Looking for high quality LED grow lights at an affordable price online? Then you’re in luck, because GrowAce is your source for LED’s. Whether you’re looking for supplemental lighting or you want to replace your H.I.D. system, we’ve got what you need to grow as big as you want with a fraction of the energy you’ll use with other lighting systems. Don’t bother hunting around your local hydro shops or building your own- let us take care of your lighting needs with our LED grow light kits.
We offer the latest and greatest units on the LED market. The Advanced Spectrum line of LED’s offer dual lens technology to give you intense, focused light down on to your grow with a good spread across your plants. They also have 1w and 3w chips in each diode for the power you want at the spectrum you need (and some lights are even equipped with Infrared diodes to help stimulate resin growth). The California Light Works line of lights offer both strong LED diodes as well as T5 fluorescent peripheral lights to help give your vegging and flowering plants an extra boost of blue light. Both LED’s also offer heat sync technology to help cool the light faster and more effectively than other lights on the market.
No matter what you’re trying to grow, we’ll set you up with the LED grow lights best suited for your garden. Need some lights to clone? Try a few 14w or a 50w LED panels above your starter cells to get those clones nice and tall. Those HID’s not covering your plants completely? Advance Spectrum 36w LED grow bulbs can be plugged in to a flood light socket, and placed anywhere around your plants that needs a little more light. And for anyone growing full-sizes plants, we’ve got an array of lights that’ll cover 4 feet of space and more!
LED Grow Light Buyer's Guide
If you’re reading this, chances are this isn’t your first look into LED grow lights. In fact, you’ve probably already searched online for the right info, but now you have more questions than answers.
“Diodes? Chips? Targeted wavelengths? 4000k? Primary vs. supplemental lighting?”LEDs may have sounded great at first, but after so many questions, you find yourself on the verge of going with an HID or not growing at all.
LED grow lights may seem a little intimidating at first, but once you gain the knowledge about LEDs, you'll find that they can give you the same yields — if not better — compared to HIDs. That’s where this guide comes in handy.
In this guide, we’ll walk you through theins and outs of LED grow lightsto help you understandwhat makes them so useful in the grow room orgrow tent, andhow to make the best choice for your plants. From what they do to how they’re made, all the way to choosing the right setup for your grow room, this guide will be a roadmap on the way to high-quality harvests using LEDs.
As the name suggests, these types of grow lights use light emitting diodes (LEDs) to grow plants instead of high pressure sodium, metal halide, or fluorescent light bulbs. LEDs are electronic-based, which makes them the only type of light that doesn’t require a chemical reaction to work. This opens up a whole host of advantages over HIDs that we’ll discuss in a bit.
While LEDs vary in design and intensity, they all work essentially the same way:
When an LED grow light is turned on, energy in the form of electricity is given to diodes on the light.
The electricity runs into the diode and streams across it a computer chip, which creates electromagnetic radiation.
Note: The size (wattage) of the chip will determine how bright a diode will be, andthe number of diodeson a light will determine the grow light'soverall strength.
The radiation created in this process results in visible light, which we can see with our eyes and, most importantly, can be utilized by plants.
The radiation generated by LEDs naturally is a piercing blue. A phosphor coating is added over the chip to defuse it so it’s not hyper intense, which would harm the chlorophyll in a plant. Chip dye can be added to each diode to give off particular photons (colors) of light outside of the white/yellow/orange light we’re used to seeing. The strength of each chip, the photons they emit, and the number of diodes in a grow light all come together to give you an LED.
Setting Up an LED Grow Light
Interestingly enough, LED grow lights offer a few assembly and setup options. Most LEDs don’t require you to put anything together, unlike HIDs that require you to assemble a reflector, ballast, and bulb. For the most part, they’re straightforward:
Install the light hangers onto the LED light/panel.
Hang the lights above your plants.
Plug in your lights to their power outlets and turn on the lights.
Now, there are lights like those fromHorticulture Lighting Groupthat requiresome assembly. Though it’s not difficult, you’ll receive a mounting board, a driver, and a number of LED panels to install. In these cases, here’s what you’d do:
Lay out the mounting board and lay out each panel where they belong on the board.
