–81.9[14]	8.1–12.0%
	7 W LED PAR20 (120 V)	28.6	4.2%
	8.7 W LED screw base light (120 V)	69.0–93.1[14][15]	10.1–13.6%
	Theoretical limit	260.0–300.0[16]	38.1–43.9%
Arc light	xenon arc light	30–50[17][18]	4.4–7.3%
	mercury-xenon arc light	50–55[17]	7.3–8.0%
Fluorescent	T12 tube with magnetic ballast	60[19]	9%
	9–32 W compact fluorescent	46–75[6][20][21]	8–11.45%
	T8 tube with electronic ballast	80–100[19]	12–15%
	PL-S 11W U-tube with traditional ballast	82[22]	12%
	T5 tube	70–104.2[23]	10–15.63%
	Spiral tube with electronic ballast	114-124.3[24]	15–18%
Gas discharge	1400 W sulfur light	100[25]	15%
	metal halide light	65–115[26]	9.5–17%
	high pressure sodium light	85–150[6]	12–22%
	low pressure sodium light	100–200[6][27][28]	15–29%
Cathodoluminescence	electron stimulated luminescence	30[29]	5%
Ideal sources	Truncated 5800 K blackbody[30]	251 [31]	37%
	Green light at 555 nm (maximum possible luminous efficacy)	683.002[32]	100%

Light requirements of plants

The plants' specific needs determine which lighting is most appropriate for optimum growth; artificial light must mimic the natural light to which the plant is best adapted. The bigger the plant gets the more light it requires; if there is not enough light, a plant will not grow, regardless of other conditions.^{[citation needed]}

For example, vegetables grow best in full sunlight, and to flourish indoors they need equally high light levels; thus fluorescent lights or MH-lights are best. Foliage plants (e.g., Philodendron) grow in full shade and can grow normally with much lower light levels, thus regular incandescents may suffice.

In addition, plants also require both dark and light ("photo"-) periods. Therefore, lights may be turned on or off at set times. The optimum photo/dark period ratio depends on the species and variety of plant, as some prefer long days and short nights and others prefer the opposite or intermediate "day lengths".

Illuminance, or luminous flux density, measured in lux is an important factor in indoor growing. Illuminance is the amount of light incident on a surface. One lux equals one lumen of light falling on an area of one square meter (lm/m²), which is approximately 0.093 foot-candle (lm/ft²). A brightly lit office would be illuminated at about 400 lux.

Lux are photometric units, in that different wavelengths of light are weighted by the eye's response to them. This makes lux an inappropriate measure of efficiency in a horticultural lighting system. In professional farming, radiometric (watt/metre² or microeinstein /second·meter^{2[citation needed]}) or photosynthetically active radiation weighted (PAR watt) units are used instead.

See also

• Chlorophyll

References

1. "Patent US6921182 - Efficient LED lamp for enhancing commercial and home plant growth – Google Patents". Google.com. Retrieved 2012-03-08.
2. Defined such that the maximum value possible is 100%.
3. 1 candela*4π steradians/40 W
4. Westermaier, F. V. (1920). "Recent Developments in Gas Street Lighting". The American City. 22 (5). New York: Civic Press: 490.
5. Bulbs: Gluehbirne.ch: Philips Standard lights (German)
6. Philips Product Catalog (German)
7. "Osram halogen" (PDF). www.osram.de (in German). Archived from the original (PDF) on November 7, 2007. Retrieved 2008-01-28.
8. Keefe, T.J. (2007). "The Nature of Light". Retrieved 2007-11-05.
9. "Osram Miniwatt-Halogen". www.ts-audio.biz. Retrieved 2008-01-28.^{[dead link]}
10. Klipstein, Donald L. (1996). "The Great Internet Light Bulb Book, Part I". Retrieved 2006-04-16.
11. White LED Offers Broad Temp Range And Color Yield Electronicdesign (HTTP cookies required) Otherwise see:Google Cache
12. "Nichia NSPWR70CSS-K1 specifications" (PDF). Nichia Corp. Retrieved April 26, 2009. ^{[dead link]}
13. "Cree Xlight XP-G LEDs Data Sheet" (PDF). Claims 132 lm/W.^{[dead link]}
14. Toshiba E-CORE LED light
15. Toshiba to release 93 lm/W LED bulb Ledrevie
16. White LEDs with super-high luminous efficacy physorg.com
17. "Technical Information on lights" (PDF). Optical Building Blocks. Retrieved 2010-05-01. Note that the figure of 150 lm/W given for xenon lights appears to be a typo. The page contains other useful information.
18. OSRAM Sylvania light and Ballast Catalog. 2007.
19. Federal Energy Management Program (December 2000). "How to buy an energy-efficient fluorescent tube light". U.S. Department of Energy. {{cite journal}}: Cite journal requires |journal= (help)
20. "Low Mercury CFLs". Energy Federation Incorporated. Retrieved 2008-12-23.
21. "Conventional CFLs". Energy Federation Incorporated. Retrieved 2008-12-23.
22. Phillips. "Phillips Master". Retrieved 2010-12-21.
23. Department of the Environment, Water, Heritage and the Arts, Australia. "Energy Labelling—lights". Retrieved 2008-08-14.
24. Panasonic. "Panasonic Spiral Fluorescent". Retrieved 2010-09-27.
25. "1000-watt sulfur light now ready". IAEEL newsletter. No. 1. IAEEL. 1996. Archived from the original on Aug. 18, 2003. {{cite news}}: Check date values in: |archivedate= (help)
26. "The Metal Halide Advantage". Venture Lighting. 2007. Retrieved 2008-08-10.
27. "LED or Neon? A scientific comparison".
28. "Why is lightning coloured? (gas excitations)".
29. "Vu1 ESL™ R-30 Energy Efficient Light Bulb Specifications".
30. Integral of truncated Planck function times photopic luminosity function times 683 W/sr, according to the definition of the candela.^{[original research?]}
31. physics.ucsd.edu/~tmurphy/papers/lumens-per-watt.pdf
32. See luminosity function.

External links