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Chapter 2: Problem 24

Preparation of a Phosphate Buffer Phosphoric acid \(\left(\mathrm{H}_{3} \mathrm{PO}_{4}\right)\), a triprotic acid, has three \(\mathrm{p} K_{\mathrm{a}}\) values: \(2.14,6.86\), and 12.4. What molar ratio of \(\mathrm{HPO}_{4}^{2-}\) to \(\mathrm{H}_{2} \mathrm{PO}_{4}^{-}\)in solution would produce a \(\mathrm{pH}\) of \(7.0 ?\) Hint: Only one of the \(\mathrm{p} K_{\mathrm{a}}\) values is relevant here.

Short Answer

Expert verified
The molar ratio is approximately 1.38:1 of \(\mathrm{HPO}_4^{2-}\) to \(\mathrm{H}_2\mathrm{PO}_4^-\).

Step by step solution

01

Identify the Relevant pKa

Phosphoric acid, being a triprotic acid, can lose protons stepwise, and each step has a different pKa value: 2.14, 6.86, and 12.4. When we want to create a buffer with a pH of 7.0, we should use the pKa value that is closest to this pH. Therefore, the relevant pKa is 6.86, which corresponds to the equilibrium between \( \mathrm{H}_2\mathrm{PO}_4^- \) and \( \mathrm{HPO}_4^{2-} \).
02

Use the Henderson-Hasselbalch Equation

The Henderson-Hasselbalch equation is given by: \[ \mathrm{pH} = \mathrm{p}K_{\mathrm{a}} + \log \left( \frac{[\mathrm{A}^-]}{[\mathrm{HA}]} \right) \]Where \([\mathrm{A}^-]\) is the concentration of the conjugate base and \([\mathrm{HA}]\) is the concentration of the acid. Here, \([\mathrm{A}^-] = [\mathrm{HPO}_4^{2-}]\) and \([\mathrm{HA}] = [\mathrm{H}_2\mathrm{PO}_4^-]\). Plug in the desired pH and the relevant pKa value:
03

Solve for the Molar Ratio

Set the pH to 7.0 and \(\mathrm{p}K_{\mathrm{a3}}\) to 6.86 in the equation:\[ 7.0 = 6.86 + \log \left( \frac{[\mathrm{HPO}_4^{2-}]}{[\mathrm{H}_2\mathrm{PO}_4^-]} \right) \]Subtract 6.86 from both sides to get:\[0.14 = \log \left( \frac{[\mathrm{HPO}_4^{2-}]}{[\mathrm{H}_2\mathrm{PO}_4^-]} \right) \]
04

Evaluate the Logarithm

To solve for the ratio \( \frac{[\mathrm{HPO}_4^{2-}]}{[\mathrm{H}_2\mathrm{PO}_4^-]} \), exponentiate both sides with base 10:\[10^{0.14} = \frac{[\mathrm{HPO}_4^{2-}]}{[\mathrm{H}_2\mathrm{PO}_4^-]} \]Using a calculator, find \(10^{0.14} \approx 1.38\).
05

Conclusion

The molar ratio of \(\mathrm{HPO}_4^{2-}\) to \(\mathrm{H}_2\mathrm{PO}_4^-\) required to achieve a pH of 7.0 is approximately 1.38 to 1. This means that the concentration of \(\mathrm{HPO}_4^{2-}\) should be 1.38 times the concentration of \(\mathrm{H}_2\mathrm{PO}_4^-\) in the buffer solution.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Henderson-Hasselbalch equation
The Henderson-Hasselbalch equation is a useful tool in chemistry for understanding the relationship between pH, pKa, and the concentration of acid and its conjugate base. It essentially states that the pH of a solution is equal to the pKa of the acid plus the logarithm of the ratio of the concentration of the conjugate base \[ [A^-] \] to the concentration of the acid \[ [HA] \].

This equation is especially helpful when preparing buffer solutions. Buffers are solutions that resist changes in pH upon the addition of small amounts of acids or bases. By allowing chemists to calculate the exact ratio of acid to conjugate base needed to achieve a desired pH, the Henderson-Hasselbalch equation is vital in buffer preparation.

Using this equation in the context of a phosphate buffer, we set \( ext{pH} = ext{p}K_a + ext{log} rac{[A^-]}{[HA]} \). This equation, when rearranged, allows us to solve for the concentration ratio that gives us a particular pH in the buffer system.
pKa values
pKa values are crucial in understanding how an acid dissociates in a solution. Each type of dissociation, where a proton is donated to the solution, has a corresponding pKa value. They are unique to each acid and indicate the strength of an acid.

A lower pKa value means a stronger acid, as it signifies that the acid more readily donates a proton. Conversely, a higher pKa value implies a weaker acid.

In the case of phosphoric acid, a triprotic acid, there are three pKa values because it can lose three protons, each with increasing difficulty. For the preparation of a phosphate buffer, identifying the correct pKa value closest to the desired pH is essential. For a pH of 7.0, the pKa value of 6.86 is most relevant.

