This is a two-part question if someone could please help!
110.0 −mL buffer solution is 0.110 M in NH3and 0.130 M in NH4Br.
Part A: What mass of HCl can this buffer neutralize before the pH falls below 9.00?
Part B: If the same volume of the buffer were 0.255 M in NH3 and 0.395 M in NH4Br, what mass of HCl could be handled before the pH falls below 9.00?
Initial number of NH3 = Molarity x vol in lts = 0.11 M x 0.11 lts = 0.0121 moles
Initial number of NH4+ = Molarity x vol in lts = 0.13 M X 0.11 lts = 0.0143 moles
Kb value of ammonia buffer = 1.8 x 10-5
pKb = -log Kb = - log (1.8 x 10-5) = 4.74
Let us consider X is Moles of HCl
Equilibrium conc. of NH3 = 0.0121 - X (decreases its conc. after addition of HCl)
Equilibrium conc. of NH4+ = 0.0143 + X (increases its conc after addition of HCl)
According to Henderson- Hasselbalch equation :
pOH = pKb + log [ NH4+]/[NH3]
pOH = 14-pH = 14 - 9 = 5
5 = 4.74 + log (0.0143 + X/0.0121-X)
5-4.74 = log (0.0143 + X/0.0121-X)
log (0.0143 + X/0.0121-X) = 0.26
0.0143 + X/0.0121-X) = Antilog (0.26)
0.0143 + X/0.0121-X) = 1.82
0.0143 + X = 1.82 (0.0121- X)
0.0143 + X = 0.022 - 1.82 X
0.0143 - 0.022 = - 1.82 X - X
-0.0077 = -2.82 X
X = 0.00273 moles of HCl
Molar mass of HCl = 36.46 g/mol
Mass of HCl = Moles x molar mass of HCl = 0.00273 moles x 36.46 g/mol = 0.0995 g
B) Initial moles of NH3 = Molarity x vol in lts = 0.255 M x 0.11 lts = 0.02805 moles
Initial number of NH4+ = Molarity x vol in lts = 0.395 M X 0.11 lts = 0.04345 moles
Kb value of ammonia buffer = 1.8 x 10-5
pKb = -log Kb = - log (1.8 x 10-5) = 4.74
Let us consider X is Moles of HCl
Equilibrium conc. of NH3 = 0.02805 - X (decreases its conc. after addition of HCl)
Equilibrium conc. of NH4+ = 0.04345 + X (increases its conc after addition of HCl)
According to Henderson- Hasselbalch equation :
pOH = pKb + log [ NH4+]/[NH3]
pOH = 14-pH = 14 - 9 = 5
5 = 4.74 + log (0.04345 + X/0.02805 - X)
5-4.74 = log (0.04345 + X/0.02805 - X)
log (00.04345 + X/0.02805 - X) = 0.26
0.04345 + X/0.02805 - X) = Antilog (0.26)
0.04345 + X/0.02805 - X) = 1.82
0.04345 + X = 1.82 (0.02805 - X)
0.04345 + X = 0.0511 - 1.82 X
0.04345- 0.0511 = - 1.82 X - X
-0.00765 = -2.82 X
X = 0.00271 moles of HCl
Molar mass of HCl = 36.46 g/mol
Mass of HCl = Moles x molar mass of HCl = 0.00271 moles x 36.46 g/mol = 0.0988 g
This is a two-part question if someone could please help! 110.0 −mL buffer solution is 0.110...
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