please look at how a sewage treatment plant operates because i have a feeling you feel that they also perform magic and are also able to make P vanish.
More dots. I've actually overseen the operation of several in the state institutions I ran during my career. Nothing vanishes but it can be sequestered.Conditiions in wastewater and sewage treatment are not like conditions in a reef tank and mostly irrelevant to this discussion,imo.
how is this irrelevant? i hear it all of the time that "refugiums" and the DSB act like sewage treatment plants. which they do, but not in the way they are reported. they imply that it is a way to make nutrients just disappear. there is significant material exported from a sewage treatment plant. it is not sequestered at the sewage treatment plant, it is actually removed. sent to land fills or in some cases converted to fertilizers. the point is that the P is not just vanishing. even in a sewage treatment plant there is a waste product that needs to be exported from the system.
the point of "cooking" is to convert the iP bound to the calcium carbonate matrix into oP in the form of the bacterial bodies. at which point the oP can be removed by siphoning. how do you think "cooking" works?
Bacterial bodies degrade;ultimately there is no more energy to be had from degradation from the bacterial cascade . The phosphate is sunk at least for a very long time barring some extraordinary environmental change or activity by PSBs(phospahte solubilizing bacteria)which likely don't do much if anything in a reef tank),imo.
The only reason I mentioned PSBs is because you asserted a significant role for them several times but now say that's not what you meant.
why do you think that PSB's are not doing much work in a reef tank? "cooking" LR shows that they are doing a significant amount of work in the system. all of that detritus building up while cooking is a visual indication that iP is being pulled from the calcium carbonate matrix. we know the cooking is done when the detrital accumulation stops.
yes, the bacterial flock can degrade releasing iP back into the system if not removed. why it is important to remove detritus on a regular basis. the less substrate for this bacterial flock to hide, the more often one needs to remove it in order to maintain the desired trophic level. if there is no more energy to be had from degradation from the bacterial cascade, then how is this material not considered a P sink? at what point do the PSB's start doing their work in our systems, if not all of the time?
I feel a bit like :deadhorse1: saying this, but again we need to check ourselves with these nutrient terms. No coral reef, be that natural or captive, anywhere on planet earth, can exist in or as an 'oligotrophic system'. The best examples we have of true oligotrophic systems are various European and North American lakes (usually alpine). The only thing you find living in the most oligotrophic of them are mats of cyanobacteria, because "cyano" biofilms are in fact light, oxygen, and pH stratified assemblages of bacteria (cyano, hetero and autotrophic), diatoms, and dinoflagellates that together can fix nitrogen directly from the atmosphere while recycling the critically low number of carbon and phosphorous atoms they capture pretty much in perpetuity. Nothing else can live in them. No fish, no plants, and certainly not coral reefs in marine examples. Trophic state (i.e. eutrophic or oligotrophic) refers to either the amount of primary productivity occurring in that system, or by another definition the total weight of biomass in a given body of water. Coral reefs (including all the stony acroporid and montiporid reefs we love) are some of the most nutrient dense, high biomass places on the planet, with very high primary productivity, which by definition makes them highly eutrophic systems. Those nutrients just aren't in the water. Having low total dissolved nutrients in the water around the most productive ecosystem that's ever existed in the history of life is not a sign of oligotrophy. It is a sign of highly efficient capture and recycling pathways and a tremendous amount of biological activity.
There is mountains of published research on this. You are using the terms wrong, which I think is leading you to mis-apply the concepts as well.
agreed. i have been using the terms to denote the amount of dissolved inorganic nutrients available in the water column. i will be more specific from now on. it does lead to confusion.
Yes, you can remove a sand bed and technically reduce the 'trophic state' of your tank because you've physically removed biomass, but why would that have anything to do with the keeping of corals? What corals care about is the moment to moment chemistry of the water they are immersed in, not the total number of atoms bound up in the organisms and biological pathways around them. Everything else being equal, let's say a tank with a sand bed has 3 times the total biomass, and thus 3 times the total number of organic carbon, nitrogen and phosphate atoms relative to a bare bottom tank. However, if the bare bottom tank and the sand bed tank have the same levels of dissolved nitrate and phosphate in the water - which is easily testable and controllable via a myriad of available technologies - then from the coral's point of view there is no difference between those systems whatsoever.
you are correct. the point i am trying to make is that we are throwing large amounts of resources at our systems in order to keep iP levels down instead of just removing the waste organic material that ultimately leads to a significant amount of dissolved inorganic nutrients. we use GFO, algae, resins, carbon dosing to cover up the affects of the decomposition of the waste organic material. hoping to remove the iP from the water column at a rate that matches the dissolved iP of the environment we are trying to replicate. all of these are resources that would not need to be as necessary if the waste organic material was removed before it has a chance to decompose. yes iP is testable and gives us something to chase, but just looking to see the amount of biomass in the system can also tell you the amount of waste oP that is being produced and ultimately able to become dissolve iP.
As an analogy: the height of a dam and the size of the lake behind it doesn't necessarily have anything to with the downstream flow rate of the river. Running bare bottom to avoid accumulation of biomass and maintain a lower 'trophic' state is just lowering the height of the dam, but it's the flow rate of the river that we care about.
a BB dam would require less resources to hold back the water to maintain the desired water flow.
the dam would not need to be made as strong, the valves holding back the water would not have to be as large. these are all resources (cost/maintenance).
I would argue that by the time you see it as detritus, most of the P that it's going to contribute to your system's rocks, water, and organisms has already been contributed. Unless you're siting in front of your tank with the siphon waiting for your fish to poop, or you vacuum every bit of uneaten food 2 minutes after you feed it, the detritus you're seeing is the end result result of the process, not the beginning. If you call using GFO to remove dissolved orthophosphate from the water top down, then vacuuming the undecomposable fraction of organic matter that collects in overflows and sumps as detritus is like top-top down. That phosphate is already in play.
as long as it is in solid form it can be removed. once removed it is not in play. if it is hiding in the substrate it is always in play. it takes time for decomposition to take place. it is not instantaneous. siphoning once a week will do wonders. you do not need to siphon every day. this is where the skimmer earns it keep. it is the only piece of equipment we use that actually exports P continuously. it makes sense to have the skimmer do as much as it can. have it see as much of the tank water as possible.
and that is why biodiversity and ecosystem are fancy words for phosphate sinks (cesspool)
Seems I keep diving in cesspools, aka one of one of the most biodiverse ecosytems on the planet...yup, you guessed it, the reef The ability of that diverse ecosystem to recycle nutrients such that the water on the reef is so nutrient poor, all the while the total nutrient levels of the reef on the whole are incredably high is something that is quite fascinating. Equally fascinating is our ability to recreate those cesspools (err, reefs) as well as we do.
I'm wondering, next class I take out to the sea grass beds, should I say "welcome to the cesspool, now jump in and start running transects"
it is important to know which type of reef someone is trying to emulate. the dissolved inorganic nutrient poor outer reef or the higher dissolved inorganic nutrient inner reefs. we need to setup our systems to match our must have organisms. why are we all told to setup our systems the same, when the organisms we keep can come from very different environments?
can we recreate the reefs even better if we would stop trying to setup all of our recreated reefs the same and start paying more attention to the environment that the organisms come from? if one wanted to grow sea grass, they would not use a BB system. if one wants to grow Acropora, then why have a substrate? i am just suggesting matching methodologies to the organisms wishing to be kept and understanding the pros and cons of each. that way the hobbyist can make informed decisions on what is more important to them and adjust for the pro's and con's to maintain the desired environment.
G~