The knowledge of pKa values allows chemists to predict at what pH levels specific ionic species will dominate in a solution.
buffer solutions
Buffer solutions play an essential role in maintaining the pH of a system. These solutions are a combination of a weak acid and its conjugate base (or a weak base and its conjugate acid). By absorbing excess H鈦 or OH鈦 ions, buffers stabilize the pH of a solution.

In biological systems, many processes rely on precise pH conditions. Buffers are crucial in scenarios like enzyme activity, where any shift in pH can lead to significant changes in activity rates.

When preparing a phosphate buffer, one must consider the ratio of \([HPO_4^{2-}]\) to \([H_2PO_4^-]\) and use the Henderson-Hasselbalch equation to maintain the solution at a desired pH. The balance of these compounds ensures that the overall pH of the buffer solution can resist changes when exposed to external influences.
triprotic acids
Triprotic acids, like phosphoric acid \( (H_3PO_4) \), are capable of donating three protons, making them complex yet versatile in biological and chemical systems. For each proton lost, there is a corresponding \( ext{p}K_a \) value.

In a triprotic acid like phosphoric acid, the first dissociation is the easiest, with a pKa of 2.14, followed by a pKa of 6.86 for the second proton, and finally 12.4 for the third. To prepare a buffer at a specific pH, it is necessary to use the pKa value closest to the pH desired. This ensures the components in the solution are balanced to maintain that pH.

Understanding the sequential release of protons in triprotic acids helps in calculating the precise molar ratios needed in solution to achieve a desired pH level. This characteristic makes triprotic acids a powerful tool in preparing buffered solutions in both laboratory and industrial settings.

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Most popular questions from this chapter

That is the \(\mathrm{pH}\) of a solution that has an \(\mathrm{H}^{+}\)concentration of a. \(1.75 \times 10^{-5} \mathrm{~mol} / \mathrm{L}\); b. \(6.50 \times 10^{-10} \mathrm{~mol} / \mathrm{L}\); c. \(1.0 \times 10^{-4} \mathrm{~mol} / \mathrm{L}\); d. \(1.50 \times 10^{-5} \mathrm{~mol} / \mathrm{L}\) ?

Phosphate-Buffered Saline pH and Osmolarity Phosphate-buffered saline (PBS) is a solution commonly used in studies of animal tissues and cells. Its composition is 137 m? \(\mathrm{NaCl}, 2.7\) m? \(\mathrm{KCl}, 10 \mathrm{mM} \mathrm{Na}_{2} \mathrm{HPO}_{4}\left(\mathrm{pK}_{\mathrm{n}}=2.14\right), 1.8 \mathrm{~mm}\) \(\mathrm{KH}_{2} \mathrm{PO}_{4}\left(p K_{\mathrm{a}}=6.86\right)\). Calculate the pH and osmolarity of PBS. Give the osmolarity in units of osmoles per liter (osm/L).

Reological Effects of pH The defendant in a lawstait over industrial pollution is accused of releasing effluent of pHI 10 into a trout stream. The plaintiff has asked that the defendant reduce the eftluent's pI to no higher than 7 . The defendant's attorney, aiming to please the court, promises that his client will do even better than that: the defendant will bring the pH of the effluent down to 1! a. Will the defense attorney's suggested remecty be acceptable to the plaintiff? Why or why not? b. What facts about pH does the defense attorney need to understand?

8 Acidity of Gastric HCl A technician in a hospital laboratory obtained a \(10.0 \mathrm{~mL}\) sample of gastric juice from a patient several hours after a meal and titrated the sample with \(0.1 \mathrm{~m} \mathrm{NaOH}\) to neutrality. The neutralization of gastric \(\mathrm{HCl}\) required \(7.2 \mathrm{~mL}\) of \(\mathrm{NaOH}\). The patient's stomach contained no ingested food or drink at the time of sample harvest. Therefore, assume that no buffers were present. What was the \(\mathrm{pH}\) of the gastric juice?

Calculation of \(\mathrm{p} K_{\mathrm{a}}\) An unknown compound, \(\mathrm{X}\), is thought to have a carboxyl group with a \(\mathrm{p} K_{\mathrm{n}}\) of \(2.0\) and another ionizable group with a \(\mathrm{p} K_{\mathrm{n}}\) between 5 and 8 . When \(75 \mathrm{~mL}\) of \(0.1 \mathrm{M} \mathrm{NaOH}\) is added to \(100 \mathrm{~mL}\) of a \(0.1 \mathrm{~m}\) solution of \(\mathrm{X}\) at \(\mathrm{pH} 2.0\), the \(\mathrm{pH}\) increases to \(6.72\). Calculate the \(\mathrm{p} K_{\mathrm{a}}\) of the second ionizable group of \(X\).
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