Quick issue this one, Tom Heo lets you in on the secret of a super/cheap reef, and an article on coral reef zonation, by DBW, is featured.
Editorial
Welcome again to another OZ REEF Press.
Sorry if this appears just a bit rushed, but it is.
Tonight I am off to celebrate 3 years with my fiance, and 3 years until our wedding.
So the mind is not quite 100% on this issue ;-)
It is good to hear that quite a few people read and appreciate the information that I put together here.
That is what this is all about, the sharing of knowledge or the advancement of this hobby.
If you ever have something that your believe I have incorrectly stated, am barking up the wrong tree completely, or are interested in further information then just let me know.
I am currently just putting stuff on here that I find interesting and that may be lacking in the available material on the WWW.
So any comments/help/feed-back would be appreciated.
On the DIY side of things this last month I have started on the chiller to keep OZ REEF cool during the summer.
This is something that will be very important, with the temperature of the Park likely to hit over 35oC without one.
And I am sure that you realise that this is way too hot for a reef to survive at for very long.
I currently have two fans in the canopy that will blow air across the water surface and the metal halide globes, that will be connected to a thermostat.
On top of this I am going to have a chiller.
It will consist of a small bar fridge that has been altered slightly, a small pump and a thermostat.
So far I have the fridge and have commenced the alterations to it.
I will keep you posted on how things go, and once it is completed I will put some plans online.
Additionally there is now online the details of the feeder that is used to feed most of the corals and a couple of the fish.
It can be found in the DIY Projects or Construction Diary sections.
The feeder is very handy little instrument to use, making it very easy to make sure that everything gets enough to eat.
It is primarily used to feed the Synchiropus picturatus, mandarin.
The food is sucked up into the airline, in this case it is brine shrimp for the mandarin, then the feeder is immersed in the Park.
Then the brine shrimp is released very close to the target fish, the mandarin, and then they are guarenteed to get some to eat.
This is especially important with a mandarin as they are not as out going as many of the other fish currenting in the Park, and he/she is just not quick enough to get any before the other fish would.
This is bit of a shrimp editorial this month ;-)
They have been up to quite a lot, and they are really quite an interesting organism to observe.
The chromis are now being cleaned by the Lysmata amboinensis, Clean shrimp.
This is really quite surprising because of the shrimp being a bit larger than the fish, and I thought that this would be threatening to them.
But this has obviously been overcome.
It only occurs a couple times per day, that has so far been observed.
It is really quite interesting to watch the interaction between the shrimp and the fish.
The chromis has to hover next to the rock, and the shrimp reaches out to them and picks at their skin.
Hopefully will have more opportunities to observe this behaviour and pick up more of what is happening.
The Cleaner Shrimp Now Are Reproducing!!!
This is just so cool.
Last weekend I noticed that one of the Lysmata amboinensis, cleaner shrimp, was slightly discoloured under its tail.
Apon closer inspection I spotted a heap of green eggs!
From the colouring I would assume that they must be very close to being released.
On top of this it also seems that the other one in the pair may be carrying eggs at the same time.
I have not heard of this yet, but it has pale eggs under its tail as well.
Will just have to wait and see what happens, and what the entire cycle is like before I can start to make any judgements.
Currently a program has been started to remove some suspected crabs that have been spotted and a mantis shrimp.
Two breeding traps are being used to hold all the four added shrimps so that the trap does not just catch them.
The trap for catching the crustaceans is just a 600ml soft drink bottle that has had the neck cut off, inverted and inserted back into the bottle.
Yet to see how it works with crabs, and may require something much more intricate to catch the manits shrimp, but it works great for the cleaner shrimps.
Everything in that Park also appears to be showing good growth.
All the Acropora sp. fragments, 5 fragments and 4 species, are growing and with good polyp extension.
The T. maxima has produced one entire new scute since it moved in about 3 weeks ago.
The shrimps are all molting regularly, along with some of the hermits.
