The wide kind of aquarithe come currently saved by hobbyists, ranging from either a elementary bowl housing one fish to complex simulated ecosystems by owning carefully engineered trend lines systems. Aquaria come commonly classified when containing newly or even even salt a lake system, at tropical or cold water temperatures. These characteristics, & others, determine a nature & severity of fish & more indweller that could hold out and thrive in the fish tank. Dweller for aquaria come typically collected from either a uncivilized, although there is a growing listing of organisms that are bred inside captivity for supply to the fish tank trade.

the careful aquarist dedicates considerable effort to maintaining a tank ecology that mimics its inhabitants' natural home ground. Controlling water quality includes managing a influx & outflow of food, virtually all notably the management of waste produced by tank inhabitants. A nitrogen cycle describes the flow of n from either input via food, across toxic nitrogen-bearing waste by tank denizen, to metabolism to less toxic compounds by beneficial bacteria populations. More components within maintaining the suitable fish tank environment include appropriate metal money choice, management of biological loading, & full physical project.

History and development
Etymology
A word marine museum itself is taken directly from either a latin peacock blue, meaning a river, using a suffix -rium, meaning "place" or even "building". Ancient practices
A keeping of fish around confined or even unreal environments occurs as practice by using deep roots around history. Ancient Sumerians were known to keep wild-caught fish around ponds, before preparing the children for meals. Around China, selective breeding of carp into today's popular koi and goldfish is believed to have begun above 2,000 years ago. Depictions of the sacred fish of Oxyrhynchus kept inside captivity inside rectangular temple pools stand been encountered in ancient Egyptian art. Several more cultures besides have a history of keeping fish for two functional & ornamental purposes. A Chinese brought carassius auratus inside in a period of the Song dynasty to enjoy them around big ceramic vessels.

Glass enclosures
A conception of an fish tank, designed for the observation of fish inside an enclosed, transparent tank to become saved inside, emerged further recently. Even so, these are hard to pinpoint a accurate date of this development. Around 1665 the diarist Samuel Pepys recorded seeing in London "a fine rarity, of fishes kept in a glass of water, that will live so forever, and finely marked they are, being foreign." A fish found by Pepys were in all probability to keep close at hand been a paradise fish, Macropodus opercularis, a familiar garden fish inside Canton, China, where the East India Company was then stock trading. In the 18th century, the biologist Abraham Trembley kept hydra found in the garden canals of the Bentinck residence 'Sorgvliet' in the Netherlands, in prominent cylindric glass vessels for learn. A conception of keeping aquatic life around glass containers, so, dates to at latest this period of time.

Popularization
the keeping of fish inside an marine museum foremost became a popular hobby within Britain only when ornate aquaria in cast-iron frames were featured at a Great Exhibition of 1851. the framed-glass marine museum was a specialised version of the glazed Wardian case developed for British horticulturists in the 1830s to protect exotic plants on yearn sea voyages. (1 feature of occasionally 19th-century aquaria that would prove curious to hobbyists today was a have of a metal base panel thus that the fish tank a lake can be heated by fire.) Germans rivaled the British in their interest, and per turn of the century Hamburg became the European port of entry for many fresh seen mintage. Aquaria became additional widely popular when houses became about always electrified when World War I. Sustaining electricity great improvements were made inside marine museum technology, permitting unreal lighting also when a aeration, purification, & heating of the a body of water. Popularization was besides assisted per handiness of air freight, which allowed the tremendously wider kind of fish to become with success imported from either distant regions of origin that consequently attracted newly hobbyists.

There are presently forecasted to exist as astir 60 million marine museum hobbyists worldwide, & several supplementary aquaria saved by the babies. A hobby has a strongest ensuing within Europe, Asia, and North America. In the United States, a big minority (40%) of aquarists maintain deuce or additional tanks at any in one case.

Function and design
From either the outdoor pool & glass jars of antiquity, modern aquaria stand evolved into a wide range of specialised systems. Aquarithe could deviate within size from either a little bowl big plenty for one little fish, to the brobdingnagian public aquaria that may simulate entire marine ecosystems. A virtually all successful aquaria, equally estimated per long-semipermanent survivability of its denizen, carefully emulate a natural environments that their residents would occupy in the untamed.

