How Does Color Spectrum Affect Growing Marijuana Plants?
Table of Contents
Note: This article is aimed at intermediate to advanced cannabis growers looking for ways to improve their results.
What is the Color Spectrum of Light?
Although natural light might appear white to us, it is actually made up of many different colors. You can see this in action when you put light through a prism, or if you catch the sight of a rainbow. When light is refracted into its individual parts, you can see all the colors that make up that light!
Over the years, we’ve learned that plants actually make “decisions” about how to grow based on the spectrum of light they receive. A different color spectrum can change how cannabis germinates, grows and even makes buds! Although we don’t have a lot of options to change the spectrum of sunlight when growing outdoors, we have almost complete control of the spectrum when growing cannabis indoors since we’re using grow lights!
So what’s the “best” light spectrum for growing cannabis? Unfortunately that’s a big question since each spectrum has its own unique effects and some are more useful to you than others, but let me share everything we know so you can decide what’s best for your goals and situation.
There is no “best” light spectrum for growing cannabis, but you can choose the best one for your goals and grow room!
So why do cannabis plants react to the spectrum of light? When growing outdoors under the light of the sun, the spectrum of light received actually gives a cannabis plant a lot of information about what’s going on in the world around them.
As just one example, during the spring and summer, more of the blue spectrum of light makes it to earth because the sun takes a more direct path through the sky.
In the summer, a plant responds to this bright direct light (with lots of blue) as a cue to grow vegetatively with lots of big leaves and short stems. The plant tries to spread out as much as it can and increase its leaf mass.
Blue light – Grow lights with a higher ratio of blue light are often used in the vegetative stage as they tend to make cannabis plants grow short and squat, with big healthy leaves.
As fall approaches the sun starts hanging lower in the sky. As a result, more of the light that reaches the plant falls within the red spectrum. More light in the red part of the spectrum is a sign to the plant that summer is coming to an end and it’s time to get in gear before winter. As a cannabis plant gets exposed to a higher ratio of red light, it reacts by growing longer stems with more space between the leaves, getting as tall as possible for the best position to start making buds and pollinate via the wind!
Yellow/Red light – Grow lights with higher amounts of red are often using in the flowering stage to encourage plants to grow tall (stretch) and to help promote budding. Plants may switch to the flowering stage faster under red light than under blue.
By keeping track of the ratio of colors in the spectrum of light, a cannabis plant is able to “know” a little bit about what’s going on around them which helps plants grow in the best way possible! As an indoor grower, it’s your job to be the sun and tell your plant what to do!
If you’re trying to keep plants short with lots of leafy growth, use grow lights that give off light in more of the blue spectrum during the beginning of your plant’s life. When it’s time to switch the plant to the flowering stage, you might switch the lights to something that has more of the reds and oranges that cannabis likes during the flowering stage.
But you don’t have to follow the general rules! I personally use an HPS bulb from seed to harvest, which gives off primarily red/yellow, because I like how young plants grow under them – I find it easier to train the plants when they have a little bit more space between nodes! But if I were in a very height-limited space, I might consider trying to give more blue light to help keep stems naturally shorter.
I personally grow plants from seed to harvest under HPS grow lights so plants grow taller, because the longer stems make plant training easier in my case. You can grow your cannabis plant from seed to harvest under any grow light as long as the light is bright enough!
How big a difference does spectrum make to plant growth?
As long as a cannabis plant is getting bright light with at least some red and blue, it will grow normally, so any reputable plant grow light you get on the market will do the job and get you to harvest with top-quality buds!
Although certainly not essential to healthy plant growth it is considered good form to choose lights in the proper light spectrum to encourage the growth you want in the vegetative and flowering stages of the marijuana plant. If you have a tool, why not use it?
However, keep in mind that different strains are affected differently by the color spectrum of the light. Some plants are barely affected at all while others might react much more strongly. It’s important to remember that the changes caused by light spectrum are relatively small (such as stems tending to grow longer) and many other factors drive some of the same changes.
For example, if your plant isn’t getting enough light, it will grow long and lanky even if the light has lots of blue because it’s “reaching” for more light.
On the flip side, if you give your plant high levels of light with lots of yellow, it tends to stay short because it’s getting so much light that there’s enough blue and no need to get taller. Since almost all grow lights give off a spectrum of light that is suitable to healthy cannabis growth, in many ways the amount of light has a much bigger effect on your plant than spectrum.
The best way to increase yields is to give your plant more light altogether!