But the hermit molts are much harder to spot because of the size difference, so they are more likely to be molting more often than can be currently observed.
And the Euphyllia frimbiata appears to be increasing in size, and that is going to be a problem too sometime next year.
Well thats it for this month.
Next month I will just have to see if I can get this thing out a bit earlier.
Well, we will see what happens ;-)
Catch ya, DBW
Welcome OZ REEF's New Residents
1 x Linckia laevigata, Blue Linckia Starfish.
Very nice starfish this one, incredible constrasting colour to have in a reef.
1 x Synaptidae sp., Medusa Worm .
These are such a strange type of Holothoid, being worm like in shape with tentacles around the mouth.
4 x ???? (Diogenidae), Green Hermit Crabs.
Niced sized guys, with the shells they are living in about 10mm across.
1 x ???? (Diogenidae), Hermit Crab.
Very interesting colouring of this Hermit Crab, blue eyes, orange stalks, green limbs.
2 x Trochus pyramis, Trochus Snail.
2 x Turban sp., Turban Snail.
1 x Acropora sp., Staghorn Coral.
Not looking that healthy, but has a great fluorescent green tinge to it.
2 x Valenciennea puellaris, Orange Spotted Gobies.
The best sort of sand stirring fish you can get, stay nice and close to the sand and sift a heap.
1 x Zoanthus sp., Zoanthid.
Very small colony that I just asked for out of the bottom of a sales tank, green and tan coloured.
Resident of the Month
Phylum:
Chordata
Subphylum:
Vertebrata
Class:
Actinopterygii
Subclass:
????
Order:
Perciformes
Scientific Name:
Chromis viridis
Common Name(s):
Green Chromis/Reef Fish
Description:
Size: 3 to 4cm.
Color: Green/blue depending on lighting angle.
Picture:
Individual
Entire School
Entire School
Current:
N/A
Lighting:
N/A
Feeding:
Eat almost anything, flake food, brine shrimp, scallop, shrimp etc (Omnivore).
Feed several small amounts daily as highly active fish and this is how they feed in nature, continually browsing.
Aggression:
Docile to other fish, can be aggressive to other individuals in the same school.
Notes:
Very active schooling fish.
Best if keep in a large sized school, +8, so that the aggression is dispersed through the school.
Also done as they feel more safe in a larger school.
Dear Marther ReefKeeper
Sorry, but Marther has not recieved any letters of problems, so therefore unable to solve them.
Tom's Bit
by Thomas S. Heo.
This time I am going to present something new that nobody else has thought of...an invisible article?
It's really good, and I will explain exactly how to keep corals in a
glass bowl with no skimmer, no artificial light (just a match), no live
rock, and no salt.
It can be setup with common household materials, such
as Coke cans, Jello, and a bottle of Tabasco sauce.
I am really surprised no one has come up with this idea previously, it is just so simple.
Firstly you take a skdhihae dkhoiej d ahi daiodj.
Eoij ...........jfoirjoidfjkdsf jkfsdkfed
dkjfkdl
iuirijtk idjf kf thoi dhufeh pnm .. dhfds .
kj $%@ 84jd c d jiojdf.
Special Feature
Coral Reef Zonation
by
Classes Of Coral Reefs
There are three basic types of coral reefs; fringing, barrier and atoll.
Fringing reefs are located very close to shore, and because of water run off they are typically high in nutrients and the water has a high turbidity.
Barrier reefs are further from shore, with a lagoon between the reef and the shore.
And finally atolls are a circular reef with a central lagoon and possibly small islands formed on the reef.
It is theorised that each of these types of reefs corresponds to a differing age of the entire reef structure.
The youngest is the fringing reef, with the corals colonising a shallow water area close to the land.
If the sea levels then rise or the land subsides, then the reef structure keeps up with this changing depth by growing upward.
eventually a shallow area with no coral growth will form behind the main reef, called a lagoon, giving a barrier reef.
