Aquarium

The degradation of pollutants takes place by microorganisms according to the principle of nitrification . In a new filter, however, the microorganisms are not yet present in sufficient numbers on the filter substrate. Newly set up aquariums are therefore operated for several weeks without fish stocking so that these microorganisms can establish themselves. This process can be accelerated by using so-called filter starters. Activated carbon filters, on the other hand, remove pollutants from the water in a physical way ( adsorption ); their absorption capacity is limited, which is why the activated carbon has to be renewed regularly.

Filter materials: peat balls to lower the pH value of the water, clay tubes and so-called "bio balls" for biological filtering, with foam in the background

In a saltwater aquarium , filtering is achieved using a protein skimmer . This is possible because sea water has a different surface tension than fresh water . Dissolved organic compounds, mainly proteins, but also fats and oils , accumulate at the interface between air and water. The creation of fine bubbles creates a more or less fine foam that can be removed from the aquarium along with the dirt. This process can also be observed on the coast when the sea surf produces foam that collects in the form of flakes on the beach.

heater

When it comes to heating, rod heating with thermostat control is most common today. A floor heating is in either a heating pad placed on the bottom disk or housed a heating cable in the ground, is not necessary when setting up in heated rooms. One advantage of underfloor heating should be that the water circulates through the ground. A disadvantage, in addition to the higher purchase price, is that (unlike the rod heater) a simple exchange in the event of a defect is not possible. In the past, heating mats were often laid below the aquarium between the floor pane and the cabinet top. This type of floor heating has the advantage that there are no live parts inside the aquarium and the disadvantage that there is a great deal of heat loss because the heat from the heating mat first has to pass through the insulating floor pane. However, the risk of an electric shock is also averted with the internal heating mats or cables, as the common heating cable systems work with harmless low voltage.

Some external filters also have an integrated heater so that heated water flows into the basin; The result is better temperature control down to the last corner of the aquarium. Here, too, the disadvantage is that with such a combination device, the entire device has to be replaced if either the heater or the filter is defective. If the filter with integrated heating fails, the aquarium fish usually survive the deteriorating water quality for several days, but not necessarily the sudden drop in temperature.

For keeping animals from very cool waters, there are compact cooling devices that are integrated into the external filter circuit or have their own pump.

lighting

In addition, a strongly moving water surface increases the loss of light by around half in contrast to a largely calm water level, which only causes around 20% light loss.

Fluorescent tubes specially tailored to the aquarium hobby enable the simulation of different lighting conditions (e.g. natural daylight, tropical sun, lighting with an increased blue component to simulate sea water depth). The choice of the illumination spectral colors influences the growth of aquatic plants (desirable) and algae (mostly undesirable). Tubes with an increased proportion of red and blue are specifically used to increase the visibility of the red, orange and blue tones of fish and corals, but they also promote algae growth. Most often, full-spectrum lighting is used, which creates color relationships similar to sunlight.

The use of electronic lighting controls enables the time-controlled setting of different lighting moods (color, brightness) and the simulation of sunrises and sunsets. As a rule, however, it is sufficient to control the lighting using a simple timer. If fish are kept, only a day-night change is necessary. Aquatic plants require a lighting period of 8 to 12 hours, which can be interrupted by a break in lighting.

The aquarium lighting is often integrated into the aquarium cover. It must be able to withstand the prevailing damp room conditions and exclude the risk of electric shock when working on the aquarium. In order to avoid unnecessary and considerable energy losses through evaporation, an aquarium cover is generally used if the aquarium is not operated in the open (with the possibility of marsh plants growing out).

For aesthetic reasons, but also to observe the behavior of nocturnal animals, moonlight lights are also used, which simulate a faint bluish moonlight after the main lighting has been switched off. This effect lighting is realized with LEDs or cold cathode tubes of low power. The effect on the nocturnal behavior of the fish is controversial. On the one hand, absolute darkness is unnatural and can cause stress in the animals, on the other hand, too bright "moonlight" can prevent the animals from calming down. There are isolated reports of improved spawning behavior under moonlight lighting.

LED tubes can now replace T8 fluorescent tubes to some extent. In the case of T8 fluorescent tubes, replacing them with T5 LED tubes is only conditionally recommended, as the tube diameter is significantly smaller than that of T8 and there is not a lot of space available for heat sinks inside the LED tube, so that the overall output of the T5 tubes is high is limited. You also have to note that there are LED replacement tubes that continue to be operated with the transformer of the fluorescent lamp, where only the starter has to be replaced by a bridge. With these "retrofit tubes" you have to consider that the efficiency does not come close to the tubes that are operated directly with 230 V, so the cabling has to be changed on the socket beforehand, in which the old transformer is completely excluded from the electrical circuit . For this reason, fully wired LED light bars have become established, which no longer have much in common with the original light bar and fluorescent tube design, but can be easily integrated into covers without having to make electrical changes.

Although aquatic plants need the entire light spectrum for their photosynthesis , they mainly use the red (around 700 nm) and blue (around 450 nm) spectral range. White light-emitting diodes also emit in this spectral range.

More equipment

Tap water and aquarium water

In general, tap water can be changed so that any desired water value can be achieved. Very hard tap water can be brought to the desired lower degree of hardness through reverse osmosis or a mixed-bed filter. Brackish water or salt water conditions are achieved by adding special mixtures of salts.

Gravel

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Most aquariums have a substrate consisting of gravel or sand with no significant lime content. Quartz gravel or sand, which has no chemical influence on the water quality, is particularly suitable for aquariums. Calcareous rocks harden the water.

Gravel is most commonly used as a substrate. It is available in different grain sizes. Round cut stones are recommended so that fish with sensitive barbels cannot injure themselves. It is also advisable if the gravel height is lower at the front than at the back. Plant remains etc. slide forward. This is an advantage as you can easily remove the plant debris. The size of the gravel depends on the creatures to be cared for. In general, there is a risk that if the gravel size is too large, food residues will fall into the stone gaps, where the fish cannot reach them and rot in the gaps, which negatively affects the water values. Small gravel sizes with a diameter of around one millimeter are necessary for freshwater shrimp , for example . The animals are then able to turn the individual stones with their legs and search for algae growth. Aquarists who value good plant growth sometimes bring organic material (special aquarium potting soil, potting soil, garden soil or sheep droppings) below the gravel layer in order to provide the plants with sufficient nutrients. Other aquarists refrain from doing so, as ground-burrowing snails can dig up this potting soil. Instead, they put fertilizer balls or sticks in the gravel directly below or in the vicinity of the plants. The color of the gravel is in large part an aesthetic choice. However, fish that are kept in aquariums with very light gravel as the substrate appear paler. In the case of fish species that come from shady habitats, a substrate that is too light can trigger scrubbing behavior.

