Your blood is a very slightly basic solution. Let's consider what happens when you drink a big bottle of soda (pH ~ 3):
Okay, maybe that's not what happens when you drink a soda. However, if there wasn't something in your blood that stabilizes its pH, it's exactly what would happen.
Buffers are solutions that resist changes in pH when acids or bases are added to them. They consist of weak acids and their conjugate bases.
As it turns out, your blood, like many solutions, is a buffer. Buffers are solutions consisting of a weak acid and its conjugate base—these solutions resist changes in pH when either acid or base is added to it.
Let's say that we have a buffered solution that contains acetic acid as its weak acid and sodium acetate as its conjugate base. If we were to add some hydrochloric acid to this solution, the sodium acetate would react with it by the following process:
The Mole Says
The quantity of acid or base that a buffer can neutralize before the pH changes greatly is called the "buffering capacity." Buffered solutions with high concentrations of weak acid and conjugate base have higher buffering capacities than those with low concentrations.
As you can see, the very strong HCl that's been added to the solution has been converted to acetic acid, which is a weak acid. Because weak acids cause a much smaller disruption in pH than strong acids, the pH of the solution will decrease much less than if it contained no sodium acetate.
Likewise, if we were to add sodium hydroxide to this solution, the acetic acid would react to it by the following process:
Because the strong base NaOH has been converted to the weak base sodium acetate, the pH of the solution won't rise nearly as much as if the acetic acid weren't present in the first place.
We can determine the pH of a buffered solution by using the Henderson-Hasselbalch equation:
where Ka is the acid dissociation constant of the weak acid in the buffered solution.
Example: What's the pH of a solution that contains 0.100 M acetic acid and 0.200 M sodium acetate? Ka (C2H3O2H) = 1.75 × 10-5.
Solution: Using the Henderson-Hasselbalch equation, we find that:
Excerpted from The Complete Idiot's Guide to Chemistry © 2003 by Ian Guch. All rights reserved including the right of reproduction in whole or in part in any form. Used by arrangement with Alpha Books, a member of Penguin Group (USA) Inc.