# Tap water pH adjustment using citric acid

I've lowered tap water pH from 7 to 6 using citric acid. After couple of hours pH raised again to 7.

What is the reason for this raise? Citric acid overcomes waters buffering feature then raise the $$\ce{H+}$$ concentration in water. Why pH raise again?

The pH was measured using a pH meter.

• The first part alone is hard to believe. Tap water is not much of a buffer, it's nearly impossible to get it to pH = 6 and not further. – Ivan Neretin Dec 24 '19 at 13:26
• @Ivan Neretin In the Moravian carst area, the majority of water hardness is the bicarbonate hardness. CO2/HCO3- forms a diluted buffer with maximum capacity at pH=pKa1*=6.83, if I remember correctly. – Poutnik Dec 24 '19 at 13:56
• What is the purpose of this pH lowering of tap water ? – Poutnik Dec 25 '19 at 14:31
• The purpose is to lower unionized ammonium level (NH3) in fresh water aquarium. For every unit increase in pH unionized ammonium will increase 10 times. So lowering ph will decrease NH3. – Mohsen Jafari Dec 25 '19 at 19:18
• Is the pH measured with or without fish in the treated water? – James Gaidis Dec 26 '19 at 15:47

Maybe citric acid have had a negligible effect on the pH. Everybody knows that in contact with air, pure water is carbonated by CO2 from the atmosphere. And the pH may go down to 5.5. Later on, the water may loose its CO2, and the pH goes back to 7

If the water contains significant amount of bicarbonates, part of released carbon dioxide may escape and original bicarbonate is finally replace by the dihydrogen or hydrogen citrate.

$$\ce{ HCO3- + H3Citr -> H2Citr- + H2O + CO2 ^}$$ $$\ce{2 HCO3- + H3Citr -> HCitr^2- + 3 H2O + 2 CO2 ^}$$

So, the final $$\mathrm{pH}$$ may not differ much from the original one, compared to the temporary one.

• So if I want to lower it how can I do it? Is there any other ways to lower pH and keep low? – Mohsen Jafari Dec 24 '19 at 18:39
• Try adding a citrate buffer Na2HCitr/Na3Citr. pKa3 = 6.39, You can prepare it by citric acid solution neutralisation to pH 6. – Poutnik Dec 24 '19 at 18:52

Oxygenated tap water is rich in transition metals including Fe and Mn ions. Citric is a source of H+ and a good chelate and can drive a redox reaction in the presence of oxygen and H+ proceeding as follows: $$4 Fe(2+)/Mn(2+) + O2 + 2 H+ --> 4 Fe(3+)/Mn(3+) + 2 OH-$$

There is also a likely metal redox couple equilibrium(s) that can be effective in recycling ions (to continue the reaction, as occurs in natural waters) in the presence of citrate acting a chelate for, say, ferric:

Fe(2+) + Mn(3+) = Fe(3+) + Mn(2+)

Cu(+) + Fe(3+) = Cu(2+) + Fe(2+)

In the presence of lab or sunlight, some further recycling of metal ions is possible.

Reference: See my comments and sources cited here.

The reaction with oxygen is electrochemical in nature with an inception period and proceeds with time.

Note: H+ is consumed, so the pH would be expected to rise.

Here is a further electrochemistry reference, in particular, Table 2, where the first listed half-cell reaction corresponds to the above after adding two H+ to both sides (creating water as a product). However, as this reaction can produce basic salts, as I have discussed previously, I believe it is more informative. Further, I do prefer my rendition, as per my prior link supplied above, it could also display a possible radical chemistry underpinning to the underlying half-cell reaction mechanics.

• I doubt chelation would take a couple of hours, in homogeneous aqueous solution it should be much faster. Also, I tried to follow you cited sources, but it appears like you are quoting yourself quoting Wikipedia on copper(I) oxidation, which has a questionable relation to this topic, so it would be nice if you duplicate your sources here, both for clarity and to protect the post from link rot. – andselisk Dec 24 '19 at 15:02
• There is not enough metal in water. Even traces of metallic ions make the taste of water quite bad. This is not the correct reason. We have to confirm if the author is using citric acid indeed or not! – M. Farooq Dec 24 '19 at 18:21