Decoration material in the aquarium

Aquariums are often decorated with stones, empty mussel shells and bog roots . The use of this decoration material not only serves the aesthetic satisfaction of the aquarium owner, but is also often necessary for the creatures cared for in the aquarium. For example, many cichlids are cave breeders and only lay their spawn on the top of a stone cave. Catfish grate the wood of the Moorkienwurzeln and shrimp of the genus Caridina prefer to look for small algae growth. Some species of fish, such as the Tanganyika snail bass , rely on their aquarium to offer them empty snail or mussel shells as a place of retreat. And finally, like aquatic plants, such decorative objects mark territorial boundaries for territorial species.

When choosing the decoration material, it is essential to ensure that it does not release any toxic substances into the aquarium water even after long periods of watering or that the water values ​​do not change the water values ​​for the species being kept. Unsuitable stones can e.g. B. release mineral salts, iron or lime.

Energy demand and energy saving

consumer

Energy is primarily used for heating, lighting and water treatment.

In the following energy consideration, a standard aquarium (200 liters) of 100 cm × 40 cm × 50 cm (L × W × H) with a cover should serve.

In total, this makes an annual consumption of 430 kWh, which is about a quarter of a single household (around 1800 kWh). As a rough estimate, one can assume about 2 kWh per year per liter.

Energy losses

Heat loss

At 47%, the heating of the aquarium is the most energy-consuming consumer. Two essential factors are decisive here:

• Heat loss through thermal conduction of the glass:

In this regard, the surface available for heat exchange, the temperature difference between the water and the surrounding room air and the heat transfer coefficient or U-value are important . The heat transfer takes place approximately on the cover and the side walls, the floor is usually already somewhat insulated and should be neglected in the consideration. A temperature difference of 5 K (25 ° C water temperature and 20 ° C room temperature) is assumed.

A high temperature difference as well as a large heat exchange surface ensure high energy losses.

• Heat loss through evaporation

Evaporation, also known as evaporation , permanently removes energy from the water, which, as with the heat transfer mentioned above, has to be replenished by heating. Now, by attaching an aquarium cover, the exchange of air and thus moisture can be reduced significantly. The air below the cover is saturated with water and cannot absorb any more moisture and thus suppresses evaporation. However, a cover will not and should not be airtight, which is why evaporation will still take place, but to a significantly limited extent.

The following example calculation makes this clear. Assuming natural convective air exchange without an aquarium cover, a water loss through evaporation of around 5-6 liters per day per square meter of water surface can be assumed. With a lid this is reduced to 1–2 liters per day. At a water temperature of 25 ° C, around 2441 kJ per kg of water are lost (corresponds to 0.684 kWh per day per liter of water).

Light output

Depending on the light source used, the energy efficiency is correspondingly good (see lighting ). In the case under consideration, light accounts for 38% of the energy. The use of LED lights would reduce the energy requirement to around 90% (approx. 20 watts) with the same light output. It must also be taken into account that there is no heat source due to the design.

Total energy losses

In practice, it depends very much on the size of the aquarium and the technology used. The main part of the energy losses is caused by the heat losses to be compensated and the lighting. In an aquarium with a volume of 500 liters (gross), energy consumption values ​​of approx. 2-3 kWh / day are measured.

Living things in the aquarium

Aquarium plants

Indian water lover

Krause water ear

Aquarium plants played no role in early aquaristics. The fishbowl , which is now rejected as cruelty to animals, was made without any vegetable contribution. In the 20th century, however, it became clear that a well-functioning aquarium also required a sufficiently large number of plants. Individual types of aquariums, for example some cichlid tanks or rock pools , are an exception. Plants that thrive optimally can improve the quality of the water in the aquarium by breaking down or absorbing pollutants such as too much phosphate , too much nitrate and too much ammonium . With the "harvesting" of aquarium plants, such pollutants as well as heavy metals and other toxins are removed from the aquarium. The aquarium plants produce the oxygen used by the living things in the aquarium for breathing by means of photosynthesis during the lighting phase of the aquarium. Plants also reduce unwanted algae growth in the aquarium by removing nutrients from the algae when they are growing well. Fish are mostly dependent on plants for their well-being. You need them as hiding places, as oxygen producers , as territorial boundaries within an aquarium and as a spawning area. In the natural aquariums , as propagated by the influential aquarist Takashi Amano , and in the Dutch plant aquariums , plants even play a leading role.

According to estimates by the aquarium plant expert Christel Kasselmann , between 100 and 150 plant species are offered as aquarium plants . Only 30 species are real aquatic plants.

Brazilian mill leaf

When designing the aquarium, a distinction is made between floating plants, foreground plants and solitary plants. Plants that can be used as floating plants in aquariums are those that basically float on the surface, as well as plants that are able to absorb the necessary nutrients through the water column and therefore do not have to be rooted in the soil. The number of aquarium plants that remain small enough to be used as foreground plants is not very large. In larger aquariums, plants with a height that would be annoying in the foreground in small aquariums can also be used for this purpose. Many aquarists plant a large plant as a visual highlight in their aquarium. Plants from the genus of sword plants are particularly often offered as solitary plants, the cultivars of which often have red-brown or conspicuously spotted leaves. Occasionally it is also recommended to plant solitary plants to the right or left of the center (see golden ratio ).

The typical Dutch plant aquaria plants roads are with plants such Bachburgel , Cardinal Flower and moss balls achieved. Owners of these aquariums often try to cultivate particularly demanding aquarium plants such as tongue leaf , cognac plant , water hair and milfoil . In the Japanese natural aquarium, small and dainty species that are planted in the foreground often play a role. These include the pond liver moss , the tongue leaf and the needle ledges . In these types of aquariums, plants such as Java fern are often tied to stones or roots. In aquariums with fish that eat tender plants, the dwarf pear leaf in particular has proven its worth, the hard leaves of which are rarely damaged by any fish species.

Carbon dioxide (CO ₂ ) , which plants need for their growth, is only dissolved to a small extent in water and comes from the bacterial decomposition of organic material such as dying plant parts or leftover fish food. The need for carbon dioxide differs depending on the type of plant. There are a number of aquarium plants, such as the dense leaved waterweed , the Indian water friend and the Indian water star , whose CO ₂ requirements can be ensured without additional supply. In addition to a whole range of aquarium plants that are also suitable for a newly set up aquarium, all three types of plants are often recommended. Because they grow well and are fast-growing, they effectively deprive the algae of their nutritional basis in the initial phase of an aquarium, when the risk of excessive algae growth is particularly high.

