Aquarium Lighting: Spectrum and Intensity

Spectrum and Intensity

Aquarium lighting not only enhances the appearance of your aquarium, it also helps boost the general health of your fish, plants, and invertebrates. When designing a lighting system for your aquarium, you should try to duplicate - as closely as possible - the conditions in which your aquarium pets would live naturally. Thankfully, technological advancements in aquarium lighting over the past decade have significantly simplified the task of simulating natural conditions. This two-part article will explain the characteristics of light and discuss the duplication of natural light in fish-only, freshwater planted, and saltwater reef aquariums.

Several factors including water depth, water clarity, weather, and air clarity affect the color and intensity of light in natural aquatic environments. These factors, combined with varied overall water conditions between individual aquatic habitats, cause light spectrum and intensity to differ from one aquatic environment to another.

Understanding how aquarium lighting duplicates natural underwater lighting conditions requires an understanding of how these conditions are measured.

Light Spectrum - Measured with the Kelvin Scale

The spectrum or "temperature" of light is measured in degrees Kelvin (K). The Kelvin scale describes the color of a light source when compared to a theoretical "blackbody." Think of a piece of steel that changes color as it is heated. The Kelvin scale does not measure the light the steel gives off as it is heated; instead, it measures the color of the light being given off. Color temperature does not represent the temperature of the light source. It merely defines the color given off in comparison to a blackbody radiating at the same temperature.

At 0 degrees Kelvin (equivalent to -273° Celsius), the theoretical blackbody emits no light. As the blackbody warms, it begins emitting red light. As the blackbody continues to increase in temperature, light wavelengths become more yellow, then green, blue, and finally violet. A candle flame on the Kelvin scale has a rating of 1800° K. Sunlight at noon, with a Kelvin rating of 5500° K, is typically referred to as full spectrum because it contains a blend of all colors throughout the spectrum. Reddish light has a lower K rating and color temperature, while bluer light has a higher K rating and a higher color temperature.

In nature, as light enters and passes through the first 15 feet of water, the red and orange wavelengths are absorbed by the water, increasing the light's K rating, and giving the light a bluer appearance. As the light penetrates to 30 feet, the water absorbs the yellow spectrum. And as the light continues past 50 feet, the water filters the green wavelengths, leaving just the blue and violet wavelengths. This results in light with the highest Kelvin rating.

Light Intensity - Measured in Lux and Watts

Light intensity can be measured in two ways: at the surface it impacts (in lux), and at its source (in watts).

Lux

Light intensity measured at an impacted surface is expressed in lux, an international metric unit of measurement similar to a foot-candle: 1 foot-candle equals 10.7 lux. The intensity of the sun on the water surface above a reef can reach values exceeding 120,000 lux. However, varied weather patterns and air quality causes this measurement to average approximately 75,000 lux. As sunlight enters the water and the different wavelengths are absorbed, the light intensity diminishes.

Water clarity determines the speed at which light degrades in different aquatic environments. For example, the level of intensity on a reef with clear water will average about 20,000 lux at a depth of 15 feet, and 10,000 lux at 30 feet. Knowing where an organism lives in nature will give you a good idea of the light intensity required to maintain that organism in your aquarium. Lux meters are relatively inexpensive, and can be used to check your lighting for required intensities, as well as to determine when bulbs in your lighting system need replacing.

Watts

Light intensity at the source is measured in watts. The higher the watts, the more intense the light, and the more energy required to produce the light. A 100-watt bulb, for example, will give off more light than a 40-watt bulb, and will cost more to use.

A watt is actually related to a lux. One lux is equal to 1.46 milliwatts (0.00146 watts) of energy of one specific frequency (555 nm) hitting a surface area of one square meter. However, since bulbs used in aquarium lighting systems emit light of many frequencies (not just 555 nm), no exact formula can be used when determining the number of lux produced by a bulb of a specific wattage.

Spectrum and Intensity

Fish-only Aquariums

Lighting on a fish-only aquarium provides fish with a simulated day and night cycle necessary for overall health. However, since fish are non-photogenic organisms, light spectrum and intensity in a fish-only aquarium are not as vital to health as in a planted or reef aquarium. Therefore, the lighting system for a fish-only aquarium can be designed around other factors such as cost and aesthetics.

When selecting your fish-only aquarium lighting system, take into account not only the initial cost, but also the operating cost. Choose a lighting fixture that does not require excessive amounts of electricity or frequent bulb changes. When shopping for lamps for your fish-only aquarium, choose a bulb rated at two watts per gallon of water in your aquarium (for example, choose a 60-watt bulb for a 30-gallon aquarium). Due to their relatively low initial cost and operating costs, standard fluorescent systems or power compact fluorescent systems work well for fish-only aquariums.

Once you've selected your lighting system, you can choose a bulb with a spectrum based on your personal preference. A lamp with a low Kelvin (K) rating (towards the redder end of the spectrum) will exhibit more vivid colors than a lamp with a higher Kelvin rating (and a bluer color). However, lamps with a low K rating tend to promote algae growth, resulting in more aquarium maintenance. If your goal is to illuminate your aquarium with a color-enhancing bulb, you can avoid excessive algae growth either by using a liquid algae destroyer, or by decreasing the daily number of hours during which the light is on.