Fasten the panels to the mounting board. Some use screws, while others may use an adhesive, so adhere the diodes to the board as instructed.
Install the driver (a ballast for LEDs) where instructed, usually on the back of the mounting board.
Wire the diode panels into the driver.
Install your mounting hardware and hang your LED grow light over your plants, then plug your light in and turn it on.
There are also certain lower wattage LEDs bulbs that you can install into flood lights, too. Those are as simple as screwing the LED bulb into the flood lamp, plugging in the lamp, and turning it on.
Why Grow With LEDs?
LED grow lights have gone through a number of improvements to get to where they are today, so it makes sense that many growers are wary of them. On the flip-side, HIDs have been around much longer than LEDs and have become a tried and true way to grow indoors. In the end, though, LED grow lights have proven their efficiency and effectiveness in the grow room. Here's why:
Low Heat Generation — LED grow lights are theonlylights around that don’t need to heat up metal or gases to extreme temperatures, unlike HIDs. That energy and the heat created by it are why HIDs get so hot and end up adding heat to yourgrow room. The heat from the radiation that LEDs emit is minimal — nowhere near the heat generated by HID lights. This heat is more of anice addition to your gardencompared to an HID's heat, which can create stressful, overheated conditions for your plants if not regulated.
Low Energy Consumption — LEDs usemuch less energyto run than HIDs. Consider theAdvance Spectrum 680W Sun Series Model-E LED Grow Lightthat consumes around465wof power but has almost the same intensity as a1000wHID. This LED gives youthe same amount of PPFDas an HID twice its wattage, and you won’t need to regulate its heat. Cooling and ventilation equipment will need to work less with LEDs, which will reduce yourenergy consumptioneven further.
Pinpointing Vital Wavelengths Plants Need — LED grow lights are great at giving plants thespecific wavelengths of light beneficial to growth. Plants only absorb certain wavelengths of light, so the drawback to HIDs and T5s is that plants waste a lot of the light their broad spectrums provide. LEDs have the ability to pinpoint andincrease the availability of various blue and red wavelengths — eveninfraredandultravioletwavelengths — your plants need so they get as many usable wavelengths as possible.
There are LEDs that offer youall white spectrums of light just likeCMH grow lights, as well aswarm and cool spectrums likeHIDsandT5s. No matter what style of light you’re used to or want to try, you’ll be able to find an LED grow light with the spectrums of light you need to get your plants where you want them to be.
Depending on the type of LED you have, you even have the ability to control the wavelengths of light you give your plants.KINDandMINTLEDs, for example, allow you to control the number of colored and white diodes your light gives off. That sort of customization is impossible with HIDs.
LED Grow Lights Inside and Out
While LED grow lights (electronic) may operate in a different way than HIDs (chemical), they're essentially made with the same parts. You have the diode that emits light like a bulb, a driver that transfers energy to your diodes like a ballast, and the housing of your LED which acts more or less like a reflector.
With that in mind, let’s break down the major components of a grow light: diodes, power supply, and housing.
A diode is what’s used to translate electricity to visible light in an LED. While a diode itself contains lots of different parts (like wires, heat sinks, and bases), we’ll focus on the main components in the diode: the chip and the lens.
Chipsare the surfaces that electricity runs across to give us light. The brightness of a diode is based on the strength and number of chips inside, and each of those chips has a wattage it takes to give off light.
Most LEDs use .5w, 1w, 3w, and 5w chips that offer you a certain amount of lumens. The more lumens a chip can give off, the brighter the diode will be. The more diodes you have, the stronger the overall LED grow light will be. And the more lumens a light has, the better it will be at penetrating your plants' canopy for vigorous growth.
It should be noted that the more chips you have on a diode’s surface, the higher the lumen output will be out of a diode. For example, COB chips work by using a lot of little, low wattage chips (around .25 to .5w) on a relatively small surface. All of these tiny chips come together to give you a super bright light, even with a phosphor cover.
Dying and Covering Chips — Chips are usually (but not always) dyed to give off a certain color that mimics a particular wavelength of light along the light spectrum. Non-programmable diodes are dyed the color they should be, whereas diodes in adjustable LEDs are dyed blue, red, and green. The particular color combination will allow you to get white, blue, red, green, and violet wavelengths that plants need.