In other words, giving your plant more light is going to give you a bigger return on yields than simply changing the spectrum. So if it’s possible to give your plant more light (up to a point), that is going to increase your yields even if you’re adding light in the “wrong” spectrum. Even bright white fluorescents that dip into the green spectrum will produce great plant growth. If it’s a grow light, it will do the job! Learn about different cannabis grow lights!
In-Depth Look at How Light Spectrum Changes How a Cannabis Plant Grows (Advanced)
Light is part of the electromagnetic spectrum, which includes not just the visible light spectrum, but also includes X-rays, Gamma rays and infrared light. Plants react to light spectrum via a process (known as photomorphogenesis) that is completely separate from photosynthesis. This section has nothing to do with PAR or lumens or how a plant makes energy from light (which I talk about below).
In this section we’re only talking about how the plant uses hidden information contained in the spectrum of light to grow better!
Although a plant can’t physically get up and move to a new spot, it is constantly growing and changing its growth patterns to maximize the amount of light it gets. For example a plant turns its leaf blades to face the light as the sun moves across the sky, and then puts all its leaves down at night to save energy and protect itself. Like all plants, a cannabis plant has ways to measure different spectrums of light, each giving the plant information about the best way to grow.
Plants “smell” the light spectrum!
Like humans, plants use the signals from their senses to help find energy to grow. For example we have a nose to smell something tasty and help us seek out food. But although we use our noses to capture the hidden messages in smells, ultimately a nose can only signal to us about possible food sources. We can’t actually eat food with our noses – we need our mouths to get food in our bellies.
Plants have certain light sensors (photoreceptors) found all over the plant that act kind of like the plant’s “nose” to detect information about the light spectrum. Just like how humans use their sense of smell to help find good food, the plant uses the information about light spectrum to help the plant grow in a way that gets the most light.
However, similar to how we can’t actually eat food with our noses, plants can’t make energy from light using their photoreceptors.
So when it comes to this section about photoreceptors and the light color response of plants, we’re talking about the “nose” of the plant, not the “mouth!” The reactions to light spectrum we talk about below are completely separate from photosynthesis! If you’re interested in how the plant actually obtains energy from light via photosynthesis, check out the section at the end of this page about PAR, lumens and light intensity.
LED grow lights use custom color spectrums to get plants to grow more efficiently
Jump straight to the section that interests you!
UVA / UVB / Ultraviolet Light (280nm-400nm)
You may be familiar with the term UV-A/UV-B when it comes to protecting your skin outdoors. We use sunscreen to protect our skin from UV rays from the sun in order to prevent skin damage. Too much UV exposure can give you sunburn now, and even carcinoma/melanoma in extreme cases!
When we’re talking about plants, UV-A (315 to 400 nm) and UV-B (280 to 315 nm) are sometimes classified as part of the “blue” light spectrum, though in the last several years, we’ve discovered the UV spectrum has its own unique effects on plants.
Like humans, plants given too high levels of UV light become damaged, and we’ve learned that plants react to UV rays by making chemicals, antioxidants and enzymes to help prevent and repair damage. Basically, they’re making their own “sunscreen!” It’s a little bit like how our body gives us a tan after UV exposure to protect us from further skin damage.
Some growers believe that providing UV-B light to plants may increase the THC levels or some other aspect of potency of cannabis buds. Theoretically, it’s definitely possible since we know that UV-B light does change how plants grow. But what we don’t know is exactly how cannabis responds to UV-B exposure. It’s possible that it increases the levels of THC, but it’s also possible it reduces it, or doesn’t affect THC at all! With what little information we have today, it’s hard to know whether supplementing cannabis with additional UV-B is actually beneficial.
That being said, most grow lights naturally produce some amount of UV rays, though far less than the sun. The exception is LED grow lights with narrow-band spectrums which need UV diodes specifically put in. There are other sources of UV light you can get such as reptile lamps. LED grow lights are also a good choice if you want to supplement above normal levels of UV, but you need to make sure you get one that has been designed to produce UV light since that isn’t standard.
There are new LED grow lights on the market that contain UVB, including this one which also contains light in the infrared spectrum. Although we know that UVB has an effect on cannabis, we don’t know exactly what changes, and whether it’s good, bad or a waste of time!
Blue Light (400 nm – 500nm)
Blue light is very important. Without at least some amount of blue light, most plants won’t grow normally. The plant has several different ways it measures blue light, and they each have their own effects. For example, when you see a plant growing towards the light, it’s actually only responding to just the blue light. Without any blue, the plant wouldn’t know where to grow!
Blue light also has an effect on how stems and leaves tend to grow. Seedlings and plants given plenty of blue light tend to stay short, with short stems and squat growth. They tend to grow big leaves and spread them out.
