pH - AP Chemistry
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What is the pH of a solution that has \[OH-\] 1 X 10–4 M?
What is the pH of a solution that has \[OH-\] 1 X 10–4 M?
pOH would be 4 (use –log \[OH–\]) and pH would be 14–pOH = 14 – 4 = 10
pOH would be 4 (use –log \[OH–\]) and pH would be 14–pOH = 14 – 4 = 10
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What is the pH of a solution with \[OH-\] = 4 X 10-6
What is the pH of a solution with \[OH-\] = 4 X 10-6
\[OH-\] = 4 X 10-6
pOH = 5.4 — use –log \[OH–\] to find pOH
pH = 14– pOH = 8.6
\[OH-\] = 4 X 10-6
pOH = 5.4 — use –log \[OH–\] to find pOH
pH = 14– pOH = 8.6
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Which of the following will produce the solution with the lowest pH?
Which of the following will produce the solution with the lowest pH?
NaOH is a base, so that won't produce an acidic solution. Of the remaining acids, HCl and HI are strong acids, and HF is weak. HI is at a higher molarity, so it will produce the most acidic solution.
NaOH is a base, so that won't produce an acidic solution. Of the remaining acids, HCl and HI are strong acids, and HF is weak. HI is at a higher molarity, so it will produce the most acidic solution.
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What is the pH of a soution containing .0001 M HCl?
What is the pH of a soution containing .0001 M HCl?
The pH of a solution is determined by taking the negative log of the concentration of hydrogen ions in solution. HCl is strong acid so it completely dissociates in solution. So adding .0001 M HCl is the same as saying that 1 *10-4 moles of H+ ions have been added to solution. The -log\[.0001\] =4, so the pH of the solution =4.
The pH of a solution is determined by taking the negative log of the concentration of hydrogen ions in solution. HCl is strong acid so it completely dissociates in solution. So adding .0001 M HCl is the same as saying that 1 *10-4 moles of H+ ions have been added to solution. The -log\[.0001\] =4, so the pH of the solution =4.
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What is the pOH of a solution that has a \[H+\] = 3.2 X 10-7 mol?
What is the pOH of a solution that has a \[H+\] = 3.2 X 10-7 mol?
\[H+\] = 3.2 X 10-7 mol
pH = -log \[H+\]
= 7 - log 3.2
= 7 -.505
=6.495
pOH = 14 - pH
= 7.5
\[H+\] = 3.2 X 10-7 mol
pH = -log \[H+\]
= 7 - log 3.2
= 7 -.505
=6.495
pOH = 14 - pH
= 7.5
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Which of the following solutions contains the greatest number of H+ ions?
Which of the following solutions contains the greatest number of H+ ions?
This question asks for the solution with the greatest number H+ ions, we can also approach this problem as if we are looking for the solution with the lowest pH. HCl is strong acid, therefore it will dissociate completely in solution. So the solution containing 0.010 mL of HCL contains 0.010 mL of H+ ions in solution, in addition to the H+ ions that are already in solution due to the auto-ionization of water. The only other solution that could have a pH less than 7 would be the one with 0.010 mL of CH3OH in excess water, becasue CH3OH is very slightly acidic. But since it is compared with an equal volume of HCl which is strong acid, it can be said that the most H+ ions will be found in the solution containing a small amount of strong acid, HCl.
This question asks for the solution with the greatest number H+ ions, we can also approach this problem as if we are looking for the solution with the lowest pH. HCl is strong acid, therefore it will dissociate completely in solution. So the solution containing 0.010 mL of HCL contains 0.010 mL of H+ ions in solution, in addition to the H+ ions that are already in solution due to the auto-ionization of water. The only other solution that could have a pH less than 7 would be the one with 0.010 mL of CH3OH in excess water, becasue CH3OH is very slightly acidic. But since it is compared with an equal volume of HCl which is strong acid, it can be said that the most H+ ions will be found in the solution containing a small amount of strong acid, HCl.
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What is the approximate pH of a 1.0 M solution of soluble CaCO3?
What is the approximate pH of a 1.0 M solution of soluble CaCO3?
Calcium carbonate is a base since it's the salt of a strong base (NaOH) and a weak acid (carbonic acid). The only basic pH on the list is 8, making it the correct answer.