If the sea level or land subsides so much as to cause the land to disappear below the water surface, then an atoll is formed.
The overall type of the reef whether it is a turbid, high nutrient reef where the stony corals are less common and algae abounds or crystal clear, low nutrient reef where the stony corals can dominate, is dependent of several factors.
These include the proximity to land (therefore water run off which will be high in nutrients), proximity to river mouths (for the same reason as land proximity), and location of deep sea currents (which typically bring nutrient rich water.
Each type of reef is also divided into various zones within each reef.
What Is Coral Reef Zonation?
Zonation is a very important concept when considering any ecosystem, with coral reefs being no exception.
A particular ecosystem will typically be divided into zones, each one having a particular set of physical parameters, such as light intensity, that set it aside from any other part of the ecosystem.
A zone is defined by its physical parameters and location within the ecosystem. Within a particular zone, various organisms will have evolved such that they are adapted to thrive under those specific conditions that are present within that zone.
It can undoubtedly live somewhere else, in a similar zone or sometimes even one vastly different, but there is always one in which it will be perfectly suited and as a result out-compete any other organisms that occupies that niche in the food web.
What Determines Coral Reef Zonation?
Zonation within a reef is typically determined by: the light intensity received, which is dependent of the depth and turbidity of the water; position relative to the open ocean or river mouths; deep ocean currents; and localised water currents.
Each of these parameters interact to give the final conditions that are characteristic of that zone.
The most dominant parameter is the light intensity, which is the major source of energy for the reef community.
And because this is directly related to the depth, then the depth can be used as a very good indicator of the predominant conditions.
As a general rule, as the water depth increases then:
Light intensity drops.
Blue light increasingly becomes the more dominant wavelengths in the light spectrum, as the other wavelengths are absorbed more rapidly by the water.
Wave surges become less intense, but currents can still remain strong
Water temperature falls and becomes more constant
Therefore the particular organisms that are present on the reef alter with the depth, as each one has evolved to fit best into one area.
The organism can also alter its behavior depending on the zone, with the physical conditions have a large effect on its behavior and even its appearance.
This is graphically shown by many of the stony corals.
In the shallow, high light intensity and extreme water motion zones they will form fingered or massive (domed) structures.
As the depth increases, light intensity rapidly drops off and wave surges are reduced, but the currents can still remain strong.
To adapt to this lower availability of light, stony corals then take on thin, flattened plates therefore increasing the surface area that is exposed to the light.
Storms are another factory that can also affect and alter the zonation of a reef.
The force of the waves and associated surges batter the reef structure, break some of the reef building corals weakened by boring organisms, distribute and eroding sediment, and eroding the shores of coral cays.
Why Is This Important For A Reef Aquarist?
This is all well and good, but what does this have to do with someone wanting to have a small part of a reef in their home?
In actual fact it is very important.
If it is understood where a particular genus/species thrives and exists on a natural reef, then the conditions that it requires within an aquarium can be inferred.
For example if a coral is found on the reef rock rim, then it is exposed to high light intensity and strong wave surges.
To keep such a coral health and happy in an aquarium under similar conditions then intense lighting and devices that cause surges throughout the tank are required.
On the other hand if it is found on the reef slope, then it is exposed to low light levels, very few surges and strong currents.
Such a coral requires lower lighting levels and more constant water currents to be kept in an aquarium.
This article deals mainly with corals, both Alcyonaceans (Soft Corals) and Scleractinians (Stony Corals) orders, the main species that are found in each of the zones, and the outstanding physical properties that are characteristic of that zone.
Each zone is presented in order of its appearance from the ocean to the land.
Note that this is a generalised progression, and a real reef may vary from this and miss some of the zones.
As usual, nature will not follow strict rules.
Reef Front / Forereef Front
The reef front is the first part of the reef as land is approached, i.e. the front of the reef.
As the sea floor starts to approach the surface, then enough light starts to penetrate and supply the energy required for a reef community to exist.