It’s often recommended for cannabis growers to use bright white fluorescents or metal halide grow lights during the vegetative stage since the extra levels of blue help keep young plants from growing tall and lanky, and encourages lots of leafy growth.
Blue light also works together with red light to help the plant “know” whether it’s day or night time, and help set circadian rhythms. You may notice that cannabis plants start drooping right before the lights go off each day, and they start perking up right when lights come on. This is a way for the plant to save energy while it’s “sleeping.” Since the blue in the light helps it “know” the time schedule, it will prepare as best it can for lights-out and lights-on.
Green Light (500 nm – 600nm)
There has been quite a bit of research on how different spectrums affect plant growth, especially over the last decade by researchers at NASA trying to find a way to grow plants most efficiently in space with LED grow lights.
We have long known that plants need at least red and blue light to grow normally, but recent discoveries have found that green light, while not the most efficient spectrum for photosynthesis, has a significant effect on how plants grow.
Green light has been shown to be involved in seedling and vegetative development, the initiation of the flowering stage, CO2/water usage, stem growth and overall plant height. There’s probably more we don’t know about yet!
But like the other spectrums, plants seem to want just the right amount of green light for the best growth, not too much or not too little. After many experiments with green light, the NASA Biological Sciences research group has reported that light sources consisting of primarily green will cause plants to grow slower. However, combinations of red and blue including up to 24% green actually enhanced growth for some plants over purely red and blue light.
So we’re learning that green is really important! In fact, in one experiment NASA did with lettuce, giving plants only blue/green/red light produced higher yields than full spectrum grow lights!
But cannabis is definitely not the same as lettuce and it doesn’t necessarily mean that adding green light will increase your cannabis yields! Nearly all grow lights provide some amount of green and it seems like adding too much green probably would hurt yields. But getting enhanced growth from green lighting is something to explore, especially for LED growers who often don’t give any green at all!
Note: There’s plenty of evidence that different types of plants respond to green light differently, so make sure you take any light spectrum study with a grain of salt!
In addition to the effects on how a plant grows, green light is what make plants appear natural and green to us. Plants under LED grow lights with just red and blue light tend to look dark or purple similar to how plants look very yellow/gold under a HPS. By adding a little bit of green we can actually see the natural color of leaves, which makes it a lot easier to spot problems!
Leaves appear dark under LEDs that don’t have any green diodes. In the picture below, leaves appear purple except in the front where a little bit of natural light coming from outside the tent. You actually see the leaves’ true green color wherever it’s touched by light that contains green.
Neat fact! Although your plant can respond to green light in some ways, it can’t “see” green when it comes to photoperiods and knowing when it’s day or night. So you can actually use green light to look at your plants in the dark and it won’t interrupt their dark period at all!
Use green light to check on plants in the dark so you don’t disturb their sleep!
(Make sure to get a light made for this purpose, not just any green light will do!)
Red & Far Red / Infrared Light (660 nm & 730nm)
We can see red light of course, but generally humans can’t see far-red (infrared) light, although we can feel it as heat. Plants, on the other hand, can sense both red and far-red light.
Red light is probably the most important type of light for plants. When it comes to photosynthesis, plants are best able to make energy out of red light. In fact, many plants can actually grow even if they only get pure red light, though they won’t grow as big or as healthy as they do under full spectrum light. Every type of grow light, even ones that are rich in blue like metal halides, provide quite a bit of red light.
However, when it comes to red and far-red light as far as signals (not photosynthesis), it’s not the amount as much as the ratio of red to far-red that’s important to the plant! For the purposes of the plant and its response to light spectrum, red light is
660nm and far-red light is
730nm on the light color spectrum.
A germinated seed moves towards red light
After a seed cracks open its shell, but before it makes it to the surface, the root goes down and the seed grows in the direction of greater levels of red light compared to far red. Blue light doesn’t usually make it underground, but the seed can sense red from the surface, and grows in that direction.
Once the seed reaches the surface and gets exposed to blue light, it stops acting like a root and starts acting more like a seedling, opening its leaves and growing towards the closest source of blue light. If it doesn’t get a good amount of blue light at the surface, it continues to grow its main stem longer and longer without making any leaves, acting more like a root than a plant because it still “thinks” it’s underground, or at least hidden from the sun.
Seeds move toward the light, and the leaves inside don’t open up once the plant hits the surface…it’s looking for the right amount of the right color of light!