Many aquarium plants need a higher carbon dioxide content in the water in order to thrive. These plants are dependent on carbon dioxide fertilization , which should achieve a CO ₂ content of at least 20 mg / l. There are a number of different ways of achieving this fertilization. This ranges from a fermentation system based on alcoholic fermentation (yeast fermentation) to chemicals that release carbon dioxide in the aquarium water and a (possibly computer-controlled ) pressurized gas cylinder system.

Strong surface movement of the water and the use of air stones (air stones) drive out the carbon dioxide dissolved in the water to a large extent. Believing that they can bring more oxygen into the water for the fish, the opposite is achieved through membrane pumps and splashing filter inlets: The carbon dioxide dissolved in the water is increasingly released into the air via the water surface and deprived of the aquatic plants as a basis for life, which then grows less react, generate less oxygen and leave more nutrients to the algae. Therefore, contrary to popular opinion of beginners, aquarium water rich in carbon dioxide is not poorer in oxygen, but richer in oxygen.

When equipping the aquarium, it must be taken into account that there are aquarium plants with higher maintenance requirements, some of them problematic plants, which have higher requirements for keeping them (for example, plants that need a lot of light, extreme requirements for water hardness, high requirements for the concentration of water constituents, special Temperature conditions) and those with low maintenance requirements, which thrive without additional carbon dioxide fertilization and are particularly suitable for the initial planting of an aquarium.

Almost all of the aquarium plants available in stores come from nurseries that specialize in the breeding of aquarium plants. Especially from the genus of sword plants , new varieties are used again and again, which are characterized above all by interesting red to reddish-brown speckled leaf colors.

Aquarium plants can also multiply in the aquarium (for example through runners on which offshoots arise, or through self- branching of the shoot axes ) or be reproduced (for example through rhizome division or by using young plants sprouted from shortened stem plants; propagation via flowers and seed attachments is only possible with Water lily plants ).

Excess plant growth can be responded to by plucking leaves or shortening stems.

fishes

The discus is considered by many aquarists still considered the "king of fish"

Blue Congo tetra are usually kept in a tropical community tank

Siamese fighting fish , male - they were first bred in Europe in France in 1893

The first fish species kept in European aquariums mostly came from local coastal and inland waters . The goldfish is one of the few foreign aquarium fish that was mentioned very early in the aquarium literature . One of the first strikingly colored tropical fish to be imported regularly and in a targeted manner was the paradise fish . It is documented that it was first held in Germany in 1876. This species was one of the few fish that could survive the long journey from Asia. Paradise fish are not only dependent on gill breathing , but as labyrinth fish are also able to breathe atmospheric oxygen via their so-called labyrinth organ .

Due to the demand in Europe, other types of fish followed very quickly, imported from regions such as Manaus in Brazil , Bangkok in Thailand or Jakarta . Most of them were labyrinth fish like the paradise fish. Due to the lengthy transport, however, initially only those fish species prevailed in the aquarium hobby that could be bred. The majority of the fish commercially available today come from bred fish. However, wild- caught fish are still offered on a regular basis, as some fish species can still not be bred in captivity or their catch is more economical than breeding. New species have also been introduced into the aquarium hobby through wild catches. This applies in particular to armored catfish , cichlids and tetras .

Like many other hobbies, dealing with the keeping of living things in aquariums is subject to trends and fashions. In freshwater aquaristics, many aquarists still consider the discus the “king of fish”. The keeping of angelfish and the so-called mbunas is also very popular . Many aquarists also keep catfish , with a strong demand especially for species that have an unusual body shape, such as the large-head frying pan catfish or the blue antenna catfish . In the case of some newly introduced catfish species such as the very strikingly colored zebra fish, this demand is also expressed in a high price compared to other fish species.

According to their diet, fish can be divided into piscivorous piscivores , insectivorous insectivores , herbivorous herbivores and plankton eaters . Usually the position of the fish's mouth suggests which food niche each species uses. Fish with an upper mouth are usually fish that eat on the surface of the water. A lower mouth can usually be found in bottom fish that look for food in sludge or on stony ground or peel off algae growth .

The animal feed industry now offers a wide range of ornamental fish feed for feeding the fish . Dry food , which is offered in flake, granulate or as food tablets, is available in different compositions to meet the different nutritional requirements of the individual fish species. However, not all fish species accept dry food. Water fleas , mosquito larvae , river flea shrimp and other small aquatic animals are primarily used to feed primarily predatory fish species. These feed animals are offered live, dried, freeze-dried or frozen (" frozen food "). Types such as B. Archer fish are absolutely dependent on live food . Live food such as grindal worms and brine shrimp can be grown yourself. However, the trade offers a range of feed animals.

Invertebrates and amphibians

Apple snail , which with its Sipho takes a breath

In recent years in particular, the targeted keeping of invertebrates has increased in freshwater aquariums . It has been practiced for a long time in saltwater aquariums.

Tower snails and ramshorn snails have been found in aquariums for a long time. The burrowing tower snails in particular aerate the soil and utilize organic plant matter. Although they ensure healthy plant growth in this way, they have always been more of a "support" in the aquarium hobby. The trade is also offering more and more strikingly colored or shaped snails such as the different species of apple snails or the zebra snail . Because of their high metabolism, they must be included in the maximum number of animals that can be kept in the aquarium. The minimum edge length for an apple snail is 60 cm.

For some years now, freshwater and rock shrimp have been kept in freshwater aquariums. Their popularity is mainly due to the Japanese photographer and aquarist Takashi Amano , who used Yamatonuma shrimp in his aquariums to control algae. This has led to the increased introduction of other types of shrimp .

Some types of cancer are also commercially available. In freshwater aquariums, it is mainly the crayfish species that belong to the fauna of Australia or North America. These crabs, similar in habit to a lobster, are mainly bred on farms for food. Blue-colored specimens such as the yabbi , the marron and the red claw lobster are particularly popular in pet shops . All three species require very large aquariums, can only be kept with large fish and also attack the aquarium plants. That is why the tiny orange pygmy crayfish is also popular . Crabs, on the other hand, are rarely kept in pure aquariums; With a few exceptions, they always need a sufficiently large area of ​​land for their well-being and are therefore kept in aquaterrariums .

Amphibians are rare pets in the aquarium . The species that are more frequently kept in the aquarium include clawed frogs , dwarf clawed frogs , the Japanese fire-bellied newt , the axolotl and the swimming burrows .