Whether they're dyed or not, a small phosphor cover is placed on the chips to dampen the piercing light that electricity gives off from the chip. In the case of ultraviolet diodes, the chip cover is made of crystals like sapphire to offer that intense wavelength when light radiation is offered. Infrared diodes, on the other hand, have secondary internal reflectors that filter light coming out so that only IR wavelengths of light are emitted.
The lenscovering each diodehelps focus the light coming from each chip so that it doesn’t emit into the open air unfocused and ineffective. This lens is what facilitates the intensity of the light given off by the chip. Therefore, the type of lens a diode has will help determine how the light is focused down onto your plants.
Contrary to popular belief, the beam angle (or the width of the beam of light coming out) doesn’t depend solely on the type of lens used. Rather, it comes from how close a chip is to the lens. The further a chip is from the lens, the more narrow and intense the light will be coming from the diode. The closer the chip is to the lens, the wider and softer the beam of light will be. Here’s what this idea looks like in real life:
180° beam angles are achieved with simple protective covers over chips. The spread on these lights is wide, giving you a big lighting area that can cover lots of plants. Though that wide coverage area isn’t filled with intense PPFD, getting more intensity you’ll only requires more chips and/or higher wattage chips. That’s why spread-style LEDs are the most common lights that offer 180° angles, as they contain hundreds of smaller low wattage chips that cover wide canopies with soft but effective light.
90° beam angles start out with thick, domed lenses. The chip of a 90° beam is raised close to the dome of the lens to offer a wide but intense beam of light down onto your plants. These are traditionally used on COBs and traditional lights because of their ability to spread light while focusing lots of it down onto plants for intense growth.
60° beam angles come from the same thick lenses, only this time the chip sits around halfway between the chip and the top of the lens. This beam of light is more narrow, and while it does offer much more intensity for your plants than 180° and 90° beams, it also offers less coverage area. If you’ve ever seen an LED that touts extreme intensity, chances are the light produces 60° beam angles or offers a dual lens.
Dual lens diodes contain two lenses: the primary lens, which gives your plants an initial 90° beam angle, and the secondary lens, which takes that 90° beam and intensifies it by focusing it into a 60° beam. This intensity helps canopy penetration from far distances.
Diodes on an LED grow light are arranged in certain combinations to ensure it works properly depending on the drivers used. There are two types of arrangements: panels and diode clusters.
An LED panel consists of diodes (usually with 180° beams) wired together and mounted directly to a panel, all illuminating when activated. Supplemental lights are a single panel of low-wattage chips mounted to a surface, whereas standalone lights consist of multiple panels outfitted with a number of 3w chips each. Usually in these arrangements, if one diode goes out, the entire panel will go out.
Diode clusters arrange diodes (usually with 90° and/or 60° beams) in a circular or rectangular shape and place them around the light. These are mostly used in standalone lights because you can fit a number of high-powered diodes into these clusters, and a number of these clusters in a grow light. However, you can find these clusters used in supplemental lights, and each cluster gets its own power supply.
A Quick Note on Bleaching and Leaf Burn
While LED grow lights may not produce heat, the light they do produce is intense. Remember that the light coming from LEDs is the result of electricity, and raw electricity is extremely bright, which is why it needs to be buffered by a cover and lens.
The problem with LEDs is that regardless of how much you dampen chips, the light produced is still super intense. As such, lights that are too close to plants can actually bleach them. When this happens, light damages the chlorophyll in the leaves, flowers, and fruit your plant produces. When chlorophyll is destroyed, plants have a hard time taking in light and breaking it down to use as energy. The plant will usually continue to grow, but it will be weaker, and the color you love on your plants will definitely be tarnished.
We should also mention that while the heat produced by LEDs is very minimal, the electric radiation they create produces heat. Thankfully, lenses and covers help insulate some of that heat, but when plants press up against diodes that’ve been on for hours, there’s a chance the diodes can get extremely hot and start to burn a plant. Some burns can be simple discoloration and damage, while sustained burning can lead to combustion if not mediated.
Fortunately, bleaching and burning are remedied simply by hanging your plants at the right height, which is anywhere between 18in and 30in above plants.