If a plant doesn’t get access to enough light at the surface, it stays in “root mode” and keeps growing taller without opening up its leaves
Stems tend to stay shorter when they’re getting more red light compared to far-red
In bright sunlight, a cannabis plant tends to grow short and squat. This is because direct sunlight usually has more red than far-red and the plant reacts to this ratio. So if a plant is getting more 660nm than 730nm light, the stems tend to stay short and the plant grows a lot of nodes with shorter stems.
On the flip side, if a plant is getting a more 730nm light than 660nm, it tends to grow tall and stretchy. This is because, in the wild, when a plant is surrounded by a lot of vegetation, the surrounding leaves absorb a lot of the red light, and so whatever light does filter down to the hidden plant or stem has a much higher ratio of far-red light.
In response to higher levels of far-red light, stems will start to elongate and grow taller, as the plant is “stretching” up towards the light until it gets a ratio with more red and “senses” it’s in direct sunlight again.
If a plant is surrounded by greenery, it starts sensing higher ratios of far-red light, and starts “stretching” upwards to grow past the other vegetation and get access to better quality light
Plants keep track of days and nights using the ratio of red to far-red light
You’ve seen red light at sunset. The reason you see red when the sun is on the horizon is because red light has the longest wavelengths, which travel the furthest. At sunset the light is fading quickly, and when all other light is too weak to see, you can still see the red coming through the horizon before it disappears too. Infrared light has even longer wavelengths, so it hangs on just a little bit longer. That means for the plant, the highest ratio of far-red light occurs at sunrise and sunset.
The information contained in the light is important to a plant because it needs to be able to “know” whether it’s the beginning or end of the day. A plant can take advantage of the light spectrum information to keep track of day and night by sensing when there’s the highest ratio of far-red light.
Far-red light is the last thing a plant “sees” at sunset, so when there are high far-red levels followed by a period of darkness the plant “knows” that it’s nighttime.
When a plant starts getting higher levels of red light combined with blue from the morning sun, it “knows” that the day has started again. If a plant is exposed to red light during the dark period, it will “wake it up” because it thinks day is happening. Blue light also affects the plant at night by messing up its circadian rhythms, though blue light alone likely won’t stop the plant from flowering.
These processes helps the plant set itself on an internal clock. Keeping track of the length of nights is the main way a cannabis plant knows when to start flowering (making buds). When nights get long, it initiates the flowering response because it “thinks” winter is coming! So growers are able to force the plant to start flowering at any time just by changing the plant’s light schedules!
Note: Even if the plant doesn’t get far-red light before dark, it will eventually “realize” it’s night time, but it starts the clock 1-2 hours later because it didn’t get that far-red “sunset” signal. Because of this, there’s some evidence that if you provide a plant with a burst of far-red light right before it goes to sleep in the flowering stage, you could cut 1-2 hours off your night period and it wouldn’t interrupt the flowering cycle. That being said, it’s always a good idea to give your flowering cannabis plant at least 12 hours of uninterrupted darkness every night to make sure budding goes smoothly! When time schedules get weird, you sometimes end up getting hermies or have your plant revert back to the vegetative stage, which most growers don’t want!
Can I use a thermal imaging camera to watch over cannabis my plants at night?
Yes. The way a thermal camera (also called an infrared camera, or thermographic camera) works is it actually absorbs/measures how much infrared light is being given off by objects.
A thermal camera works by showing warmer objects as lighter colors. So for example, the cold ground will appear dark, while a plant is a little warmer and will appear lighter. A human is warmer still and appears almost white on such a camera.
A thermal (infrared) camera doesn’t actually give off any light, it only measures it. So although far-red light does have an effect on plants, it won’t be affected by a camera that doesn’t produce any.
However, if your camera has a screen, the light from the screen is definitely an unwanted source of light!
What if I can only pick one spectrum?
We’ve learned that spectrum can change how a plant grows. So it’s definitely a good idea to try to match the spectrum with your goals, but what do you do when you can only get one light and must choose between one spectrum or the other?
If you have to choose between one or the other, it’s generally recommended to use the flowering light spectrum (more red) for the whole grow. This results in bigger yields watt-for-watt. However, you can successfully grow buds in the blue light spectrum for the whole grow, and many growers do this with excellent results. Some growers even claim they like their quality better under blue lights!
In other words, color spectrum is important, but it won’t make or break your grow.
Note: I’ve used all types of grow lights during all stages of growing marijuana, and even when you’re not using the “right” color spectrum, you will still produce potent buds with any strong grow light! I’ve even used “bright white” CFL grow lights (which have high levels of green), and you may be surprised to learn that these work great for growing weed, too!