Unwanted organisms in the aquarium

Seaweed

Guppy  - they are among the fish that eat algae growth

Shell flowers remove nutrients from the water and thereby reduce algae growth

The Yamatonuma shrimp is also used to combat algae in the aquarium

Algae spores are only a few micrometers in size. They are brought in when fish and plants are moved and put in, and when the water is changed. If they multiply explosively, this is an indication that the nitrogen conversion in the aquarium is not working sufficiently well.

The so-called beard and brush algae belong to the red algae . They are a dirty green to blackish color. The red color, which gives it its name, is visible when the algae threads are placed in alcohol. Red algae are eaten by a number of fish species. Diatoms occur, among other things, when an aquarium is only inadequately lit and the oxygen content is too low due to the then low assimilation performance of the aquarium plants. These algae, which form a smeary, brownish coating on stones and roots, disappear when the lighting conditions in the aquarium are improved. Green algae , on the other hand, have similarly high demands on the water as aquarium plants. They are green to light green in color and, depending on the type, grow like cotton wool, thread-like or tuft-like and can be easily removed by hand or tweezers.

Particularly in the initial phase of an aquarium, so-called blue - green algae (cyanobacteria) can multiply strongly, which usually form a blue-green, occasionally blackish-purple or brownish coating over plants and stones. Blue-green algae grow very quickly and can suffocate plants that have not yet grown well. Mechanical removal makes sense, but even the smallest residues can grow back in large quantities.

Measures against algae

An excessive growth of algae in the running-in phase of an aquarium can be prevented by waiting several weeks before the aquarium is filled with fish and invertebrates for the first time. During this time, the aquarium is illuminated for about ten hours a day, and the filter is already running continuously. At the same time, the aquarium is planted very densely with fast-growing plants. The plants deprive the algae of the nutrients necessary for their explosive growth, and during this time the microorganisms that are necessary for the conversion of ammonium , phosphate and nitrite can settle in the filter . New filters can be inoculated with special bacterial cultures from specialist dealers in order to stimulate biological activity. When the filters are run in, all filter media should never be changed / cleaned at the same time, so that the colonized bacterial cultures are not completely destroyed. If you already have an aquarium, you can replace some of the fresh water in the new aquarium with aquarium water and put some filter sludge from the inserted filter into the filter of the new tank. This helps in the running-in phase to form a new equilibrium more quickly. Beginners in particular confuse well-meaning “sterility” with biological cleanliness, which is produced less by mechanical filtering and “fresh” water than by active microorganisms in the substrate and the coarse-pored filter media.

The majority of aquarium plants are marsh plants that are grown emersed in water nurseries . You therefore need a few days to adapt to the aquarium environment. The recommended plants, which grow very quickly even with previous emersed cultivation, include Indian water friend and water star . Dense leaved waterweed is also very suitable; it is cultivated submerged, but requires strong lighting. It can grow both flood and rooted; The native horn leaves are almost always flooding and also contribute to a reduction in nutrients in the aquarium. The same applies to floating plants such as mussel flowers and duckweed .

A number of fish species eat algae. The Siamese trunk barbel and the beautiful-finned trunk barbel are excellent algae eaters . Also otocinclus and ancistrus be maintained, among other things because of this characteristic in the aquarium. Often held by beginners guppies and Spitzmaulkärpflinge to the cultivar Black Molly heard are, eat fish which caused algae nursery. An existing algae plague can hardly be combated by algae-eating fish, as these animals mainly graze on young, tender algae. Despite their reputation for destroying algae, snails are not very suitable, as they can develop into a plague through proliferation and contribute to fertilization themselves through their metabolic products. In addition, it is freshwater shrimp that effectively counteracts the growth of algae. The trade also offers chemical agents against algae growth. However, these agents also damage the plants, even if, with a delay of weeks or even months, since plants have a smaller effective surface area than algae.

Filamentous green algae (thread algae), which often appear in the running-in phase of an aquarium, can be collected daily and then usually disappear again.

UV lamps can be installed in the water circuit of an external filter against floating algae.

If the aquarium is infested with cyanobacteria, switching off the light and darkening for eight days after a water change of around 50% can help.

Snails and planarians

Although snails have an important function in the aquarium, some species can reproduce very quickly and get out of hand in the aquarium. They often become a nuisance when the fish are fed too abundantly, so that the snails find a very large food supply. They can be removed using special snail traps. Some fish species also eat young snails, although it must be noted that the snail-eating fish, which are often recommended, have special requirements that cannot be achieved in many aquariums (e.g. loach can be up to 30 cm long and require several conspecifics and require an aquarium with a minimum edge length of 150 cm).

Planariums also occasionally appear in aquariums. These are worms up to several millimeters in size that crawl around on panes and furnishings. While they are not dangerous to adult fish, they can eat the fish spawn. Planarians multiply particularly when there is plenty of leftover food and organic waste in the aquarium. Chemical agents that treat planarians also make snails and possibly plants die. It can be helpful if the aquarium has a water temperature of at least 35 degrees Celsius for several days. During this time, the fish and “desired” invertebrates must be kept in a replacement aquarium.

Chemistry in the aquarium

PH value

The scalar needs a pH value between 5.5 and 6.5 for its well-being.

The pH value is an important "water value" in aquaristics. It expresses the relationship between the acidic and alkaline components of the water; more precisely, the ratio of hydrogen ions and hydroxide ions. If there is an excess of hydrogen ions, one speaks of an acid, if the hydroxide ions predominate, one speaks of a base. Living organisms have a differently large tolerance range for the pH value and cannot survive outside of this in the long term. Checking whether an animal species finds suitable conditions for survival in an aquarium is based, among other things, on the pH value.

The pH is measured on a logarithmic scale with values ​​between 1 and 14. Water values ​​in the aquarium are between 4.5 and 9.5, both of which represent extreme values. A pH of seven is considered to be “neutral”; H. neither as alkaline (basic, pH value> 7) nor as acidic (pH value <7). Logarithmic means that water with a pH value of six already contains 10 times more acids than water with a pH value of 7. Water with a pH value of five already contains 100 times more acids than water with a value of 7. So-called black water aquariums , in which South American fish such as angelfish or the frequently kept red neon thrive, have pH values ​​in the range of 5.5 to 6.5.

Most aquatic plants thrive best in water with a pH value between 6.2 and 7.2, as these values ​​usually also have a higher carbonic acid content, which is important for plant growth . East African cichlids in particular feel good in water with a pH value above 7 .