The power supply, or driver, of all LED grow lights is essentially the brains. The driver is what helps regulate the voltage coming into the light so that it doesn’t overpower each diode and cause shorts. It's also responsible for protecting LEDs from power fluctuations that can cause your light to short.
The type of driver used depends on how much power it needs to regulate. There are internal and external drivers that help various types of grow lights depending on the strength of the chips it will need to power.
Internal driversare small but capable of powering a good amount of chips. They’re commonly used for lower wattage grow light panels like the50 Watt Advance Spectrum Dual Band LED Grow Light Panelthat haveone hundred .5w chips, but can be found in higher wattage lights like 100w COBs withone 100w diode.
External driversare capable of poweringmany more chips at much higher wattages. For example, each diode cluster in theAdvance Spectrum 240W Sun Series Model-E LED Grow Lightrequires its own external driver. That’s because each cluster containsfifteen diodes with 3w chips, including UV and IR that require a special considerations. Large panels like those from Black Dog LEDs need to powerhundreds of 3w and 5w chipsacross a number of panels, so they also use external drivers.
Because external drivers take in and distribute so much energy, they have built-in heat syncs and even power fans to keep cool.
LED grow lights don’t use traditionalreflectorslike HID and T5 grow lights do. For the most part, they don’t use reflectors at all. Instead, each driver, diode cluster, and panel is housed in a shell. The shell offers openings for the diodes and chips to emit light from, while offering awhite or silver reflective backgroundto help reflect the light each diode emits down onto your plants.
There are benefits and challenges to using LED grow lights with shells:
If you have a more complicated light — say, a dimmable LED grow light with lots of diode clusters that have their own drivers — shells will help keep all that technology safe from dust and moisture found in the open air. They’re also made with air vents to help air flow to prevent overheating.
LED grow lights without shells, from supplemental lights to high-powered ones, tend to be more minimal in design. When working with these lights, make sure to keep an eye on the moisture and dust around the light. They’ll work as well as lights with a shell, but keep in mind that they're more exposed to the environment.
You shouldn’t be swayed one way or another about a light based on whether it has a shell. Ensuring drivers are able to safely operate and give your diodes energy is just as important, and that will depend on whether your light has a shell or how clean you keep the area around drivers and diodes.
Types of LEDs
Now that you know what LED grow lights are made of, let’s talk about the types of LEDs that are out there for you. There are a lot of styles with their benefits and challenges, so let’s dive into the types of LEDs you can choose from.
Traditional LED grow lights are an industry standard these days. They’re some of the most reliable LEDs on the market, with individual drivers controlling up to 100w per cluster.
Out of all LEDs, traditional lights have the most versatility. Each diode in a traditional LED has 1 to 5w chips depending on the strength of the overall light, with 1 to 2 lenses helping project light. A single lens will a light to give you a 90° focus beam of light, and a secondary lens would give you an extra 60° of focus to intensify that further.
These lights also have the widest spectrum availability. From cool and warm temperatures like T5s to deep purples all the way to UV and IR lighting, there’s virtually no wavelength of light that traditional LEDs can’t give you.
As great as they are, traditional LEDs can be on the heavy side. The stronger the light, the more equipment is used, which adds weight to the light. Any light falling on your plants will harm them, but a high-powered traditional LED like theAdvance Spectrum 900W Sun Series Model-E LED Grow Lightthat weighs over30 lbscrashing down onto your plants will annihilate them, no question.
So when you’re going the traditional route, focus on two things: ensuring it has the spectrums of light your plants need, and that your grow room is equipped to handle at least 25 to 30 lbs securely.
Spread-style LED grow lights get their name from the way the diodes on them are spread across their surface. They’re relatively inexpensive compared to other LED grow lights, and just as effective despite their limited wavelength offerings.
The chips in spread-style LEDs tend to be low, but with the number of diodes on each panel, the possibilities of reaching a high lumen output are virtually endless. That’s because of two key structural factors:
Each diode contains a single .25 to 1w chip.With an average lumen output of 60 lumens per watt, a simple 50w panel with 50 chips can give you 3000 lumens of light — that’s more intense than a 54w T5 6400k bulb.