The color spectrum of your grow lights does affect how a plant develops, but color spectrum won’t make or break your grow!
Light energy is what matters most when it comes to cannabis growth rates and yields. Your plant turns light into sugars via the process of photosynthesis, and it’s these sugars that it uses to power the growth of the plant and especially the buds!
When it comes to photosynthesis and yields, as long as you’re using a grow light, the most important thing is pure power of light. Because of this, one of the best ways to increase your yields is to increase the amount of light your plant gets.
There’s two main ways to increase the amount of light for your indoor plants:
- Train your plants to use more of the light you have (get ups to 40% more yields compared to an untrained plant in the same setup)
- Upgrade to bigger grow lights
Learn more about the different kinds of marijuana grow lights for indoor growers.
PAR vs Lumens: Which is Best to Measure Grow Light Intensity?
When it comes to measuring how “good” a grow light is, or how much light it’s producing for your plants, it can get confusing because a lot of terms get thrown around willy-nilly.
The truth is that there is no one best way to measure light, but there are several ways and each has their own strengths and weaknesses.
One of the most common ways you’ll see light measured is with lumens. Lumens measure “luminous flux” which is a fancy way of saying that it’s how much light you can see as a person. It measures how “bright” something is to human eyes, and it’s weighted so that light we see counts more than the light we don’t see as well. The amount of light received at a particular point in space is known as lux, or lumens per square meter (1 lumen/m2 = 1 lux).
When it comes to plants, the type of light we can see, and the type of light they can use are pretty close. So even though lumens don’t measure light exactly as a plant sees it, it does give us a good general idea of how bright a light is to plants for many types of grow lights. Not perfect, but a good ballpark figure.
For example lumens are a pretty great way to compare the amount of light put out by fluorescent lights, CFLs, HIDs, MH and HPS grow lights. However, when it comes to LED grow lights, lumens are not as a good measure anymore since LEDs usually give off light only in very narrow wavebands of light, and the weighted numbers from lumens aren’t as good a way to predict how much usable light is getting sent to the plants.
Which takes us to another common way to measure light from grow lights…
Photosynthetically Active Radiation (PAR)
Instead of considering how much light is produced from a light source as humans see it, PAR actually considers only the spectral range of solar radiation from 400 to 700nm, which is the spectra of light that plants can use for photosynthesis. It’s pretty close to the range of light that humans can see, but not quite.
PAR refers to light in the 400-700nm range, as this is the range plants use for photosynthesis
There is a lot of confusion about this term! PAR is actually just a way to talk about the spectrum of light between 400-700nm. It doesn’t actually measure anything. When people are talking about “the amount of PAR a grow light gives off,” they’re actually talking about how much light in the PAR range that a light is giving off, or PPFD (Photosynthetic Photon Flux Density, sometimes abbreviated PPF).
So when most people talk about PAR, they’re actually talking about “PPFD” or how much light is getting sent that can be used for photosynthesis. When scientists and plant biologists are measuring how much light is being produced for a plant in experiments with light spectrum, they almost always measure in PPFD.
Plants are more efficient at producing energy from light in some parts of the PAR spectrum than others. For example, we know that plants are most efficient at photosynthesis when using light in the red and blue range. This is why you see graphics like this when people are talking about PAR. This measures how well each type of chlorophyll in plants is able to absorb energy from light at different parts of the PAR spectrum.
However, it’s important to note that cannabis plants can photosynthesize light from all parts of the spectrum, including in the green section as you can see in the graphic above, even if a plant doesn’t absorb energy from all types of light evenly.
One way green light is helpful is it penetrates further down into the canopy than red and blue light, which get mostly absorbed by the upper leaves. This adds to amount of photosynthesis happening to leaves further down on the plant.
Additionally, since the spectrum of light also has an effect on how plants grow in ways that are completely separate from photosynthesis (as explained in this article), you probably wouldn’t get the best results focusing only on only photosynthesis anyway! As has been demonstrated by NASA and others, many plants grow more healthfully and faster when they also receive at least a little (not too much!) light from the green section, even though it’s not the most efficient light for photosynthesis.
As you’ve read today, cannabis uses many aspects of light to develop into the bud-bearing plants we love! Instead of focusing on any one aspect, it’s important to look at your results as a whole!
What to focus on for best results when it comes to quality of light:
- Power is more important than spectrum – the total amount of light given is a lot more important to growth than spectrum!