This is divided into two sub-zones, the reef slope and upper reef slope.
Reef Slope / Deep Forereef
Below 20m in depth on the reef front is the reef slope.
At these levels the blue part of the light spectrum dominates and the light available is vastly lower than that at the surface.
Corals expand horizontally in shape in order to capture as much sunlight as possible.
Therefore any branching species that are found in shallower waters are largely replaced by plate-like forms of the same species.
Gorgonian fans (Gorgonacea) are very prolific in this zone, along with the feather stars (Crinoidea) that are associated with gorgonians.
The dominant species present are:
Scleractinians: Echinopora, Porites, Turbinaria, and Acropora.
Alcyonaceans: Dedronephthya.
Gorgonacea: Subergorgia etc.
Upper Reef Slope / Seaward Platform
Above the reef slope to around 5m is the upper reef slope, with this being the most densely populated zone of the reef.
This region typically has a spur and groove feature, with fingers of coral formations penetrating into the ocean with coral sand channels in-between.
The spurs are typically dominated by large fingered structures of Acropora and massive coral species.
The spur formations provide calmer regions where fleshy green algae, sponges and encrusting corals can grow.
The sandy groove regions support little coral or algae growths because of the strong scouring surges and tidal run-off running through these grooves.
But the occasional tough algae growths such as Halimeda can survive.
The grooves often open out to a region of rubble and coarse sand.
This entire zone provides a region where nutrients are concentrated then transported into the reef flat area by algae growing then becoming detached.
Corals have to take on expansive body forms designed to maximise the exposure to the sunlight, but are not limited to the vast horizontal plates characteristic of the reef front.
The shallower regions also have more Scleractinians because of their more robust structure, higher growth rates under intense light and territorial defense mechanisms.
Feather stars, sponges and other suspension feeders expose themselves to intertidal currents on structures that jut out into the currents, such as gorgonians.
Inside overhangs and caverns, azooxanthellae corals, sponges and soft corals are dominant.
The dominant species present are:
Alcyonaceans: Lemnalia, Lobophytum, Nephthea, Sarcophyton, Sinularia, and Xenia.
Scleractinians: Acropora, Goniastrea, Favia, Favites, Leptoseria, Lobophyllia, Plerogyra, Pocillopora, Porites, Millepora, and Stylophora. Zoanthidea: Palythoa.
Reef Rock Rim
The rock rim is the highest energy zone of a coral reef ecosystem, with very intense light, and intense wave action and surges.
Parts of it may be exposed at low tide.
Corals that live within this zone are typically very short and fingered or massive in structure to withstand the strong wave action and as don't have to spread out to capture light.
Almost all surfaces in this zone are exposed to some light (not just the upper area as in the deeper reef front zone) so the massive and fingered structures utilised this fact and are strong enough to resist the strong currents.
Coralline algae can cements this region together, forming a solid terraced like pavement.
Also can be present low, sand binding algae mats that entrap sediment.
The dominant species present are:
Alcyonaceans: Lobophytum, Sarcophyton, and Sinularia.
Scleractinians: Acropora, Favites, Montipora and Pocillopora.
Zoanthidea: Palythoa.
Reef Flat
The reef flat behind the reef rock rim is also a rigorous environment.
The organisms here must be able to withstand intense ultra violet radiation, desiccation, high salinities and elevated water temperature.
This zone is divided into two sub-zones, living coral sub zone and sand sub-zone.
Coral cover decreases inward, with sand covering the inner part of the reef flat.
This entire zone is usually most prolific with Acropora, Actiniarians (anemones), Asteroids (starfish), Holothurioids (sea cucumbers), Alcyonaceans, and reef fishes.
Living Coral Sub-Zone
Within the living coral sub-zone tongues of the reef structure penetrate into the lagoon with narrow sand channels in-between.
This is very similar to the upper reef slope.