Freshwater aquaria remain a virtually all popular due to their moo cost & more comfortable maintenance, however marine (saltwater) aquaria have gained cachet as dedicated enthusiasts prove these are conceivable to preserve these challenging environments.

Design

the most common freshwater marine museum maintained by the at home aquarist generally includes the refinement models, an unreal lighting models, air pumps, & a heater. Additionally, occasionally freshwater system tanks (& virtually all saltwater tanks) have powerheads to increase water circulation.

Cooperative biological & mechanical refinement systems come okay, commons; which are actually designed to dislodge possibly unsafe build higher of nitrogen-bearing wastes & phosphates dissolved in the water, likewise when particulate. Refining systems come a virtually all complexly engineered component of virtually all residence aquaria, & various designs come utilized. Virtually all systems apply pumps to dislodge the little part of the tank's water supply supply to an external pathway in which refinement occurs; a cleansed water is so returned to the fish tank. Protein skimmers, filtration hardware that dislodge proteins and more waste from either a a body of a river, come normally obtained simply within salt water aquaria.

Air pumps come listed to adequately oxygenate (or even in a out break of the heavy ingrained fish tank, provide carbon dioxide to) the water system. These hardwcome, another time universal, are nowadays somewhat less ordinarily utilized when a few freshly refinement systems produce plenty skin-deep agitation to supply adequate flatulence exchange at a surface. Fish tank heaters come designed to work when thermostats to regulate water system temperature at a level intended per aquarist whenever a prevailing temperature of air surrounding a marine museum is following the desired water temperature. Coolers come as well available for even utilize around cold a body of water aquaria or inside area of a globe in which a ambient room temperature is above the desired tank temperature.

An marine museum's physical characteristics form a second aspect of marine museum project. Size, lighting conditions, density of swimming & rooted plants, placement of bogwood, creation of coffee bar or even overhangs, nature and severity of substrate, and more factors (including an fish tank's aligning in a room) may completely affect the behavior & survivability of tank denizen.

A conjunct work one elements is to maintain appropriate a stream quality & characteristics suitable for the fish tank's residents.

Classifications
Aquaria may be classified by many variables that determine a nature and severity of aquatic life that may be fitly housed. A conditions & characteristics of a a a water supply system contained inside an marine museum come the first classification criteria, when virtually all aquatic life might non subsist possibly limited exposure to unsuitable water conditions. A size of an fish tank as well restricts a aquarist around what types of ecosystems he potty reproduce, metal money choice, & biological loading.

Water conditions
A dissolved content of a a lake supply is perchance a first aspect of water conditions, when dissolved salts & other constituents potty dramatically impact basic fluids chemistry, and so how else parasites come take a breath to interact by owning their environment. Salt content, or even salinity, is the most basic classification of fluids conditions. An fish tank will use fresh water (a salt level of < 0.5%), simulating a lake or river environment; salt water (a salt level of 5%–18%), simulating an ocean or sea environment; or brackish water (a salt level of 0.5%–5%), simulating environments lying between fresh and salt, such as estuaries.

Several other water characteristics result from dissolved contents of the water, and are important to the proper simulation of natural environments. The pH of the water is a measure of alkalinity or acidity. Hardness measures overall dissolved mineral content; soft or hard water may be preferred. Dissolved organic content and dissolved gases content are also important factors.

Home aquarists typically use modified tap water supplied through their local municipal water system to fill their tanks. For freshwater aquaria, additives formulated to remove chlorine or chloramine (used to disinfect drinking water supplies for human consumption) are often all that is needed to make the water ready for aquarium use. Brackish or saltwater aquaria require the addition of a mixture of salts and other minerals, which are commercially available for this purpose. More sophisticated aquarists may make other modifications to their base water source to modify the water's alkalinity, hardness, or dissolved content of organics and gases, before adding it to their aquaria. In contrast, public aquaria with large water needs often locate themselves near a natural water source (such as a river, lake, or ocean) in order to have easy access to large volumes of water that does not require much further treatment.