- Give bright light with lots of blue for shorter stems and bigger leaves
- Give light with lots of red/yellow to promote germination, for longer stems and to promote flowering
- Try to give a spectrum of light that includes even a small amount of green if possible for the best growth (all grow lights except most LEDs already have some green) though red/blue is all you need for the plant to grow up healthy
- As long as you start with a great cannabis grow light, you don’t really need to worry about spectrum! Always train your plants to get the most out of your grow light (up to 40% more yields under the same grow light compared to not training) or if you’re still having trouble reaching your yield goals, upgrade to a bigger light!
I hope that helps you cut through all the conflicting information and gives you the information you need to make the right choices for your cannabis garden!
Changes Direction a Plant Grows
- Phototropism – Plant bends towards light
- Gravitropism – Plant points new growth upwards, opposite of gravity’s pull
Changes How a Plant Grows
- Photomorphogenesis – plant’s response to spectrum of light (affects germination, length of stems, and when a cannabis plant starts flowering)
Determines How Much Energy is Produced from Light
- Photosynthesis – The process of capturing energy from light to produce sugars in the plant to power growth! The amount of light (often measured in lumens or PAR/PPFD) is directly related to how fast a plant grows!
What do I need to know about the color spectrum of light when growing marijuana indoors? Blue light delivers more squat growth, yellow light leads to stretchier growth and…
The Ideal LED Grow Light Spectrum for Plants
The use of LED grow lights in crop farming has recently seen substantial growth. However, choosing the right light spectrum for plants and knowing how they affect photosynthesis, can be challenging and oftentimes confusing.
This article aims to help you understand the light spectrums needed for plant growth and how full spectrum LED lighting is now widely used for crop production. We’ll address what broad-spectrum lighting is, how different grow light spectrums affect different stages of plant growth, and its effect on Cannabis production.
What is Grow Light Spectrum?
Grow light spectrum refers to the electromagnetic wavelengths of light produced by a light source to promote plant growth. For photosynthesis, plants use light in the PAR (photosynthetic active radiation) region of wavelengths (400nm-700nm) measured in nanometers (nm).
Nanometers are a universal unit of measurement but also used to measure spectrum of light – humans can only detect visible light spectrum wavelengths (380-740nm). Plants, on the other hand, detect wavelengths including our visible light and beyond, to include UV and Far Red spectrums.
It’s important to note light spectrums affect plant growth differently depending on things like environmental conditions, crop species, etc. Typically, chlorophyll, the molecule in plants responsible for converting light energy into chemical energy, absorbs most light in blue and red light spectrums for photosynthesis. Both red and blue light are found in the peaks of the PAR range.
LED Grow Lights
LED grow lights are energy-efficient lights used by indoor and greenhouse farmers and Cannabis growers too. Used as either a sole light source (indoor) or supplementary (greenhouses), LEDs help plants grow using full-spectrum lighting at a lower cost than traditional HPS lamps ( 1 ).
Many growers take advantage of LED lights to help scale plant production due to their full light spectrum capabilities, low heat waste and maintenance, and extended lifespan. And given a plant’s physiology and morphology are strongly affected by specific spectrums, LED grow lights can efficiently promote growth in crops ( 2 ) at specific times in the growth cycle. With the ability to closely monitor quality, energy output can be easily evaluated for scaling crop production.
Grow Light Spectrum Chart
The above chart shows the PAR range – the spectrum of light plants use for photosynthesis. Grow light spectrum charts like this include both the PAR range and other spectrums as it’s been discovered that wavelengths outside of the PAR range are also helpful for plant growth.
The peak of photosynthetic efficiency (light absorption) falls in the red light and blue light spectrums of the PAR range. Red radiation (around 700nm) is considered most efficient at driving photosynthesis – especially in the flowering stage for biomass growth (important to Cannabis growers). Blue light is essential for both the vegetative and flowering stages of plant growth, but mainly for establishing vegetative and structural growth.
What is the Ideal Grow Light Spectrum for Plants?
The ideal grow light spectrum for plants depends on several factors. These include how specific plants use PAR-spectrum light for photosynthesis but also the wavelengths outside of the 400-700nm range. This light can help accelerate flowering, increase nutrition, speed up rate of growth, etc. If the light source is sole (indoors) or supplementary (greenhouses) also affects which grow light spectrums should be used.
Generally, photosynthetic efficiency occurs at the red and blue peaks which means plants absorb these spectrums most when growing. You might think the ideal grow light spectrum is equal to sunlight – after all, it’s had millions of years of experience – however, it’s more detailed than this.
Sunlight produces a lot of greens, yellows, and oranges – they’re the most readily available spectrums of light. In fact, studies ( 3 ) tell us how green light, while not absorbed by chlorophyll as well as red and blue (hence why most plants appear green), it’s absolutely critical for photosynthesis.