Calcium carbonate is a base since it's the salt of a strong base (NaOH) and a weak acid (carbonic acid). The only basic pH on the list is 8, making it the correct answer.
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What is the pH of a 1 * 10–3M solution of H2CO3 acid? (pKa is 6.4)
What is the pH of a 1 * 10–3M solution of H2CO3 acid? (pKa is 6.4)
The –log of the pKa will give you the Ka, so take the –log (6.4), which gives you approximately 4 * 10–7. The Ka expression is set up with products over reactants (hydrogen carbonate ion * hydrogen ion/carbonic acid). The undissociated carbonic acid is 0.001M, and you should use the variable 'x' to account for how much it dissociates and how many of the ions are produced. Ka = 4 * 10–7 = x2/0.001 ends up being your Ka expression, if you assume x is negligible compared to the original concentration of 0.001. Solving for x, you get 2 * 10–5. This is the hydrogen ion concentration. pH = –log (hydrogen ion concentration), so pH = –long(2 * 10–5), which is approximately 4.7.
The –log of the pKa will give you the Ka, so take the –log (6.4), which gives you approximately 4 * 10–7. The Ka expression is set up with products over reactants (hydrogen carbonate ion * hydrogen ion/carbonic acid). The undissociated carbonic acid is 0.001M, and you should use the variable 'x' to account for how much it dissociates and how many of the ions are produced. Ka = 4 * 10–7 = x2/0.001 ends up being your Ka expression, if you assume x is negligible compared to the original concentration of 0.001. Solving for x, you get 2 * 10–5. This is the hydrogen ion concentration. pH = –log (hydrogen ion concentration), so pH = –long(2 * 10–5), which is approximately 4.7.
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If the Ksp of Mg(OH)2 is 1.2 * 10–11 and the magnesium ion concentration is 1.2 * 10–5M, at what pH does the Mg(OH)2 compound begin to precipitate?
If the Ksp of Mg(OH)2 is 1.2 * 10–11 and the magnesium ion concentration is 1.2 * 10–5M, at what pH does the Mg(OH)2 compound begin to precipitate?
The expression for Ksp is Ksp = \[Mg2+\]\[OH–\]2.
Thus, \[OH–\] = √(1.2 * 10–11)/(1.2 * 10–5)
\[OH–\] = 1 * 10–3
Thus, pH = –log(1 X 10–3) = 3
pH = 14 – 3 = 11
The expression for Ksp is Ksp = \[Mg2+\]\[OH–\]2.
Thus, \[OH–\] = √(1.2 * 10–11)/(1.2 * 10–5)
\[OH–\] = 1 * 10–3
Thus, pH = –log(1 X 10–3) = 3
pH = 14 – 3 = 11
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What is the range of possible hydrogen ion concentrations in acidic solution?
What is the range of possible hydrogen ion concentrations in acidic solution?
For a solution to be acidic, it must have a pH between 1 and 6.99, since 7 is neutral; pH is –log(hydrogen ion concentration), the range of possible values is between 10–1 and 10–6.999.
For a solution to be acidic, it must have a pH between 1 and 6.99, since 7 is neutral; pH is –log(hydrogen ion concentration), the range of possible values is between 10–1 and 10–6.999.
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What is the range of possible hydrogen ion concentrations in basic solution?
What is the range of possible hydrogen ion concentrations in basic solution?
For a solution to be basic, it must have a pH between 8 and 14, since 7 is neutral; pH is –log(hydrogen ion concentration); the range of possible values is between 10–13 and 10–7.001.
For a solution to be basic, it must have a pH between 8 and 14, since 7 is neutral; pH is –log(hydrogen ion concentration); the range of possible values is between 10–13 and 10–7.001.
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What is the pH of a 0.05M solution of hydroflouric acid?
What is the pH of a 0.05M solution of hydroflouric acid?
The Ka = \[H+\]\[F–\]/\[HF\]. The beginning concentration of HF is given as 0.05, and we can use x as the variable that accounts for how much of the HF is lost, along with how much of the H+ and F– are formed.
Thus, Ka = _x_2/.05 if you use the approximation that x is negligible compared to the starting concentration of HF.