Secondary water characteristics
Secondary water characteristics are also important to the success of an aquarium. The temperature of the water forms the basis of one of the two most basic aquarium classifications: tropical vs. cold water. Most fish and plant species tolerate only a limited range of water temperatures: Tropical or warm water aquaria, with an average temperature of about 25 °C (78 °F), are much more common and house most popular aquarium fish. Cold water aquaria are those with temperatures below what would be considered tropical; a variety of fish are better suited to this cooler environment.

Water movement can also be important in accurately simulating a natural ecosystem. Aquarists may prefer anything from still water up to swift simulated currents in an aquarium, depending on the conditions best suited for the aquarium's inhabitants.

Water temperature can be regulated with a combined thermometer/heater unit (or, more rarely, with a cooling unit), while water movement can be controlled through the use of powerheads and careful design of internal water flow (such as location of filtration system points of inflow and outflow).

Size

An aquarium can range from a small, unadorned glass bowl containing less than a liter of water—although generally unsuited for most fish (except, perhaps, air breathing fish such as Betta splendens)—to massive tanks built-in public aquaria which are limited only by engineering constraints and can house entire ecosystems as large as kelp forests or species of large sharks. In general, larger aquarium systems are typically recommended to hobbyists due to their resistance to rapid fluctuations of temperature and pH, allowing for greater system stability.

Aquaria kept in homes by hobbyists can be as small as 3 U.S. gallons (11 L). This size is widely considered the smallest practical system with filtration and other basic systems. They can be as large as to 300 U.S. gallons (1100 L). Practical limitations, most notably the weight (water weighs about 8.3 pounds per U.S. gallon (1 kg/L)) and internal water pressure (requiring thick, strong glass siding) of a large aquarium, keep most home aquaria to a maximum of around 1 m³ (300 U.S. gallons). However, some dedicated aquarists have been known to construct custom aquaria of up to several thousand U.S. gallons (several cubic meters), at great effort and expense. Public aquaria designed for exhibition of large species or environments can be dramatically larger than any home aquarium. The Shedd Aquarium features an individual aquarium of two million U.S. gallons (7,500 m³), as well as two others of 400,000 U.S. gallons (1,500 m³). The Monterey Bay Aquarium has an acrylic viewing window into their largest tank. At 56 feet long by 17 feet high (17 by 5 m), it used to be the largest window in the world and is over 13 inches (330 mm) thick. The Okinawa Churaumi Aquarium is the world's second largest aquarium and part of the Ocean Expo Park located in Motobu, Okinawa. Its main tank, which holds 7,500 cubic meters of water, features the world's largest acrylic panel measuring 8.2 meters by 22.5 meters with a thickness of 60 centimeters. The size of public aquaria are usually limited by cost considerations.

Species selection
Several theories on species selection circulate within the community of hobby aquarists. Perhaps the most popular of these is the division of aquaria into either a community or aggressive tank type. Community tanks house several species that are not aggressive toward each other. This is the most common type of hobby aquarium kept today. Aggressive tanks, in contrast, house a limited number of species that can be aggressive toward other fish, or are able to withstand aggression well. In both of these tank types, the aquarium cohabitants may or may not originate from the same geographic region, but generally tolerate similar water conditions. In addition to the fish, invertebrates, plants, and decorations or "aquarium furniture" (all of which may or may not be natural neighbors of any of the fish) are typically added to these tank types.

Species or specimen tanks usually only house one fish species, along with plants, perhaps found in the fishes' natural environment and decorations simulating a true ecosystem. These tanks are often used for killifish, livebearers, cichlids etc. They can be simple as bare bottom with a few necessities or a complex planted aquarium. Some tanks of this sort are used simply to house adults for breeding. Such tanks are common in fishrooms, where people keep many tanks at home.