There are various ways to measure the pH value:

1. pH test strips or indicator paper: the solution to be measured is dripped onto such a test strip or indicator paper or the test strip is immersed in the water to be examined. The discoloration is compared with a table to determine the pH. This is an easy and quick way to measure pH, but it is relatively imprecise.

2. pH drop test: In this measuring method, drops of a reagent containing an indicator are added to a certain amount of a solution to be measured, and the discoloration is also compared with a table. This measuring method takes a little more time and is usually a little more expensive, but also much more accurate than measuring with indicator paper.

3. Electronic measuring device: Here an electrode is dipped into the solution to be measured and an electronic display device determines a pH value from various factors. The advantage of this measurement method is that the solution can also be discolored or otherwise contaminated.

Carbonate and total hardness (acid capacity and hardness)

The carbonate hardness (KH) describes the amount of carbonate and hydrogen carbonate ions. So that these anions can function as carbonate hardness builders, a corresponding number of calcium and magnesium cations must be present. The carbonate hardness represents an acid buffer in water, which prevents a strong and rapid change in the pH value. The carbonate hardness is therefore referred to as the acid capacity (acid binding capacity up to pH 4.3). Water with a low KH value generally has a low pH, while water with a high KH value is usually alkaline.

The total hardness (GH), also called hardness , denotes the sum of all ions of the alkaline earth metals dissolved in the water . In addition to magnesium and calcium (approx. 80%), these include strontium and barium . In the aquarium hobby, the total hardness usually plays a smaller role than the carbonate hardness. Usually the carbonate hardness is lower than the total hardness.

Instead of the newer terms acid capacity and hardness, the established terms carbonate hardness and total hardness are mostly used in aquaristics. It should be noted that an acid capacity of 1 mmol / l corresponds to a carbonate hardness of 2.8 ° dH and a hardness of 1 mmol / l corresponds to a total hardness of 5.6 ° dH.

Conductance

The conductivity (wrongly for the electrical conductivity measured at 25 ° C in µS / cm) depends on the sum of all dissolved salts in the water. The more salts are dissolved in the water, the better the conductivity. Fully demineralized water hardly conducts any electricity (low conductivity is always given due to self-dissociation ).

The conductance plays a role in particular when soft water fish are to be bred.

Salinity and redox potential

A determination of the salinity and the redox potential is only required for brackish water and sea ​​water aquariums .

The density of the salt content is measured with a hydrometer . Fresh water has a specific gravity of 1.0 at a temperature of 4 degrees Celsius. Tropical sea water, i.e. sea water that is normally reproduced in a sea water aquarium, has a specific gravity between 1.020 and 1.027 at this temperature because of the dissolved salts and trace elements. Brackish water lies between these two values. The hydrometers used in the aquarium hobby are calibrated to 24 degrees Celsius.

The redox potential says how much the water is contaminated with organic substances and what oxygen content it has. High values ​​indicate a high oxygen content and a low content of organic substances. The redox potential is measured with electronic measuring devices. When determining the values, the pH value and the water temperature must also be taken into account.

Nitrogen conversion in the aquarium

Nitrogen cycle in the aquarium

Plants need nitrogen as a nutrient. The aquarium plants have ammonium (NH ₄ ) and nitrate (NO ₃ ) available as nitrogen sources. Other nitrogen compounds in the aquarium water are urea as well as nitrite and ammonia, which are toxic for fish . Nitrite and ammonia can be converted into non-toxic nitrate by bacteria , which is referred to as nitrogen conversion or nitrification .

This nitrogen conversion, which takes place in the aquarium (and in the aquarium filter) by plants and microorganisms, is also known as the nitrogen cycle. In very few aquariums, however, there is actually a cycle in which interventions are no longer necessary. The living things in the aquarium are usually dependent on food. Regular partial water changes are used to reduce nitrate .

The toxic ammonia is initially released through the gills and from the urine of the creatures cared for in the aquarium as well as the unused food . In water that is not too alkaline, this nitrogen compound is mainly present as ammonium . This is less harmful to the fish and invertebrates in the aquarium. For plants it is even a fertilizer. Ammonia predominates only at high pH values ​​and temperatures. Ammonia is a strong poison for fish. If ammonia is highly concentrated in the water, they are no longer able to breathe ammonia through the gills.

The ammonium that is not consumed by the plants as a nutrient is used by microorganisms such as B. Nitrosomonas bacteria, which are present in both the aquarium and the filter, are broken down into nitrite . Like ammonia, nitrite is poisonous for fish and fatal from values ​​of 1 milligram per liter. Sudden shooting of the fish in the aquarium, apathetic behavior or hectic breathing indicate possible poisoning by nitrite. Nitrite is, however, by z. B. Nitrobacter bacteria are converted to nitrate in the next stage. This process, in which ammonium is converted into nitrate with consumption of oxygen, is known as nitrification . Nitrate is not toxic to fish, but in high concentrations it can damage the aquarium plants. It should be kept low in order to avoid (partial) denitrification (see below) in the aquarium or the body of the fish, which would ultimately release nitrite again. Nitrate is therefore removed from the aquarium water by regular partial water changes. In addition to nitrification, there is another process in which microorganisms inhale nitrate as a substitute for oxygen. This anaerobic process is known as denitrification . It rarely occurs in most aquariums. For the removal of nitrate z. B. a special nitrate filter can be used.

If the nitrate content of the water is too low (below about 0.5 mg / l), plants can be damaged - just as if the content is too high. A nitrate deficiency can cause symptoms similar to an iron deficiency in aquarium plants.

Other chemical substances relevant for the aquarium

The presence of macro and micronutrients is essential for aquatic plants .

Macronutrients:

• Carbon: Plant building material, absorbed from carbon dioxide. Some aquarium plants, especially sword plants, can (if there is too little carbon dioxide in the water) obtain carbon from hydrogen carbonate ions. During this process, called biogenic decalcification , crust-like deposits of lime, which is a “waste material”, are deposited on the photosynthetically active leaves.
• Phosphate : Plant nutrient whose concentration in the water (for planted aquariums about 0.2 to 0.7 mg / l) by adding more fish food or sodium hydrogen phosphate ( Na ₂ HPO ₄ or NaH ₂ PO ₄ ) and also potassium dihydrogen phosphate (KH ₂ PO ₄ ) can be increased.
• Potassium : from 0.5 to 30 mg / l

Micronutrients:

• Iron : Aquarium plants can develop chlorosis (yellowish-white discoloration of young leaves) due to impaired chlorophyll formation with a lack of iron (less than 0.1 to 0.3 mg / l) as well as with a lack of nitrates. When fertilizing with iron supplements, a distinction must be made between chelated and non-chelated iron (e.g. in the form of iron citrate ) , particularly with regard to the dosage .
• Copper ; both trace elements and (from 0.5, sometimes from 0.1 mg / l in aquarium water) plant toxins
• Zinc : Plant nutrient that is contained in trace element fertilizers and should be present in the aquarium water in a concentration between 0.002 and 0.02 mg / l. From 0.05 mg / l, phytotoxic damage patterns similar to those caused by too much copper appear in many plants.