Spread LEDs usually don’t use domed lenses.This frees up space on each panel to fill with as many diodes as possible. This will both increase the overall intensity of the LED and increase the light footprint it casts.
While they have the possibility for wide, even light coverage, that coverage tends to be less focused than with other LEDs. This results in softer coverage, requiring many more diodes to increase power. When using spread LEDs, be sure you have plenty of room to adjust their height as needed. If you don’t have the room to raise your lights, make sure the spread LED you choose offers a dimming feature.
COB (Chip on Board)
COB stands for “chip on board”, and it’s called that because of the construction of the diodes. Each diode contains many tiny, low-wattage chips that shine together to give you a super charged light out of a single diode.
50w COB diodes, for example, usually have fifty mini 1w chips on one small surface, giving you around anywhere from 3000 to 5000 lumens out of a one diode. That’s right — the same intensity you’d get out of a fifty 1w chips on a larger panel, you can get out of one COB diode. It will take fewer COB diodes to give you the same lumens as a spread or traditional panel, which means you can get high-powered COBs in much smaller sizes than other LED grow lights.
While they offer crazy intensity, the issue with COBs lies within their limited spectrum availability. These are available primarily warm 3500k spectrums and cool 6000k spectrums, but nothing in the way of multi-colored wavelengths, IR, or UV spectrums. However, if you’re looking for a grow light with huge intensity out of a small light, COBs are the way to go.
Primary vs. Supplemental Lighting
Like the names imply, LED grow lights can either be your plants primary source of light, or they can be used to supplement the lights you’re already using.
Your primary lights will have the most significant impact on your plants. Therefore, you’ll want to ensure these lights offer plenty of strength to stimulate plant growth.
At the lower end of the scale you’ll see 210w LED grow lights that offer peak PPFD at 455 or higher, which is good for a single flowering/fruiting plant.
On the higher end, you have 1000w lights that pump out over 1700 PPFD, which is more than enough for 2 to 3 mature fruiting plants per light.
As far as their spectral availability, primary lights come with an array ofmulti-colored spectrums, as well aswhite color temperatures. Some primary lights offer1 spectrum, while other lights have the ability to adjust spectrums. TheKind LED K5 Series XL750, for example, hasprogrammable wavelengthsto offer plants all-red, all-blue, all-white, or a mix of wavelengths depending on the stage of growth. No matter what spectrum of light you give your plants,make sure your primary light has all the wavelengths they need.
Supplemental lights, on the other hand, are made to supplement your primary lighting. You can use them to fill in dark areas around your grow room when your primary lights can’t reach. They're also perfect for seedlings, clones, and young plants because they give them enough light to grow without overwhelming them.
In general, supplemental LEDs are great at giving your plants an additional amount of lumens and wavelengths they need. If your primary light can’t give your plants all the lumens or wavelengths they need, using one or more lower-powered supplemental LED grow lights will help your plants get all the light they need to thrive.
How to Choose the Right LED Grow Light for Your Plants
The LED you choose will be a vital part of your garden’s success, so it’s important to choose the right one. Despite all the knowledge you have about LED grow lights now, it can still be tricky to find the right one for you. So let’s look at the features you should pay attention to when shopping for the best LED for your grow room or grow tent.
Choosing the Wavelengths Your Plants Need
Particular wavelengths of light along the light spectrum stimulate specific functions within the plant. For example, red wavelengths help stimulate flower and bud growth, and blue wavelengths help stimulate branch and leaf growth.
Some LED grow lights target specific wavelengths of light — like 660nm redor465nm blue— by dying their chips a specific color. Other chips are covered and offer spectrums of light like3500kor5000k that give you a wide range of wavelengths depending on the phosphor used. Both are beneficial for your plants, so how are you supposed to know which ones to go with?
In order to know what to choose, it’s important to know what your plants need. Here are the wavelengths your plants will need:
430 to 450 nm blue wavelengths are necessary for root growth.
640 to 680 nm red wavelengths are necessary for stem growth, as well as chlorophyll, flower, and bud production.
IR (710 nm) helps stimulate resin production.
UV (10000k) helps strengthen stems and create stronger plants.
