That's the tricky part, no? If the nitrospira does not die, but merely becomes dormant, I would expect the majority of them to become active at around the same time. If so, the graph should be rather linear after a initial lag time.
I have seen a death rate estimate of 1% per day for AOB’s. That would leave 40% of the bacteria after 3 months. @taricha’s ammonia consumption at 48 hrs seems (0.4 ppm NH3-N) close to my 0.5 ppm NH3-N in 48 hrs for a recommended dose of BioSpira. Admittedly, this could just be a coincidence. So, I am still left wondering about the AOB’s ability to get into maintenance mode and hang around a long time, and then spring into action.
I think the assumption of linearity needs a relook. Might the start up time for bacteria follow some sort of statistical distribution? I‘ll bet on the statistical distribution but have no idea whether the ammonia consumption curve would resemble an exponential curve.
If it's a normal distribution for start up, then I think i would expect something closer to a lag + linear graph. I did a simplified model to show the expected dynamic.
Yeah, in the data I posted it took ~4 days to clear ~1ppm ammonia-N, so 0.25ppm/day is a good estimate. But that same sand tested the same way immediately after 9 days of cycling (on ammonia drops) was processing 2+ppm/day. so this represents a ~90% decrease of Ammonia oxidation rate during the "curing" couple of months.
True, but since it's such a tight fit to an exponential, the derivative will just be a scaled exponential with the same rate constant.
Since this population had a high ammonia oxidizing capacity earlier, dormancy and regain of capability is plausible. Y'all are right to think about what the regain of function could look like. If it looks like this....
) 
Wait a second - if your exponential curve is similar to the rise of nitrite in your example it does not show the growth of only NOB - it shows the an combined exponential growth of both AOB and NOB instead - the nitrite that you measure is the waste product from the AOB and the resource for NOB, The waste production depends on the concentration (of NH3/NH4 their resource) and amount of AOB:s producing the waste (NO2). The use of the resource NO2 depends on the concentration of the resource and the amount of NOB:s consuming it. But your estimated growth rate is in line with other investigations I have seen. In pure media 13 hours - in combined longer
Presumably the population of NOB has not become significant / or remain dormant during the first three days?
This makes things clear.If it's a normal distribution for start up, then I think i would expect something closer to a lag + linear graph. I did a simplified model to show the expected dynamic.
I would say this mechanism is quite different from exponential growth.
Brilliant and to the point.Yeah, in the data I posted it took ~4 days to clear ~1ppm ammonia-N, so 0.25ppm/day is a good estimate. But that same sand tested the same way immediately after 9 days of cycling (on ammonia drops) was processing 2+ppm/day. so this represents a ~90% decrease of Ammonia oxidation rate during the "curing" couple of months.
True, but since it's such a tight fit to an exponential, the derivative will just be a scaled exponential with the same rate constant.
Since this population had a high ammonia oxidizing capacity earlier, dormancy and regain of capability is plausible. Y'all are right to think about what the regain of function could look like. If it looks like this....
...then there's a long tail of the fast responders waking up that could look like the exponential data I saw.
(but there's no good reason why the time dependence for that re-activation ought to look so much like a plausible doubling time for ammonia oxidizers. could be coincidence though.)
Might find this relevant to discussion at hand....
"Stationary-phase cells, washed and resuspended in ammonium free inorganic medium, were starved for periods of up to 42 days, after which the medium was supplemented with ammonium and subsequent growth was monitored by measuring nitrite concentration changes. Cultures exhibited a lag phase prior to exponential nitrite production, which increased from 8.72 h (no starvation) to 153 h after starvation for 42 days. Biofilm populations of N. europaea colonizing sand or soil particles in continuous-flow, fixed column reactors were starved by continuous supply of ammonium-free medium. Following resupply of ammonium, starved biofilms exhibited no lag phase prior to nitrite production, even after starvation for 43.2 days, although there was evidence of cell loss during starvation. Biofilm formation will therefore provide a significant ecological advantage for ammonia oxidizers in natural environments in which the substrate supply is intermittent."
That seems to be a plausible parallel for my months-long "curing" sandbed recirculating in the dark with no inputs.
(What were we talking about again? Sorry for the derail, Dan.
For the initial portion, barring any measurement accuracy issues, does not suggest a strong correlated NH4 and NO2.Right. The exponential that fits the rise of NO2 tells something about the population of active Ammonia oxidizers. When it stops fitting the exponential 3+ days is when the NOB show up and become important.
if you look at the points in the Red oval, during this time frame - the ammonia decrease matches tightly to the NO2 increase - no "missing" N (yet). The blue and green data mirrors each other tightly.
After that point, from 3+ days on, the NO2 level drops below what would be expected from the Ammonia decrease. That is, NO2 "goes missing" as it went to NO3.
I didn't try to test through NO2 to find NO3 during the time, but after clearing NO2, the final NO3-N was 1.5ppm (initial ~0.2ppm) and the input was 1.06 ppm Ammonia-N. So decent agreement with the classical ammonia->NO2->NO3 expectation.
Right. The large initial drop in ammonia (day 0.0 to 1.0 data) clearly has nothing to do with the slowly ramping up ammonia->NO2->NO3 pathway.
I am starting that experiment today. The rock in my 2 tanks have not been 'fed' for a month now (give or take). They were previously able to process 2ppm in approx 24 hours. Do you think a month is enough?
Darn - I added the ammonia today
btw - between your experiments. - do you exchange all the water? I think I will do it - it gives a 1 month version at least. But at least I have the tanks to do the experiment 2 months from now
Yes, 100% water changes between runs.Darn - I added the ammonia today
I just completed the study - in the 'experiment section' - within 24 hours - the free ammonia level was clearly back to safe - from 2ppm/alert. (after a month)
