Sorry but I'd like to correct you, so everyone can benefit. I'm a environmental science major, ocean represents one of most important part on our planet.
Firstly, denitrifying bacteria only lives in anoxic area, it is a desirable area for them unlike hypoxic area where nitrifying bacteria can thrive, whereas denitrifying bacteria cannot.
1-2 inches under sea floor(or in aquarium the sand bed), is not considered as hypoxic zone. There is still a great amount of oxygen and water circulation for nitrifying bacteria to live in.
Therefore burying a rock under 2 inches will not help denitrifying bacteria to grow, as the depth is not near to anoxic zone also the rock is porous.
If nitrifying bacteria grows in a specific zone, you will never find denitrifying bacteria in the same zone.
oTo enter hypoxic zone, you will need over 2 inches of sand, and for anoxic zne you need over 4 inches of sand to stimulate a mini ocean.
If you were to manage to keep denitrifying bacteria under an impermeable rock, they are not going to thrive long enough to complete the cycle and for such a small area it is not going to give you benefit also.
Well, I wish you had asked a question rather than posting infromation that demonstrates a misunderstanding of the nitrogen and anaerobic and aerobic activity.
Ufortunately, your post needs to be corrected:
Firstly, denitrifying bacteria only lives in anoxic area, it is a desirable area for them unlike hypoxic area where nitrifying bacteria can thrive, whereas denitrifying bacteria cannot.
False.
Denitrifying bacteria are faculative heterotrophic bacteria. Heterotrophic means they can't produce their own carbon sources . Faculative means they use oxygen directly and when it's not available as in hypoxic conditions go to NO3( nitrate ) for oxygen to respire. they live in the presence of oxygen and in hypoxic areas too. They do not live in anoxic areas where no oxygen or nitrate is available. Anoxic areas are the domain of sulfur reducing bacteria which take oxygen from sulfate(SO4),creating toxic hydrogen sulfide gas and sufides as by products.
Therefore burying a rock under 2 inches will not help denitrifying bacteria to grow, as the depth is not near to anoxic zone also the rock is porous.
Two inches of sand is plenty of depth for anoxia.
False,
Burying a live rock a couple of inches down in the sand will provide decaying organic matter which provides the organic carbon the heterotrophs need to flourish. They will exhaust the oxygen and nitrate creating an anoxic environment where the sulfur reducing bacteria will take over .This is why buried areas of rock often show black sufide deposits which occur as hydrogen sulfide is oxidized.
If nitrifying bacteria grows in a specific zone, you will never find denitrifying bacteria in the same zone.
False,
As noted above denitrifying bacteria are faculative heterotrphs which means they live in oxic( high oxygen) and hypoxic (low oxygen including that in NO3)areas often even in the same clump of bacterial mulm if a source of organic carbon is present.
oTo enter hypoxic zone, you will need over 2 inches of sand, and for anoxic zne you need over 4 inches of sand to stimulate a mini ocean.
False.
Studies have shown that denitrification occurs quite well in shallow sand beds of an inch or less.
If you were to manage to keep denitrifying bacteria under an impermeable rock, they are not going to thrive long enough to complete the cycle and for such a small area it is not going to give you benefit also.[/QUOTE]
False.
Live rock is not impermeable. The faculative heterotrophs live in the rock and the sand under it. As flowing water strikes the rock or any obstruction there is a drop in water pressure under the rock footprint which causes advective flow, an upwelling under the rock and consequent downward flow of water to the void created by the upwelling water.. This flow sources organic carbon ,oxygen and nitrate and mitigates against anoxia. This is part of how natural reefs work as sediment nutrients flow upward through the reef structure.
Good luck in your studies. Reading about the nitrogen cycle, nitrifying and bacteria, heterotrophic bacteria , advective flow , anaerobic digestion,and basic reef chemistry will be helpful in improving an understanding of the interplay between the physics, chemistry and biology of natural reefs. Searches on these terms will yeild a welath ofinformation and many associated scientifc studies.