The coral sand that is present is produced from coralline algae, foraminifers, calcareous algae, and the breakdown of the reef structure.
Echinoids (sea urchins), Asteroids (starfish), Holothurioids (sea cucumbers) and molluscs are abundant over this entire zone.
The dominant species present are:
Scleractinians: Acropora, Pocillopora, Gonipora, Platygyra, Seriatopora, Lobophyllia, Tubipora, Montipora, Fungia, Goniastrea, Favia, Favites, and Porites.
Sand Sub-Zone / Lagoon
Gradually the reef structure gives way to vast areas of coral sand eroded from the main reef structure.
Dotted throughout this zone are small 'islands' of Scleractinians that rise up out of the sand.
In the calmer regions delicate branched corals form intricate growths.
The lagoon is constantly supplied with nutrients and sediment removed from the reef front and reef rock rim zones, with some lagoons becoming muddy from the accumulated sediment.
Holothurioids are prolific inhabitants and constantly rework the surface sediment.
Deeper lagoons with heavy sediments or high turbidity have:
Scleractinians: Cataphyllia, Euphyllia, Gonipora, Leptoseris, Pachyseris, and Montipora.
The island or patch reefs that rise out of the lagoon floor consist of:
Scleractinians: Acropora, Favia, Favites, Galaxea, Goniastraea, Pavona, Pocillopora, Porites, Seriatopora, Stylophora, and Tubipora.
Spread over the sandy bottom can be found:
Scleractinians: Heliofungia, Fungia, and Herpolitha.
Other families present:
Alcyonaceans: Heliopora, Sarcophyton, Lobophytum, Xenia, Cespitularia, and Sinularia.
Coralliomorpharia: Rhodactis.
Zoanthidea: Palythoa, and Zoanthus.
Cay
Intertidal Zone
This is another high energy zone, with the organisms that live here adapted to withstand intense ultra violet radiation, desiccation and high salinities.
There is usually water retained in tidal pools even at low tide.
Some corals can survive this harsh environment completely exposed to the air.
Gastropods are very common in this zone, and usually the most conspicuous inhabitants.
Specific family information has yet to be found.
Beach
Finally then comes the beach.
This region is of no interest to current aquaria, but hey imagine it, your own Pacific island beach!
Any thing inhabiting this region is very resilient.
Some obvious organisms are Molluscs (mainly mussels that bury themselves in the sand) and Decapods (crabs).
But there is also a multitude of interstitial sand fauna that extensively inhabits this zone.
References:
Aw, Michael, Tropical reef life: a marine awareness guide, OceaNEnvironment:Carlingford, 1997.
Delbeek, J. Charles, and Sprung, Julian, The reef aquarium: a comprehensive guide to the identification and care of tropical marine invertebrates, vol. 1, Ricordea:Coconut Grove, 1995.
Moe, Martin A. Jr., The marine aquarium reference: systems and invertebrates, rev. ed., Green Turtle:Plantation, l993.
You Wouldn't Believe It!
..... barnacles can extend its penis up to 30 times the length of its body.
The fact that barnacles are sessile and unable to move from their settled location, makes it a bit difficult to sexually reproduce.
In order to overcome this motility problem, the barnacle can extend it penis to any near neighbour in order to impregnate them with its sperm.
..... the amount of sand that a pair of Valenciennea puellaris, orange spotted gobies, can more around.
Within a day of the pair being introduced to the Park a large mound of sand about 15cm high, double the height of the sand typically, had been constructed around some rocks.
Here they were building a burrow to call home.
They pick up sand just like a shovel in their mouth, go to where they want it, then spit it out again.
And by the second day the entire bottom of the tank sand was white.
Bereavement Notices
Gonipora sp.
Well, I suppose time before this happened.
The one that has died is the smaller daughter colony, it contained about 12 polyps.
Over the course of a week it failed to open at all, then the flesh just peeled off the skeleton.
Rather a depressing thing to watch :-(
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