Freshwater Planted Aquariums

Before choosing a lighting system for a freshwater planted aquarium, visit a reputable online resource such as LiveAquaria.com, peruse a book, or ask a vendor for details about the amount of light necessary for the specific types of plants you plan to keep. Once you have chosen your plants, look for a lighting system that can effectively simulate the intensity and spectrum of light they receive naturally. Generally, you should provide between 2 and 5 watts per gallon depending on the species of plant you plan to keep. You will also need to consider initial and operating costs, and the heat generated by the lighting system.

Most of today's freshwater aquatic plants originated in the shallow tributaries and rivers of Central and South America, where the natural water clarity was typically murky to stained. Because these plants are naturally accustomed to living in dirty shallow water in bright sunlight, you should provide a full spectrum range of light (5500 K to 7500 K) to simulate natural daylight. However, due to varied water qualities in their natural habitats, the light intensity required for freshwater plants will also vary. Between 2 and 5 watts per gallon should be adequate.

The initial and operating costs for lighting systems on freshwater plant aquariums depend on the type of system you select, as well as the type of ballast you use with your system. Keep in mind that an initially pricey system may save you money in the long run by using less electricity and requiring less frequent bulb changes. Also, when considering a lighting system for your freshwater plant aquarium, make sure that bulbs are available for that system in the proper spectrum range. Some lighting systems do not offer the full-spectrum bulbs ideal for freshwater planted aquariums. Power compact fluorescent and metal halide lighting systems with carefully selected bulbs work well for freshwater planted aquariums.

Further, lighting systems appropriate for a freshwater planted aquarium usually give off large amounts of heat. This must be addressed during system installation. You'll most likely need to incorporate one or more cooling fans and possibly a water chiller to maintain proper water temperature in your aquarium. Room temperature can also have an effect on aquarium temperature, and must also be addressed during aquarium setup - be sure to place your aquarium in a room that does not experience temperature extremes (hot or cold), and a room that will not become excessively warm from the heat given off by the lighting system.

Saltwater Reef Aquariums

Photosynthetic corals and invertebrates in a saltwater reef aquarium rely heavily on light for their nutritional needs. Therefore, adequate lighting is very important. However, do not assume that all corals and invertebrates require high levels of light; some varieties have adapted to living in low-light conditions, since varied water depths in natural coral reefs cause light spectrum and intensity to vary accordingly.

Most corals for the aquarium hobby live naturally in areas surrounding a reef at a depth of 15 to 65 feet. In the wild, these corals typically receive light with a high Kelvin rating (blue in color).

Consider initial and operating costs; lighting intensity and spectrum; and the system's radiant heat when choosing a lighting system for your saltwater reef aquarium. Lighting systems for reef aquariums, such as metal halide and HQI systems, tend to be rather expensive due to their high initial cost, high levels of required energy, and characteristically frequent bulb changes.

To adequately illuminate reef aquariums 24" deep, plan on providing between 4 and 6 watts of light per gallon of water. Shallow reef aquariums (less than 16" deep), and reef aquariums specifically designed for low-light or non-photosynthetic corals and invertebrates do not require the intensities of taller aquariums. However, under no circumstances should you provide photosynthetic corals and invertebrates with less than two watts of light per gallon of water; they will not have enough light to survive.

Natural conditions have caused all corals and invertebrates to adapt to bluer light. Therefore, most lighting systems include bulbs that focus specifically on blue wavelengths. Fluorescent systems, for example, offer blue bulbs called actinic bulbs. While most corals and invertebrates thrive under blue light, most people find blue-lit reef aquariums rather unattractive. This aesthetic dilemma can be solved by combining an actinic light with a white light. Most reef aquariums thrive under a half-and-half blue/white light combination in which the white lights give light in the range of 8000 to 12000 K. This lighting combination gives corals and invertebrates the spectrum necessary for growth, in addition to the spectrum necessary for accurate color rendering within the aquarium.

Lighting systems designed for reef aquariums produce two types of intense heat, which must be addressed prior to installation. The first type of heat - from the actual bulbs - surrounds the bulbs and should be removed with cooling fans. The second type of heat - radiant heat produced by the lighting system - is unavoidably absorbed by the aquarium water and should be controlled with a water chiller (be sure to budget for a water chiller in your installation plans).

Consider the types of corals and invertebrates you wish to keep before you choose a lighting system for your saltwater reef aquarium. Once you have selected your new pets, look for a lighting system that can effectively simulate the intensity and spectrum of light they receive naturally. You will also need to consider initial and operating costs, and the heat generated by the lighting system.

Conclusion

When choosing lighting for your aquarium, keep your inhabitants' natural lighting conditions foremost in your mind. Budget for and select the necessary lighting components that will provide your new fish, plants, corals, or invertebrates with the spectrum and intensity of light they receive in their natural habitats. Successfully duplicating these conditions greatly increases both the survival and growth rate of these organisms, while giving you a beautiful, enjoyable aquarium.