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4 June, 09:14

A beaker with 1.80*102 mL of an acetic acid buffer with a pH of 5.000 is sitting on a benchtop. The total molarity of acid and conjugate base in this buffer is 0.100 M. A student adds 5.10 mL of a 0.440 M HCl solution to the beaker. How much will the pH change? The pKa of acetic acid is 4.740.

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  1. 4 June, 09:35
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    The pH will become a little more acid, by changing 0.225 units.

    Explanation:

    Step 1: Data given

    Volume of acetic acid buffer = 1.80 * 10² mL

    pH of the buffer = 5.00

    Molarity of acid and conjugate base = 0.1.00 M

    A student adds 5.10 mL ( = 0.0051 L) of a 0.440 M HCl solution

    The pKa of acetic acid is 4.74

    Step 2: The Henderson-Hasselbalch equation

    pH = pKa + log ([conjugate base]/[weak acid])

    with acetic acid (CH3COOH) as the weak acid and CH3COO - as it's conjugate base. The pH = 5 and the pKa of acetic acid is 4.74

    5 = 4.74 + log ([conjugate base]/[weak acid])

    log ([CH3COO-]/[ (CH3COOH]) = 0.26

    [CH3COO-]/[ (CH3COOH] = 10^0.26 = 1.82

    This means the buffer contains 1.82 times more conjugate base (CH3COO-) than weak acid (CH3COOH)

    Since both the conjugate base and the weak acid, share the same volume we can say:

    (Number of moles of CH3COO-) = 1.82 * (Number of moles of CH3COOH)

    Step 3: Calculate number of moles of acid and conjugate base

    As said, the total molarity of acid and conjugate base is 0.100 M

    [CH3COOH] + [CH3COO-] = 0.100 M

    Since molarity = Number of moles / volume (mol/L), We can write this as:

    (n (CH3COOH) / 180 * 10^-3 L) + (n (CH3COO-) / 180 * 10^-3 L) = 0.100 moles / L

    OR

    n (CH3COOH) + n (CH3COO-) = 0.018

    1.82*n (CH3COOH) + n (CH3COOH) = 0.018

    n (CH3COOH) = 0.00638 moles

    n (CH3COO-) = 1.82 * 0.00638 moles = 0.0116 moles

    Step 4: Adding 5.10 mL of a 0.440 M HCl solution:

    When adding HCl, the HCl will react with the acetate anions to form acetic acid and chloride anions (Cl-):

    HCl (aq) + CH3COO - (aq) → CH3COOH (aq) + Cl - (aq)

    ⇒For 1 mole of HCl consumed, we need 1 mole of CH3COO-, to produce 1 mole of CH3COOH and 1 mole of Cl-

    Step 5: Calculate moles of HCl

    Number of moles = Molarity * Volume

    Number of moles HCl = 0.440 M * 5.10 * 10^-3 L = 0.002244 moles

    Step 6: The limiting reactant

    HCl is the limiting reactant and will be completely consumed by the reaction. 0.002244 moles is consumed. There will remain 0 moles.

    Step 7: Calculate remain moles

    For CH3COO-, there is also 0.002244 moles consumed.

    There will remain 0.0116 moles - 0.002244 moles = 0.009356 moles

    For CH3COOH, there will be produced 0.002244 moles. There will be in total: 0.00638 moles + 0.002244 moles = 0.008624 moles

    The total volume of the solution is: 180 mL + 5.10 mL = 185.1 mL = 0.1851 L

    Step 8: Calculate the concentrations

    Concentration = Number of moles / volume

    The concentrations of acetic acid and acetate ions will be:

    [CH3COOH] = 0.008624 moles / 0.1851 L

    [CH3COOH] = 0.0466 M

    [CH3COO-] = 0.009356 moles / 0.1851 L

    [CH3COO-] = 0.0505 M

    Step 9: Calculate the new pH

    pH = 4.74 + log (0.0505 M / 0.0466 M)

    pH = 4.775

    ΔpH = 5 - 4.775 = 0.225

    The pH will become a little more acid, by changing 0.225 units.
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