Note: The “K” here stands for Kelvin, which is a measurement of color temperature. The color temperature of a light is a reflection of the color given off by that light, which is usually a form of white light that contain a wide range of wavelengths.
COB and spread LED grow lights often use white light that falls within 3500k and 5000k color temperatures. These two temperatures contain all of the wavelengths of light your plants need, with 3500k offering a little more red wavelengths and 5000k offer more blue.
Lights with these wide spectrums are great for growers used to HPS and MH grow lights who want the same spectral range. While it’s true plants will waste a number of the wavelengths they receive with these color temperatures, they won’t fight excess heat doing so like with HIDs. In this instance, having more spectrums than necessary can be a good thing.
Traditional LED grow lights tend to use what’s known as targeted lighting. Instead of offering huge spectrum ranges, these lights target specific nanometers (nm) of light your plants need instead of giving them with a wide range of wavelengths. These offer designated blue and red wavelengths, along with a range of orange, light blue, and even IR and UV wavelengths for a bump of protection and flavor.
These lights are capable of growing extra strong, healthy plants, as they target wavelengths plants need to ensure they don’t waste any energy getting rid of light. Because they’re so targeted, though, it’s important to make sure the wavelengths fall within the ranges above. Without them, your plants are going to struggle to grow.
Now, of course, wavelengths of light are only as helpful as the diodes that emit them. After you figure out which wavelengths of light you want to work with, it’s time to figure out the strength you’ll need for your grow room.
Choosing the Strength Your Plants Need
The strength of an LED grow light is going to determine how effectively your plants grow. If your grow light’s too strong for your plants, you’ll end up bleaching and burning them. Too weak of a light and your plants will grow underdeveloped, stretched out, and they’ll be unable to support themselves.
In order to figure out how strong of a light you need, you’ll first want to find out what the amount of usable light — i.e., PPFD, measured in micromoles (µmol) — your plants need. According to experts, most plants thrive off 65µmol (PPFD) per sqft, so it’s our job as growers to make sure our plants get the proper amount of light they need to thrive.
It’s important to remember that when we’re talking about lighting requirements, we’re speaking about lighting the canopy. A garden’s canopy is the leaves and growth that need to be lit, not the entire growing area. Keep this in mind because if you get a light for your entire growing space instead of the canopy, you risk getting a light that’s too strong for your plants. Moreover, note that all plants are different and will require research as to their specific recommended PPFD.
Calculating the PPFD Your Plants Need
To calculate the PPFD your plants need, here’s what you’ll want to do:
Measure the length, width, and height of your canopy. Remember: The canopy is only the area you plan on lighting — it should only be the amount of greenery you plan to cover in light. For example, if you lollipop your plants, the height wouldn’t be the entire length of the plant. Rather, it will be just the leaves, flowers, buds, and fruit you want to light, which is usually the top 6 to 10 inches of the plant.
Take the recommended amount of µmol your plants need and multiply it by the volume of your canopy.
Though recommendations for plants are measured insqft, it’s important to also account forlight penetration. This can be done by alsoadding in the height of your plants.
Let’s put this into action. Say that your garden’s canopy measures 3ft x 3ft x 10in (we’ll round that up to 1ft), and your plants need 65µmol/sqft.
3 x 3 x 1 = 9cu ft to cover
9 x 65µmol = 585µmol (PPFD) required for your plants
Once you have the PPFD your grow room needs, it’s time to find the light that can meet it. To do that, make sure the LED grow light you’re looking into has PPFD charts to show its PAR ratings and intensity at different heights. From there, keep a few things in mind:
If you have a big canopy that requires lots of PPFD, it’s better to use multiple lower-watt lights instead of one powerful light. This will give you more even light coverage across your canopy, resulting in more uniform harvests (i.e., the same size buds/fruits/flowers).
The shape of the light will play a big part into its footprint, and subsequently its effectiveness on your grow. The wider/narrower a light is, the wider/narrower its footprint will be. Rectangular LEDs, for example, have great intense coverage horizontally but have weaker coverage vertically. Square LEDs, on the other hand, have a more even footprint.
Make sure you have the space to fit the LED grow light you need in your growing area. For example, if you need a light that measures 2ft x 3ft, be sure your grow tent or growing area is at least 4ft x 4ft to be sure you have plenty of room for your plants and grow light.