Solving for x, x = 1 * 10–3. This is the H+ ion concentration.
pH = –log(H+) = –log(1.0 * 10–3)) = 3
The Ka = \[H+\]\[F–\]/\[HF\]. The beginning concentration of HF is given as 0.05, and we can use x as the variable that accounts for how much of the HF is lost, along with how much of the H+ and F– are formed.
Thus, Ka = _x_2/.05 if you use the approximation that x is negligible compared to the starting concentration of HF.
Solving for x, x = 1 * 10–3. This is the H+ ion concentration.
pH = –log(H+) = –log(1.0 * 10–3)) = 3
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A chemist adds 625g of solid 
to 500mL of 16M 
. What is the pH of the solution after it reaches equilibrium?
A chemist adds 625g of solid
Consider the reaction of 
and 
:
Now we will calculate the moles of 
in the solution prior to adding base.
We will then calculate the amount of moles of 
that react with the base.
We will then calculate the remaining moles of 
:
We will then calculate the new concentration of sulfuric acid:
Sulfuric acid is a diprotic acid, so the hydrogen ion concentration is 0.76 M.
![pH=-log[H^{+}]=-log(0.76)=0.12](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/20061/gif.latex)
Consider the reaction of
Now we will calculate the moles of
We will then calculate the amount of moles of
We will then calculate the remaining moles of
We will then calculate the new concentration of sulfuric acid:
Sulfuric acid is a diprotic acid, so the hydrogen ion concentration is 0.76 M.
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A chemist adds 
to 
mL of water. What is the pH of the solution?
A chemist adds 
First, we will calculate ![[KOH]](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21614/gif.latex)
as follows:
Now we will calculate the pOH:
![pOH=-log[OH^-]](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21616/gif.latex)
In solution 
, so ![[KOH]=[OH^-]](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21618/gif.latex)
.
![pOH=-log[1.497\times 10^{-1}]=8.248\times 10^{-1}](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21619/gif.latex)
First, we will calculate
Now we will calculate the pOH:
In solution
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A chemist boils off the water from 627 mL of a solution with a pH of 10.2. The only dissolved compound in the solution is 
. How much solid remains?
A chemist boils off the water from 627 mL of a solution with a pH of 10.2. The only dissolved compound in the solution is
The pH of the solution is 10.2, and we know:
![pOH=-log[OH^-]](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21966/gif.latex)
![3.8=-log[OH^-]](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21967/gif.latex)
![-3.8=log[OH^-]](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21968/gif.latex)
![[OH^-]=10^{-3.8}=1.58\times 10^{-4}](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21969/gif.latex)
And since 
, ![[NaOH]=1.58\times 10^{-4}](https://vt-vtwa-assets.varsitytutors.com/vt-vtwa/uploads/formula_image/image/21971/gif.latex)
.
The pH of the solution is 10.2, and we know:
And since
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A chemist adds 10mL of a solution with a pH of 3.00 to 50mL of water. What is the pH of the new solution?
A chemist adds 10mL of a solution with a pH of 3.00 to 50mL of water. What is the pH of the new solution?
First, we will determine the amount of hydronium ions in the first solution. This allows us to measure the moles of hydronium ion that are transferred to water.
Now we can calculate the hydronium ion concentration in the new solution, using the amount transferred and the volume of water, and can solve for pH.
First, we will determine the amount of hydronium ions in the first solution. This allows us to measure the moles of hydronium ion that are transferred to water.
Now we can calculate the hydronium ion concentration in the new solution, using the amount transferred and the volume of water, and can solve for pH.
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A chemist mixes 
of a 
solution with 
of a 
solution. Assuming the two solutions are additive, what is the pH of the resulting solution?
A chemist mixes
To find the pH of the solution after mixing the individual components, one first has to determine the final hydroxide concentration, \[-OH\].
(Remember that 1 mole of Ba(OH)2 will give 2 moles of \[-OH\]).
To find the pH of the solution after mixing the individual components, one first has to determine the final hydroxide concentration, \[-OH\].
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Which two solutions, when combined in equal amounts, will produce the lowest pH?
Which two solutions, when combined in equal amounts, will produce the lowest pH?
HCl is a strong acid, while NaCl is a salt. Mixing these two will result in a pH < 1.