• Other trace elements: magnesium and manganese .

Economy, science, nature and animal protection

Origin of the organisms kept in the aquarium

Most of the freshwater fish regularly offered in pet shops come from offspring. It is estimated that there are 300 million ornamental fish that are raised for the aquarium trade every year.

The fish are mainly bred in Southeast Asia. Breeding stations are mainly in the area around Hong Kong , Singapore and Bangkok and to a lesser extent in Sri Lanka , Japan and Taiwan . There are also large ornamental fish farms in North and South America , in some South African countries as well as Israel and the Czech Republic . Breeding systems for seawater fish have been built especially since the mid-1990s.

For transport by air to the importing countries, the fish are usually packed in bags, one third of which is filled with water and two thirds with air or oxygen. Air is used in species like labyrinth fish and armored catfish because they also breathe atmospheric air. Pure oxygen would be deadly to them. Occasionally, an anesthetic is added to the water so that the metabolism of the fish is not too high and the water is not too polluted. Ornamental fish exporters also fast their fish for a few days before they are transported in order to keep water pollution low. The bags are then packed in polystyrene boxes and flown to their destinations. One of the large cargo airports where many ornamental fish arrive is Frankfurt Airport . Importers are usually wholesalers who initially keep the fish in quarantine tanks and usually only sell them after seven to 14 days.

Piranha caught in the wild

Furthermore, fish, plants and invertebrates are still being taken from the wild around the world for animal and plant export. Especially in countries with a low per capita income, this can represent a significant source of income for parts of the population in rural regions. Above all, fish that are not or only very difficult to breed are regularly imported. In addition, there is great demand for new aquarium items. The number of wild catches is estimated at 30 million per year.

The negative effects of collecting fish and plants are repeatedly and critically discussed. Criticisms cited include that when reef fish are caught in the wild, coral reefs are destroyed, many other animal species are removed as bycatch and species stocks are so heavily plundered that populations in the original range collapse. Group expeditions are lengthy, costly, and not always successful. The transport to the export centers can be very stressful for the animals. Many aquarists therefore only keep fish from offspring. Among US aquarists who specialized in saltwater aquariums, two-thirds of those questioned in a 1997 survey said that they would rather buy fish from offspring than wild-caught fish. 80 percent of those surveyed also stated that only those fish should be placed on the market that either ensure the continued existence of the species on site through catch quotas or that come directly from bred fish.

Animal welfare aspects

When operating the aquarium hobby (whether professionally such as in zoos, breeding establishments or in science or amateurish as a leisure activity), it must be noted that fish are living beings to whose keeping animal welfare law applies.

Keeping fish species in the aquarium as appropriate to the species as possible requires, like any keeping of living things, sufficient knowledge. Many aquarists invest a lot of time and money to provide good conditions for their fish or invertebrates. A number of aquarists also deliberately keep only those animals that can be bred and sometimes make great efforts to breed rarer fish species.

If insufficient knowledge is available, conditions can very quickly arise in an aquarium that can be viewed as cruelty to animals . Typical holding errors are:

• too many fish and invertebrates. There are different rules of thumb for calculating the maximum stock size in the aquarium. As a guide, two liters of water are required in the aquarium for every centimeter of fish. (refers to the length of the adult animals)
• the socialization of animal species that are incompatible with one another,
• keeping animal species at water values ​​that are outside the spectrum where they are comfortable. Overfeeding can also contribute to the fact that water values ​​in the aquarium deteriorate and exceed a level that the fish can tolerate. Partial water changes that have not been carried out also usually lead to poor water values ​​(see backwater aquariums, however ).
• the individual keeping of schooling fish
• Keeping fish and invertebrates with territorial behavior in groups in tanks that are not large enough so that the animals behave very aggressively towards one another.
• keeping fish in tanks that are not the size of the fish.

The silverfin leaf is often offered as a freshwater fish, but needs brackish water for its well-being

In the best case scenario, the fish react to these holding errors with delayed growth and reduced color. The fish perish more frequently, however, and death can take several months.

The quality of advice in specialist pet shops is highly dependent on the individual and ranges from a high level of professional competence to pure sales behavior. For some species, cultivated forms are offered which, from the point of view of a very large number of aquarists, represent excruciating breeding . These are, for example, goldfish with telescopically enlarged eyes or fins that are so enlarged that the animals can no longer behave appropriately. Species are also regularly offered that have very special holding requirements that very few aquarists can meet. For example, the silver fin leaf is regularly offered as freshwater fish, even though the fish needs a 1,400 liter aquarium with brackish water conditions when fully grown.

Breeding and maintenance breeding

The reproduction of their fish is of great interest to many aquarists. A spawning grid is used for fish that are not viviparous, especially open and ground spawners in the aquarium .

A number of fish species, invertebrates and aquatic plants are threatened with extinction or are considered to be extinct in the wild. Some tropical organisms have only very small areas of distribution. The South American Villavicencio dwarf cichlid has only been found in a few bodies of water near the Colombian city ​​of Villavicencio at the foot of the Andes and is threatened by biotope destruction . Endler's Guppy from the family of livebearing carp comes from a single freshwater lagoon in the northeast of Venezuela . It is considered extinct in the wild; as an aquarium fish, however, it is bred by both private individuals and public zoos such as the Cologne Zoo . This also applies to a number of other species. In its April / May 2006 issue, for example, the specialist journal Aquarium Live published a call from Peter Finke to participate in the conservation breeding of the Parosphromenus genus . These fish are among the most endangered labyrinth fish as their habitat is threatened by forest deforestation. The fish that live in the very acidic, almost mineral-free jungle streams of Southeast Asia are, however, very demanding in their keeping and are extremely rarely offered in specialist pet shops. However, there is a working group that has set itself the goal of stopping the extinction of this species of fish, at least in aquariums.

However, maintenance breeding is not easy to do. Fish bred in captivity can very quickly differ significantly in body shape and color from their fellow species living in the wild.