Ecotype or ecotope aquaria attempt to simulate a specific ecosystem found in the natural world, bringing together fish, invertebrate species, and plants found in that ecosystem in a tank with water conditions and decorations designed to simulate their natural environment. These ecotype aquaria might be considered the most sophisticated hobby aquaria; indeed, reputable public aquaria all use this approach in their exhibits whenever possible. This approach best simulates the experience of observing an aquarium's inhabitants in the wild, and also usually serves as the healthiest possible artificial environment for the tank's occupants.

Species selection for saltwater aquaria
In addition to the types above, a special category of saltwater aquaria is the reef aquarium. These aquaria attempt to simulate the complex reef ecosystems found in warm, tropical oceans around the world. These aquaria focus on the rich diversity of invertebrate life in these environments, and typically include only a limited number of small fish. Techniques of maintaining sea anemones, some corals, live rock, mollusks, and crustacea, developed since the 1980s, have made the recreations of a reef ecosystem possible. Reef aquaria are widely considered the most difficult and demanding of the common hobbyist aquarium types, requiring the most expertise in addition to the most specialized equipment (and corresponding high cost).

Source of aquarium inhabitants

Fish and plants for the first modern aquaria were gathered from the wild and transported (usually by ship) to European and American ports. During the early twentieth century many species of small colorful tropical fish were caught and exported from Manaus Brazil, Bangkok Thailand, Siam, Jakarta Indonesia, the Dutch West Indies, Calcutta India, and other tropical ports. Collection of fish, plants, and invertebrates from the wild for supply to the aquarium trade continues today at locations around the world. In many places of the world, impoverished local villagers collect specimens for the aquarium trade as their prime means of income. It remains an important source for many species that have not been successfully bred in captivity, and continues to introduce new species to enthusiastic aquarists.

The practice of collection in the wild for eventual display in aquaria has several disadvantages. Collecting expeditions can be lengthy and costly, and are not always successful. The shipping process is very hazardous for the fish involved; mortality rates are high. Many others are weakened by stress and become diseased upon arrival. Fish can also be injured during the collection process itself, most notably during the process of using cyanide to stun reef fish to make them easier to collect.

More recently, the potentially detrimental environmental impact of fish and plant collecting has come to the attention of aquarists worldwide. These include the poisoning of coral reefs and non-target species, the depletion of rare species from their natural habitat, and the degradation of ecosystems from large scale removal of key species. Additionally, the destructive fishing techniques used have become a growing concern to environmentalists and hobbyists alike. Therefore, there has been a concerted movement by many concerned aquarists to reduce the trade's dependence on wild-collected specimens through captive breeding programs and certification programs for wild-caught fish. Among American keepers of marine aquaria surveyed in 1997, two thirds said that they prefer to purchase farm raised coral instead of wild-collected coral, and over 80% think that only sustainably caught or captive bred fish should be allowed for trade.

Since the 'fighting fish' Betta splendens was first successfully bred in France in 1893, captive spawning techniques have been slowly discovered. Captive breeding for the aquarium trade is now concentrated in South Florida, Singapore, Hong Kong, and Bangkok, with smaller industries in Hawaii and Sri Lanka. Captive breeding programs of marine organisms for the aquarium trade have been urgently in development since the mid-1990s. Breeding programs for freshwater species are comparatively more advanced than for saltwater species.

Aquaculture is the cultivation of aquatic organisms in a controlled environment. Supporters of aquaculture programs for supply to the aquarium trade claim that well-planned programs can bring benefits to the environment as well as the society around it. Aquaculture can help in lessening the impacts on wild stocks, either by using raised cultivated organisms directly for sale or by releasing them to replenish wild stock (Tlusty 203), although such a practice is associated with several environmental risks.

Ecology
Ideal aquarium ecology reproduces the equilibrium found in nature in the closed system of an aquarium. In practice it is virtually impossible to maintain a perfect balance. As an example, a balanced predator-prey relationship is nearly impossible to maintain in even the largest of aquaria. Typically an aquarium keeper must take steps to maintain equilibrium in the small ecosystem contained in his aquarium.