Diode layout and type are different from light to light. Three LEDs can offer you a peak PPFD of 1000 µmol, but depending on the number and type of diodes used in the LED, the light will be different.
A single COB can be up to 100w, which means you’ll need only a few of these diodes on a light for high intensity. However, that means the light will be relatively small, giving you a smaller footprint than others.
Traditional LEDs are equipped with a number of 1 to 3w diodes and 90° and/or 60° lenses to keep up with larger wattage lights. To match one 100w light, a traditional light would need anywhere between 30 to 50 diodes with 2w or 3w chips. This will give you a rectangular footprint with intense coverage in the center of the canopy, though it will become weaker on the outsides.
Spread LEDs usually have lots of diodes with .25 to .5w chips on a surface. To reach 100w, for example, you’d need at least 200 to 400 diodes. This results in physically larger lights than lights with stronger chips, which actually benefits your plants. Though the light they give off is not super intense across the board, it’s much more even than other LEDs.
Growing with LED Grow Lights
So there you have it, folks! From the construction down to the very diode, you’ve learned everything there is to know about LED grow lights and what to look for when shopping for one. Now you’re ready to make the best, most well-informed decision for your grow.
If it were only that simple, right?
Let’s face it: We can get all the information we need and do all the research possible down to finding the manufacturer of each chip in every diode. The truth is even with all that info, it’s much easier to know what to look for when you have a little help. That’s why we turned to the experts to see what LED grow light brands are the best fit for your grow room.
What the Experts Recommend
When it comes to the best LED lighting, we went to expert LED growers for their recommendations. From fruits and veggies to medicinal plants and flowers, we went on a mission to find you the best brands for the plants you want to grow. Here are the top five LED grow light brands we saw pumping out big, consistent harvests.
We don’t say Advance Spectrum is the best overall brand simply because of these LEDs' intensity (which comes in spades). Advance Spectrum LEDs range from softer 24w supplemental LEDs all the way to intense primary lights of over 900w, all with varying strength diodes tailored to fit any growing style.
The lower-watt (24 to 50w) supplemental lights are spread-style with internal drivers and .5w chips, giving young plants soft light to absorb. Meanwhile, the larger-watt Advance Spectrum Sun Series line of primary LED grow light kits have external drivers, 3w chips in each diode, and even offer IR and UV diodes to boost resin growth and plant strength.
In addition, Advance Spectrum also has the widest selection of lights on this list, with a standard Advance Spectrum line of lights that range from 24w to 50w, in single and multi-colored chips. The high-powered Advance Spectrum Sun Series line from 240w (648 PPFD) to 900w (over 2400 PPFD) are all targeted, highly intense full-spectrum lights. So if you’re looking for a brand that has everything your plants need, as well as costs that go easy on your wallet, Advance Spectrum LED grow lights are what you’re looking for.
The 24w LED lights are great for 1 tray of clones or seedlings, as well as small herbs and spices.
The 50w LED lights work great for 1 to 2 trays of clones and seedlings, as well as herbs and spices.
The 240W LED Grow Light is perfect for 1 to 2 mature flowering plants, along with a host of leafy greens and vegetables.
The 400W LED Grow Light can grow 2 to 4 mature flowering plants, as well as a number of vegetables, including root veggies.
California Light Worksis known for its wide range ofpersonal and commercial LED grow lights, but the company's standout lights have to be theSolarSystem UVBlights. While UVB diodes may be helpful during growth, their effect is minimal compared to a dedicated bulb. Complete with two24w UVB bulbs per light, the SolarSystem550and1100systems give your plants the best, most efficient amount of UVB of any grow lights on this list.
That’s not even mentioning the strength that these lights already offer on their own. These spread-style LED grow lights have high-efficiency OSRAM diodes and offer three programmable spectrums (veg, bloom, and full spectrum). You can even fine-tune wavelengths of light with the included controller for a light crafted just for your plant. On top of that, their diodes kick out some serious power for commercial and at-home grows.
The SolarSystem 550 gives you 888 PPFD with a 4ft x 4ft footprint during flowering and a 6ft x 6ft footprint during flowering. That’s enough for at least 2 mature flowering plants per light.