As for the other choices, mixing 2.0M HCl and 2.0M KOH will result in the formation of KCl and H2O, resulting in a neutral pH. Acetic acid (pKa= 4.76) is a weak acid, so it will have a pH less than 7 but greater than 1. Finally, NH3 and NH4+ is a buffer system between a weak base and weak acid, and if equal amounts are present, the pH will be the same as the pKa of NH4+, which is around 9.
HCl is a strong acid, while NaCl is a salt. Mixing these two will result in a pH < 1.
As for the other choices, mixing 2.0M HCl and 2.0M KOH will result in the formation of KCl and H2O, resulting in a neutral pH. Acetic acid (pKa= 4.76) is a weak acid, so it will have a pH less than 7 but greater than 1. Finally, NH3 and NH4+ is a buffer system between a weak base and weak acid, and if equal amounts are present, the pH will be the same as the pKa of NH4+, which is around 9.
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1mol of hydrobromic acid (HBr) is added to water, resulting in 1L of solution. Worried that the acid is too strong, a professor adds more water, increasing the volume of solution to 2L.
What was the pH of the solution before adding water? What was the pH after adding the water?
1mol of hydrobromic acid (HBr) is added to water, resulting in 1L of solution. Worried that the acid is too strong, a professor adds more water, increasing the volume of solution to 2L.
What was the pH of the solution before adding water? What was the pH after adding the water?
The pH of a solution is given by the equation 
.
- We can assume that hydrobromic acid, as a strong acid, will dissociate completely. As a result, there will be 1mol of protons in the initial solution. Molarity is a method of measuring the concentration of an agent in a solution and is defined by the equation below.
Since we have 1mol of protons and 1L of solution, the molarity of protons is simply 1M in the initial solution (1mol/1L). We can plug this into the pH equation and solve.
- After the dilution with water, the concentration of protons will change. Since the volume of the solution has doubled, the concentration of protons has been halved.
* Key points to remember!
-
The lower the pH, the more acidic the solution. This is why the diluted solution was 0.3 and the original, more acidic solution was 0.
-
pH is a logarithmic scale. As a result, a pH of 2 is ten times more acidic than a pH of 3. This is why halving the concentration DID NOT halve the pH.
The pH of a solution is given by the equation
- We can assume that hydrobromic acid, as a strong acid, will dissociate completely. As a result, there will be 1mol of protons in the initial solution. Molarity is a method of measuring the concentration of an agent in a solution and is defined by the equation below.
Since we have 1mol of protons and 1L of solution, the molarity of protons is simply 1M in the initial solution (1mol/1L). We can plug this into the pH equation and solve.
- After the dilution with water, the concentration of protons will change. Since the volume of the solution has doubled, the concentration of protons has been halved.
* Key points to remember!
-
The lower the pH, the more acidic the solution. This is why the diluted solution was 0.3 and the original, more acidic solution was 0.
-
pH is a logarithmic scale. As a result, a pH of 2 is ten times more acidic than a pH of 3. This is why halving the concentration DID NOT halve the pH.
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What is the pH of a solution if you dilute 10mL of a 0.56M NaOH solution into 100mL of water?
What is the pH of a solution if you dilute 10mL of a 0.56M NaOH solution into 100mL of water?
We first need to calculate the moles of NaOH in 10mL of a 0.56M solution.
Now, in the new volume, the concentration is equal to this same number of moles divided by the new volume. The new volume is the sum of the two solutes together, so the sum of 10mL of solution and 100mL of water.
Now we need to calculate pH. Since NaOH will dissociate one hydroxide ion for every molecule of NaOH in solution, the concentration of hydroxide is equal to the concentration of NaOH.
Knowing the pH allows us to solve for the pH.
We first need to calculate the moles of NaOH in 10mL of a 0.56M solution.
Now, in the new volume, the concentration is equal to this same number of moles divided by the new volume. The new volume is the sum of the two solutes together, so the sum of 10mL of solution and 100mL of water.
Now we need to calculate pH. Since NaOH will dissociate one hydroxide ion for every molecule of NaOH in solution, the concentration of hydroxide is equal to the concentration of NaOH.
Knowing the pH allows us to solve for the pH.
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