Approximate equilibrium is facilitated by large volumes of water. Any event that perturbs the system pushes an aquarium away from equilibrium; the more water that is contained in a tank, the easier such a systemic shock is to absorb, as the effects of that event are diluted. For example, the death of the only fish in a three U.S. gallon tank (11 L) causes dramatic changes in the system, while the death of that same fish in a 100 U.S. gallon (400 L) tank with many other fish in it represents only a minor change in the balance of the tank. For this reason, hobbyists often favor larger tanks when possible, as they are more stable systems requiring less intensive attention to the maintenance of equilibrium.

Nitrogen cycle
Of primary concern to the aquarist is management of the biological waste produced by an aquarium's inhabitants. Fish, invertebrates, fungi, and some bacteria excrete nitrogen waste in the form of ammonia (which may convert to ammonium, depending on water chemistry) which must then pass through the nitrogen cycle. Ammonia is also produced through the decomposition of plant and animal matter, including fecal matter and other detritus. Nitrogen waste products become toxic to fish and other aquarium inhabitants at high concentrations.

A well-balanced tank contains organisms that are able to metabolize the waste products of other aquarium residents. The nitrogen waste produced in a tank is metabolized in aquaria by a type of bacteria known as nitrifiers (genus Nitrosomonas). Nitrifying bacteria capture ammonia from the water and metabolize it to produce nitrite. Nitrite is also highly toxic to fish in high concentrations. Another type of bacteria, genus Nitrospira, converts nitrite into nitrate, a less toxic substance to aquarium inhabitants. (Nitrobacter bacteria were previously believed to fill this role, and continue to be found in commercially available products sold as kits to "jump start" the nitrogen cycle in an aquarium. While biologically they could theoretically fill the same niche as Nitrospira, it has recently been found that Nitrobacter are not present in detectable levels in established aquaria, while Nitrospira are plentiful.) This process is known in the aquarium hobby as the nitrogen cycle.

In addition to bacteria, aquatic plants also eliminate nitrogen waste by metabolizing ammonia and nitrate. When plants metabolize nitrogen compounds, they remove nitrogen from the water by using it to build biomass. However, this is only temporary, as the plants release nitrogen back into the water when older leaves die off and decompose.

Although informally called the nitrogen cycle by hobbyists, it is in fact only a portion of a true cycle: nitrogen must be added to the system (usually through food provided to the tank inhabitants), and nitrates accumulate in the water at the end of the process (or contribute to a growth in biomass via plant metabolism). In practice, this accumulation of nitrates in home aquaria requires the aquarium keeper to make periodic water changes, removing water from the tank that is high in nitrates and replacing it with water low in nitrates.

Aquaria kept by hobbyists often do not have the requisite populations of bacteria needed to detoxify nitrogen waste from tank inhabitants. This problem is most often addressed through two filtration solutions: Activated carbon filters absorb nitrogen compounds and other toxins from the water, while biological filters provide a medium specially designed for colonization by the desired nitrifying bacteria.

Cycling
New aquaria also do not usually have the required populations of bacteria for the handling of nitrogen waste. In a process called cycling, aquarists cultivate these bacteria as fish and other producers of nitrogen waste are gradually added to the tank over the course of several weeks. Aquarists use several different methods to jump start this process, including the use of water additives containing small populations of the bacteria, or "seeding" a new tank with a mature bacterial colony removed from another aquarium (such as can be found on gravel or biological filter media).

Other cycling methods that have gained popularity in recent years are the fishless cycle and the silent cycle. As the name of the former implies, no fish are kept in a tank undergoing a fishless cycle. Instead, small amounts of ammonia are added to the tank to feed the bacteria being cultured. During this process, ammonia, nitrite, and nitrate levels are tested to monitor progress. The silent cycle is basically nothing more than densely stocking the aquarium with fast-growing aquatic plants and relying on them to consume the nitrogen products rather than bacteria. According to anecdotal reports of aquarists specializing in planted tanks, the plants can consume nitrogenous waste so efficiently that the spikes in ammonia and nitrite levels normally seen in more traditional cycling methods are greatly reduced, if they are detectable at all.

Improperly cycled aquaria can quickly accumulate toxic concentrations of nitrogen waste and kill its inhabitants.