Science and aquaristics

Organisms kept in aquariums have repeatedly played a role in the natural sciences . This applies from Priestley's oxygen research using aquatic plants in the 18th century, to Konrad Lorenz's observations on territorial behavior using the example of sticklebacks in the early 20th century, to studies on the effects of pollutants dissolved in water today. The aquarium hobby also leads to the introduction of animal and plant species that have not yet been scientifically described. For some fish families in which the number of newly discovered species exceeds the speed with which they are classified, aquarists make do with code systems. For example, armor catfish that have not yet been classified are designated with L numbers . The repercussions of the commercial interest associated with the aquarium hobby on research can also be seen in an entirely different family: A few years ago, scientific research on freshwater shrimp was still focused on rock shrimp bred for human consumption in shrimp farms . Only since there has been a demand for species that can be kept in aquariums has research here expanded to include numerous other shrimp species.

Aquaristics as an economic factor

According to the Central Association of German Zoological Companies, 4 percent of German households had 1.9 million aquariums in 2019. The turnover for ornamental fish was 182 million euros , that of ornamental fish feed was 53 million euros.

Public show aquariums

Many zoos also have aquariums on their premises, such as the aquarium in the Berlin Zoological Garden , which has one of the oldest aquariums in Germany. The Aquazoo Düsseldorf , which is also a natural history museum, endeavors in its exhibition to make the adaptation of animals to their habitat clear. The collection is structured according to pedagogical aspects.

The numerous public show aquariums also include the German Marine Museum in Stralsund , the Ozeaneum Stralsund and the sea water aquarium in Wilhelmshaven . Further examples are the Oceanário de Lisboa in Lisbon , which was built on the occasion of the 1998 World Exhibition and is considered the second largest saltwater aquarium in the world, or the Oceanium , which opened in 2001 in the Rotterdam Zoo, Diergaarde Blijdorp .

On March 29, 2014 the largest aquarium in the world with a total volume of 48,750 m³, the Chimelong Ocean Kingdom , was opened. It is located on the Chinese island of Hengqin immediately west of Macau and 70 km southwest of Hong Kong in Guangdong Province . It contains 19 pools, was built at a cost of 1.5 billion euros and sets 5 world records: Largest acrylic glass pane (W × H 39.6 m × 8.3 m) as the largest aquarium pane, largest aquarium underwater dome, largest single tank.

The world's largest aquarium as of 2008, the Georgia Aquarium , is located in Atlanta , USA. The basins hold more than 30 million liters of water. Over 500 different species, a total of around 120,000 sea creatures, find space in this artificial reef. The main attraction are two whale sharks . These aquariums are often criticized for keeping such marine animals. The American Sea World chain with its dolphin and orca shows is particularly often criticized because it is doubted that such large marine animals can be kept in a species-appropriate manner. The also commercial British chain Sea Life Center pursued a different concept, at least in Germany, and worked with Greenpeace until 2006 . Greenpeace used the space for its own exhibitions. The Sea Life Center did not show any deep sea sharks, tropical fish species or threatened species. However, this obligation also prevented the Sea Life Centers from participating in conservation breeding.

Show aquariums on a smaller scale are also operated by some aquarium associations, which in Germany are predominantly part of the Association of German Associations for Aquarium and Terrarium Studies e. V. are organized. Other European associations have mostly come together in the European Aquarium and Terrarium Association.

literature

History of the aquarium

• Bernd Brunner: How the sea came home - the invention of the aquarium. Transit Verlag, Berlin 2003. (Revised and expanded edition Verlag Klaus Wagenbach. Berlin 2011.)

Bernd Brunner: The Ocean at Home - An Illustrated History of the Aquarium. Princeton Architectural Press, New York 2005. (Revised and expanded edition of Reaction Books. London 2011.)

• Jörg Scheller : "Appetite for the Magnificent. An essayistic dive into the shallows of the aquarium using the example of Philip Henry Gosses". In: ders., David & Tania Willen, Appetite for the Magnificent. From aquariums . Edition Patrick Frey, Zurich 2017. (English edition: Appetite for the Magnificent. On Aquaria , Edition Patrick Frey, Zurich 2017; republication of the German text online on pop-zeitschrift.de, December 3, 2018).
• Mareike Vennen: The Aquarium: Practices, Techniques and Media of Knowledge Production (1840–1910) , Wallstein 2018 (received the Opus Primum sponsorship award )

Set up aquariums

• Takashi Amano : The great book of natural aquariums. bede Verlag, Ruhmannsfelden 1998, ISBN 3-931792-80-3 .
• Kaspar Horst and Horst E. Kipper : The optimal aquarium - guidelines for setting up and maintaining a freshwater aquarium. Ad aquadocumenta Verlag, Bielefeld 1992, ISBN 3-925916-15-6 .
• Christel Kasselmann : Designing planted aquariums . Franckh-Kosmos Verlag, Stuttgart 2001, ISBN 3-440-08518-X .
• Petra Kölle: 300 questions about the aquarium. Gräfe and Unzer, Munich 2005, ISBN 3-7742-7369-3 .
• Gina Sandford: Aquarium - Freshwater and Saltwater Aquarium Manual. Dorling Kindersley , Stamberg 2004, ISBN 3-8310-0553-2 .
• Claus Schäfer: Basic aquarium course. Eugen Ulmer, Stuttgart 1998, ISBN 3-8001-7378-6 .
• Rüdiger Latka, The reef aquarium practice for newcomers. Rüdiger Latka Verlag, 2005, ISBN 3-9810570-0-7 .

Living things in the aquarium

• Hans A. Baensch , Rüdiger Riehl : Aquarium atlas. Volume 1-6. Mergus, Melle 1982-2004; New edition in 2006, ISBN 3-88244-177-1 .
• Hans Gonella: Crabs, crabs and prawns in the freshwater aquarium. bede-Verlag, Ruhmannsfelden 1999, ISBN 3-931792-87-0 .
• Bernd Greger: Plants in the freshwater aquarium. Birgit Schmettkamp, ​​Bornheim 1998, ISBN 3-928819-16-X .
• Kaspar Horst: Plants in the aquarium. Ulmer, Stuttgart 1986, ISBN 3-8001-7159-7 .
• Christel Kasselmann: aquarium plants. 2nd Edition. Ulmer, Stuttgart 1999, ISBN 3-8001-7454-5 .
• Hans-Georg Kramer: Plant aquaristics á la Kramer. Tetra-Verlag, Berlin-Velten 2009, ISBN 978-3-89745-190-2 .
• Ulrich Schliewen: Aquarium fish from A to Z. Gräfe and Unzer, Munich 2006, ISBN 3-7742-5694-2 .
• Diana Walstad: The planted aquarium. A handbook for practical use on a scientific basis. 3. Edition. Tetra-Verlag, Berlin-Velten 2013. ISBN 978-3-89745-199-5 .
• Uwe Werner: Unusual aquarium keepers. Landbuch, Hannover 1993, ISBN 3-7842-0495-3 .