The SolarSystem 1100 gives plants 1730 PPFD with a 5ft x 5ft flowering footprint and an 8ft x 8ft vegging footprint. That’s enough room and intensity to cover 4 to 5 mature flowering plants.
EachUVB bulbused on these grow lights gives off90 PPFDat36into plants with a4ft x 4ft footprint. Nowdoublethat energy and lower it at6 to 18in lower, and that UVB intensity skyrockets!
While it’s true that too much UV will harm a plant, the T5 fluorescent bulbs included with these lights is softened by phosphor. This helps buffer your plant from too much UV that will harm it, giving your plants only beneficial wavelengths.
If you have extra large plants or need to cover large areas with super intense light, Black Dog LEDs are what you’re looking for. From warehouses to closets, these LEDs offer 2 to 5w chips in each diode, giving these relatively small grow lights huge intensity and wide footprints.
Take the Black Dog LED PhytoMAX-2 200 LED Grow Light, for example. This light offers a 3ft x 3ft footprint at 21in above plants with 330 PPFD at 210w of power. At 16in above plants, that number jumps up to 587 PPFD, which is more than enough light for 1 to 2 plants to thrive in a 3ft x 3ft coverage area. Even a step up with the PhytoMAX-2 400 packs a huge punch, giving you 660 PPFD at 21in above plants. From there, the intensity levels go up even further, as explained below.
The PhytoMAX-2 200 will give you 330 PPFD at 21in above plants, which is enough for a single flowering plant to thrive off.
The PhytoMAX-2 400 offers 660 PPFD at 21in above plants, which will give you enough strength to grow at least 2 to 3 flowering plants in a 4ft x 4ft area.
The PhytoMAX-2 800 gives your plants a whopping 971 PPFD at 25in above plants. That’s enough strength to grow 3 to 5 mature flowering plants in a 6ft x 6ft growing area.
The PhytoMAX-2 1000 gives you an insane 930 PPFD at 29in above plants (so you can imagine the huge jump in strength lowering that down to 25in). This is enough to cover at least 4 to 5 plants in a 6.5ft x 6.5ft area.
Whether you want a couple of super-charged plants or you want to cover a large number of plants across a large area with a single light, all you need is a few Black Dog LEDs to crank out all the light you need.
If you're looking for bigger flavor and stronger aromas, KIND LED's X-Series grow lights will unlock the trichomes in your plants to yield tastier, more aromatic harvests. Their targeted spectrum combines with a secondary UV-IR spectrum to give your plants all the wavelengths of light they need to thrive for huge flowers and fruit.
Each X-Series grow light offers KIND LED's patented targeted spectrum is created for plants to maximize harvest weight and plant quality by giving plants more usable photons of light- not just lots of white light like other LED's offer.
They also implement a dedicated UV/IR channel you can use at any stage of growth to increase resin, trichome, and terpene production.
Each channel on X-series LED grow lights is programmable, allowing you to increase/decrease intensity as you see fit.
The X220offers 561μmol/s, which is enough to grow 1-2 flowering plants to harvest.
The X330offers 841μmol/s, enough to grow 2-3 flowering plants
The X420offers 1071μmol/s, enough to grow 3-4 flowering plants
The X750offers 1730μmol/s which is enough to cover 5-6 flowering plants.
The X2 Commercial lightoffers 1650μmol/s plus concentric square lighting for the most even coverage possible over 5-6 plants.
So if you're after the tastiest, best smelling yields you've ever had, these lights need to be in your grow room. Otherwise, you're losing out on the most intense trichome production possible.
From growerstransitioning to LEDs from HID grow lights, to growers starting their first grow, aHorticulture Lighting GroupLED will give your plants the same great wavelengths tried-and-true HIDs give you, only with a softer (and gentler) light footprint.
The Samsung chips in each diode on these spread-style LEDs are .2w, and the more strength you need out of a light, the more diodes are added. Not only do these diodes come together to create an intense light, the coverage is more even than traditional and COB LEDs. With these lights, the outside parts of your canopy will be lit almost as well as the center of the light, compared to other lights where PAR drops dramatically the further you go out from the center of the light.