Light spectrums outside of blue and red wavelengths are used least by plants to grow as reds and blues are where most photosynthetic activity occurs – a big reason why full-spectrum grow lights are incredibly efficient because a grower can get very specific.
What is Broad Spectrum Lighting?
Broad spectrum lighting – often referred to as full spectrum lighting, means the complete spectrum of light given by sunlight. This means wavelengths of broad spectrum lighting include the 380nm-740nm range (which we see as color) plus invisible wavelengths too, like infrared and ultraviolet.
One advantage of LED grow lights is they can be set up to produce certain wavelengths for specified periods during the day or night. This makes it ideal for plants because growers can isolate specific spectrum colors depending on crops and growing conditions. Full spectrum lighting can also speed up or slow growth rate, enhance root development, improve nutrition and color etc.
Grow Light Spectrum and Cannabis
The grow light spectrum for Cannabis varies when compared to other plants as growers are focused on maximizing yields, controlling levels of THC and other cannabinoid production, increasing flowering, and to maintain overall uniformity.
Aside from visible colors, Cannabis responds especially well to wavelengths just outside of the PAR range. Therefore, an added benefit of using full spectrum LEDs is the ability to use specific doses of ultra-violet wavelengths (100-400nm), and far-red wavelengths (700-850nm) outside of the PAR range.
For example, an increase in far-red (750nm-780nm) can help stimulate Cannabis stem growth and flowering – something growers want, whereas necessary blue light in minimal amounts, can prevent uneven elongation of stems and leaf shrinkage.
So, what’s the ideal grow light spectrum for Cannabis? There’s no single spectrum since varying light exposure promotes certain plant morphology during different stages of growth. The chart below explains the concept of outer-edge PAR light spectrum use.
Personal vs. Commercial Cannabis
The difference with personal vs commercial grow lights for Cannabis can be determined by a number of factors. Firstly, the available light spectrums in commercial LED grow lights will include the full PAR range and beyond – which is particularly advantageous for Cannabis growers.
Commercial grow lights can be wirelessly configured to put out specific wavelengths and intensities at certain intervals in a 24-hour cycle – grow light settings often work in conjunction with a grower’s HVAC systems too.
With personal LED grow lights, lumens per watt will likely be lower – which makes them less energy efficient with smaller potential yields. Many are not broad spectrum and may only offer small spectrums of blue and red light. Additionally, while personal grow lights will still be inexpensive to run, other factors to be considered include noisier fans, inferior quality plastic casing, shorter LED lifespans and overheating issues.
Should I Use a Different Light Spectrum for Different Plants?
In some crops, blue light can benefit nutritional levels and coloring, and a higher red to far-red ratio can help with leaf size and flowering. It’s why today’s full-spectrum LEDs are so advanced – because by selecting the right quantities of red and blue light ( 4 ), chlorophyll pigments absorb more light they need.
Cannabis growers – who pay attention to UVB/blue for its various structural and THC-potency benefits, which we’ll get into, are predominantly concerned with leaf size and flowering. Therefore, far-red and red light is relatively more important to boost their yields.
Other indoor growers are also experimenting with the controlled use of far-red spectrum, like salad leaf farmers for example. Plants associate this spectrum with shading from direct sunlight, which would happen lower down the canopy, causing leaf & stem stretching as the plant reaches out for sunlight.
This means when used strategically, bigger leaves and flowering can occur without unnecessary stress. So while there is no specific LED grow light spectrum for any particular plant, the ratio of red to blue light is very important to maximize growth and the rate of photosynthesis.
Spectrum for Photosynthesis, Growth, and Yield
For photosynthesis to occur and chlorophyll to absorb the maximum amount of light for plant growth, plants use both blue and red light most efficiently. Other spectrums of light, like greens/yellows/oranges, are less useful for photosynthesis due to the amount of chlorophyll b, absorbed largely from blue light, and chlorophyll a, absorbed largely from red and blue light.
It’s worth noting photosynthesis is more complex than just chlorophyll absorption, but it’s important to recognize the fundamental principles.
For growth, blue light is essential to help plants produce healthy stems, increased density, and established roots – all which occur in the early vegetative growth stages. Growth then continues with increased red light absorption, resulting in longer stems, increased leaf and fruit/flowering etc. It’s here that red light plays the dominating role in plant maturity and, therefore, size.
And finally, yield – this comes down to a combination of light spectrums and is often very unique to growers, including growers of several varieties of the same crop (like Cannabis). There’s no one single light spectrum that produces more of a crop – optimal lighting is very much a holistic, ever-changing process.