Lexicons

• Hans Frey: The aquarium from A to Z. 1st edition. 1957. (14th edition. Melsungen / Basel / Vienna 1976, ISBN 3-7888-0013-5 )
• Claus Schaefer, Torsten Schröer (ed.): The large lexicon of aquaristics. Eugen Ulmer, Stuttgart 2004, ISBN 3-8001-7497-9 .
• Daniel Knop: Lexicon of marine aquaristics . Natur und Tier-Verlag, Münster 2013, ISBN 978-3-86659-213-1

Trade journals

• DATZ - the aquarium magazine . Nature and animals, Münster. ISSN  0723-4066 (electrical resource 2003 ff.)
• Amazonas - freshwater aquarium specialist magazine. Nature and animals, Münster 1.2005.1ff. ISSN  1861-2202
• Aquaristic trade magazine . Tetra, Berlin. ISSN  1437-4854
• Aquaristics - Current Freshwater Practice . Dähne, Ettlingen. ISSN  0947-6512
• VDA-aktuell - Association magazine of the VDA . VDA, Sparneck, ISSN  1863-4648
• Aqua Terra Austria - magazine of the Austrian Association for Vivaristics and Ecology

Web links

Wiktionary: Aquarium  - explanations of meanings, word origins, synonyms, translations

Commons : Aquarium  - album with pictures, videos and audio files

Wikisource: Aquarium  - Sources and full texts

• - Aquarium-Magazin (OAM) - free PDF aquarium magazine
• Detailed explanations for measuring the water values. In: scienceblogs.de
• https://vda-online.de/ - Association of German Associations for Aquarium and Terrarium Studies e. V.
• http://www.aqua4you.de - Aquaristik-Online-Magazin - Introduction to the topic, including a fish database
• https://www.drta-archiv.de - Archive of important topics of the German aquarium newsgroup
• Seawater Lexicon - the lexicon about seawater animals
• Aquarium plants database at www.flowgrow.de
• https://pop-zeitschrift.de/2018/12/03/appetite-for-the-magnificenteine-essayistische-tauchfahrt-in-die-untiefen-des-aquariums-am-beispiel-philip-henry-gossesvon-joerg- scheller / essay on the beginnings of aquaristics around 1850

Individual evidence

1. ^ Karl Ernst Georges : Comprehensive Latin-German concise dictionary. 8th, improved and increased edition, Hahnsche Buchhandlung, Hanover 1913–1918. 1918, Retrieved November 6, 2017 . 
2. ↑ ^{a b} Elena Nikulina, Ulrich Schmölcke: Fish farming in ancient Rome and its change in reputation in the light of the political situation . In: Writings of the natural science association for Schleswig-Holstein . tape 70 , December 2008, p. 36–55 ( uni-kiel.de [PDF; 1000 kB ; accessed on November 10, 2010]). 
3. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 72 f.
4. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 100-105.
5. ^ Hanns-Jürgen Krause: Aquarientechnik, Handbuch. 4th edition. Verlag Bede, 1999, ISBN 3-927997-10-2 .
6. ↑ Martin Sander: Aquarium technology in fresh and sea water . Verlag Eugen Ulmer, 1998, ISBN 3-8001-7341-7 .
7. ↑ Claus Schaefer, Andreas Raschke: Pocket atlas aquarium technology. Technology, furnishings, care . Verlag Eugen Ulmer, 2005, ISBN 3-8001-4675-4 .
8. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 72 f.
9. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 73 f.
10. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 75-77.
11. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 14.
12. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 14.
13. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 61 and 75 f.
14. ↑ foreground plants (selected): needle ledges , dwarf leaf peer , dwarf sword plant , Bolivian sword plant , horizontal sword plant .
15. ↑ Solitary plants (selection): Bleher's sword plant , Heart-leaved sword plant , Grisebach's sword plant , Horizontal sword plant , Wavy-leaved sword plant , Osiris sword plant , Rispige sword plant .
16. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 66.
17. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 66-68.
18. ↑ Aquarium plants with higher maintenance requirements (selection): American pennywort , needle ledges , some water ears , water goblets of the Cryptocoryne cordata group, the sword plant Echinodorus gabrielii Rataj , the pipe root plant Tonina fluviatilis Aubl. , some Nesaea species ( loosestrife with low nitrate tolerance), especially Nesaea pedicellata , the rush Juncus repens Michx. .
19. ↑ Aquarium plants with lower maintenance requirements (selection): Small and large fat leaf , dense leaf waterweed , some water friends , some sword plants, flooding arrow weed , Java fern , wavy water ear , false water friend .
20. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 76-84.
21. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 75-78.
22. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. Tetra-Verlag, Berlin-Velten 2009, ISBN 978-3-89745-190-2 , p. 85 f.
23. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 85.
24. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 86.
25. ↑ Christel Kasselmann: aquarium plants. 2nd, revised and expanded edition. Ulmer, Stuttgart (Hohenheim) 1999, p. 60.
26. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 19-24.
27. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 19 f.
28. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 24 f.
29. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 60-62.
30. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 60–62 and 91.
31. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 66 and 90.
32. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 63-65.
33. ↑ wasserpantscher.at: Phosphate, nitrate and potassium in the aquarium (PDF)
34. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 62 f.
35. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 56–60 and 91.
36. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, pp. 56 and 91 f.
37. ^ Hans-Georg Kramer: Plant aquaristics á la Kramer. 2009, p. 91 f.
38. ↑ Animal Welfare Act .
39. ↑ ZZF: ZZF: sales data of the pet industry. Retrieved June 11, 2020 . 
40. ↑ For the fish: Largest aquarium in the world. In: Kleinezeitung.at , print edition of June 7, 2014, p. 8 f.
41. ↑ Kevin Lynch: China's Hengqin Ocean Kingdom confirmed as world's largest aquarium as attraction sets five world records. In: guinnessworldrecords.com , March 31, 2014, accessed June 7, 2014.
42. ^ European Aquarium and Terrarium Association
43. ↑ http://www.pop-zeitschrift.de/2018/12/03/appetite-for-the-magnificenteine-essayistische-tauchfahrt-in-die-untiefen-des-aquariums-am-beispiel-philip-henry-gossesvon -joerg-scheller
44. ↑ Thomas Steinfeld : Review

This article was added to the list of excellent articles on April 30, 2006 in this version .