Other nutrient cycles
Nitrogen is not the only nutrient that cycles through an aquarium. Dissolved oxygen enters the system at the surface water-air interface or through the actions of an air pump. Carbon dioxide escapes the system into the air. The phosphate cycle is an important, although often overlooked, nutrient cycle. Sulfur, iron, and micronutrients also cycle through the system, entering as food and exiting as waste. Appropriate handling of the nitrogen cycle, along with supplying an adequately balanced food supply and considered biological loading, is usually enough to keep these other nutrient cycles in approximate equilibrium.

Biological loading
Biological loading is a measure of the burden placed on the aquarium ecosystem by its living inhabitants. High biological loading in an aquarium represents a more complicated tank ecology, which in turn means that equilibrium is easier to perturb. In addition, there are several fundamental constraints on biological loading based on the size of an aquarium. The surface area of water exposed to air limits dissolved oxygen intake by the tank. The capacity of nitrifying bacteria is limited by the physical space they have available to colonize. Physically, only a limited size and number of plants and animals can be fit into an aquarium while still providing room for movement.

In order to prevent biological overloading of the system, aquarists have developed a number of rules of thumb. Perhaps the most popular of these is the "one inch of fish per U.S. gallon" rule, which dictates that the sum in inches of the lengths of all fish kept in an aquarium (excluding tail length) should not exceed the capacity of the tank measured in U.S. gallons (about 7 mm per liter of water). This rule is usually applied to the expected mature size of the fish, in order to not stunt growth by overcrowding, which can be unhealthy for the fish. For goldfish and other high-waste fish, some aquarists recommend doubling the space allowance to one inch of fish per every two gallons.

The true maximum or ideal biological loading of a system is very difficult to calculate, even on a theoretical level. To do so, the variables for waste production rate, nitrification efficiency, gas exchange rate at the water surface, and many others would need to be determined. In practice this is a very complicated and difficult task, and so most aquarists use rules of thumb combined with a trial and error approach to reach an appropriate level of biological loading.

Public aquaria
Public aquaria are facilities open to the public for viewing of aquatic species in aquaria. Most public aquaria feature a number of smaller tanks, as well as one or more large tank greater in size than could be kept by any home aquarist. The largest tanks hold millions of U.S. gallons of water and can house large species, including dolphins, sharks or beluga whales. Aquatic and semiaquatic animals, including otters and penguins, may also be kept by public aquaria.

Operationally, a public aquarium is similar in many ways to a zoo or museum. A good aquarium will have special exhibits to entice repeat visitors, in addition to its permanent collection. A few have their own version of a "petting zoo"; for instance, the Monterey Bay Aquarium has a shallow tank filled with common types of rays, and one can reach in to feel their leathery skins as they pass by.

Also as with zoos, aquaria usually have specialized research staff who study the habits and biology of their specimens. In recent years, the large aquaria have been attempting to acquire and raise various species of open-ocean fish, and even jellyfish (or sea-jellies, cnidaria), a difficult task since these creatures have never before encountered solid surfaces like the walls of a tank, and do not have the instincts to turn aside from the walls instead of running into them.

The first public aquarium opened in London's Regent's Park in 1853. P.T. Barnum quickly followed with the first American aquarium, opened on Broadway in New York. Following early examples of Detroit, New York and San Francisco, many major cities now have public aquaria. Most public aquaria are located close to the ocean, for a steady supply of natural seawater. An inland pioneer was Chicago's Shedd Aquarium that received seawater shipped by rail in special tank cars.

In January 1985 Kelly Tarlton began construction of the first aquarium to include a large transparent acrylic tunnel in Auckland, New Zealand, a task that took 10 months and cost NZ$3 million. The 110-meter tunnel was built from one-tonne slabs of German sheet plastic that were shaped locally in an oven. A moving walkway now transports visitors through, and groups of school children occasionally hold sleepovers there beneath the swimming sharks and rays.

Top public aquaria are often affiliated with important oceanographic research institutions or conduct their own research programs, and usually (though not always) specialize in species and ecosystems that can be found in local waters.

For a partial list of public aquaria worldwide, see list of aquaria.