Grow Light Spectrum by Type
Certain light spectrums trigger growth characteristics in plants. In general, blue light spectrums encourage vegetative and structural growth and red light promotes flowering, fruit, leaf growth, and stem elongation. Each crop type is sensitive to different spectrums and quantities of light at different times throughout a daylight cycle – this directly affects the rate of photosynthesis.
Essentially, we know that controlling grow light spectrum can have a significant impact on areas of growth – like flowering, flavor, color, compactness etc. However, it’s important to recognize that signaling specific growth factors is part of a much larger, complex cycle. Results also vary depending on the environment (indoor or greenhouse), the relative temperature/humidity, crop species, light intensity (lumens per watt), and photoperiod etc.
Let’s look at specific grow light spectrums and their application in horticulture.
UV Light Spectrum (100–400 nm)
UV light spectrum, which is not visible to the human eye, is outside the PAR range (100nm-400nm). Around 10% of the sun’s light is ultraviolet, and like humans, plants can be harmed from overexposure to UV light. Categorized into 3 types, UV-A (315-400 nm), UV-B (280-315 nm), and UV-C (100-280 nm).
While the benefits of ultraviolet light use in horticulture are still being researched, UV light is often associated with darker, purple coloring – in fact, small amounts can have beneficial effects on color, nutritional value, taste, and aroma.
Research shows environmental stress, fungus, and pests can also be reduced using controlled amounts of UV. Research has emerged that suggests an increase in cannabinoids like THC ( 5 ) in Cannabis can be achieved using UV-B light (280nm – 315nm).
Blue Light Spectrum (400–500 nm)
Blue light spectrum is widely responsible for increasing plant quality – especially in leafy crops. It promotes the stomatal opening – which allows more CO2 to enter the leaves. Blue light drives peak chlorophyll pigment absorption which is needed for photosynthesis.
It’s essential for seedlings and young plants during vegetative stages as they establish a healthy root and stem structure – and especially important when stem stretching must be reduced.
Green Light Spectrum (500–600 nm)
Green wavelengths have been somewhat written off as less important for plant photosynthesis given it’s (in)ability to readily absorb chlorophyll compared to red or blue light spectrums. Nonetheless, green is still absorbed and used for photosynthesis; in fact, only 5-10% is actually reflected – the rest is absorbed or transmitted lower down! This is due to green light’s ability to penetrate a plant’s canopy
In greenhouses, due to the presence of sunlight, supplementing green light spectrum using LED grow lights would be less important compared to crops are grown solely indoors – like Cannabis or vertical crop farming.
Red Light Spectrum (600–700 nm)
Red light is known to be the most effective light spectrum to encourage photosynthesis as it’s highly absorbed by chlorophyll pigments. In other words, it sits in the peaks in chlorophyll absorption. Red light wavelengths (particularly around 660nm) encourage stem, leaf, and general vegetative growth – but most commonly, tall, stretching of leaves and flowers.
A balanced pairing with blue light is necessary to counteract any overstretching, like disfigured stem elongation. It’s important to consider that while red is the most responsive light spectrum for plants, its efficacy really steps in when in combination with other PAR wavelengths.
Far-red Light Spectrum (700–850 nm)
There are a few ways far-red can affect plant growth – one is to initiate a shade-avoidance response. At around 660nm (deep red) a plant senses bright sunlight exposure. From 730nm and beyond – i.e. a higher ratio of far-red to red light, a plant will detect light “shade” from another plant or leaves higher up the canopy, so stretching of stems and leaves occurs.
Far-red can be very useful to promote flowering, and in certain plants, increase fruit yield ( 6 ). In short-day plants like Cannabis, which rely on longer periods of darkness, 730nm can be used at the end of a light cycle to promote flowering. Many growers are experimenting with interrupting the dark cycle with bursts of red light to boost growth and flowering.
Finding the Right Grow Light
There’s a great deal of information and science to take on board as we understand the way plants interact with different light spectrums. Optimizing yield production and consistent quality of plants we’ve learned are attributed to light spectrums used together – much like natural sunlight.
At BIOS we’re constantly developing our knowledge and research of how light spectrums on specific crops and strains work best – and at which time during a plant’s light cycle. Our LED grow lighting systems are designed and developed using detailed scientific research to give growers the control of using the ideal light spectrum for optimizing the yield, quality, and variability of their plants.
What is the ideal grow light spectrum for plants? Do different plants need different LED lights? What about for cannabis growth? Learn more from BIOS!