Calculations - AP Chemistry

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Question

$Zn_{(s)}+2HCl_{(aq)}\rightarrow ZnCl_{2}_{(aq)}+H_{2}_{(g)}$

3.2 g Zn and 8.1 g HCl are placed in an open beaker. As the reaction proceeds, the hydrogen gas is allowed to escape, causing the reaction to go to completion.

Which reactant (if either) is in excess, and how many grams of it remain?

Answer

First calculate the number of mols of each reactant:

$\frac{3.2 :g :Zn}{65.38:\frac{g :Zn}{mol :Zn}} = 0.048945 :mol :Zn$

$\frac{8.1 :g :HCl}{36.45:\frac{g :HCl}{mol :HCl}}=0.2222 :mol :HCl$

The ratio of to is 1:2. So, given that we have 0.048945 mol , we only need 0.09789 mol . Since we have more than is needed, is in excess. How much is in excess?

Now convert mols of to grams:

$0.12431:mol :HCl*36.45:\frac{g :HCl}{mol :HCl} = 4.53 :g :HCl$

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Question

25 mL of water at room temperature is vaporized and heated to 515 degrees Celsius in an open system.

$R=0.08206: \frac{L\cdot atm}{mol\cdot K}$

What will the volume of the resulting gas be? Round your answer to the nearest liter.

Answer

The system is open, so the pressure can be assumed atmospheric, e.g. 1 atm.

Using the ideal gas law,

$V=\frac{nRT}{P}$

We need to convert to kelvin.

$T=515^{\circ}C+273.15 = 788.15 :K$

The density of water at room temperature is approximately 1 g/mL, so we have 25 g of water. Convert to mols:

$n=\frac{25:g}{18:\frac{g}{mol}}=1.389 :mol$

Plugging everything in:

$V=\frac{1.389:mol788.15:K0.08206:\frac{L\cdot atm}{mol\cdot K}}{1:atm}=89.83:L \rightarrow90:L$

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Question

A cylindrical metal wire, initially at 100 degrees Celsius, is immersed into a bomb calorimeter containing 100 mL of water at 25 degrees Celsius. After some time, the temperature of the system is homogenous at 35 degrees Celsius.

The wire is 135 cm long with a diameter of 0.1 cm.

$C_{p,water}=4.18:\frac{J}{g^{\circ}C}$

$\rho_{metal}=2.5:\frac{g}{mL}$

What is the heat capacity of the metal? Round your answer to the nearest $\frac{J}{g^{\circ}C}$ .

Answer

First we need to calculate the mass of the wire. We will do this by calculating its volume then multiplying by the density.

$m=\rho V=\rho \pi r^{2}l =2.5:\frac{g}{mL}(0.05:cm)^{2}135:cm =2.651:g$

Next we need to find out how much energy the water gained from the metal wire.

$Q=mC_{p}\Delta T=(100:g)(4.18:\frac{J}{g^{\circ}C})(25^{\circ}C-35^{\circ}C)=-4180:J$

The energy the water gained is equal to the energy the wire lost. This allows us to calculate the heat capacity for the metal:

$4180:J = 2.6507:g*C_{p,metal}(100^{\circ}C-35^{\circ}C)$

$C_{p,metal}=24.26:\frac{J}{g^{\circ}C}\rightarrow 24:\frac{J}{g^{\circ}C}$

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Question

A chemistry student is trying to determine the identity of an unknown gas. If the gas has a molar mass of $120\frac{g}{mol}$ at $50^{o}C$ and , what is the density of this unknown gas under these conditions?

Answer

We are given the pressure, temperature, and molar mass of the gas in the question stem and are asked to determine the density. To do this, we will need to make use of a manipulated form of the ideal gas equation.

To find density, we will need a way to relate the variables given in the question stem to other parameters, namely mass and volume. Since we already have the volume, , contained in the ideal gas equation, we just need a way to find the mass, . We can do this by noting that the number of moles, , can also be written as the mass divided by the molar mass, $\frac{m}{MM}$ . Substituting this in gives us:

$PV = \left ( \frac{m}{MM} \right )RT$

And rearranging, we obtain the density:

$\frac{m}{V}=\frac{P\left ( MM \right )}{RT}=\rho$

But we're not done yet! Remember, we also have to convert the units given for pressure and temperature in the question stem into their proper form. Since we need pressure in terms of atmospheres, and there are in of gas, we can find that:

$1140mmHg\left ( \frac{1atm}{760mmHg} \right )=1.5atm$

Furthermore, we need to convert degrees Celsius into Kelvins.

$50^{o}C+273=323: K$

Now that we have all the units in their correct form, we're finally ready to plug our values into the equation for density:

$\rho=\frac{P\left ( MM \right )}{RT}=\frac{\left ( 1.5atm \right )\left ( 120\frac{g}{mol} \right )}{\left ( 0.08206 \right \frac{L\cdot atm}{mol\cdot K})\left ( 323K \right )}=6.79\frac{g}{L}$

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Question

The hospital carries 0.9% $\left(\frac{w}{v}\right)$ solution of sodium chloride in purified $\small H_{2}O$ . The professor asked his student to prepare 500mL of 0.45% percent $\left(\frac{w}{v}\right)$ solution sodium chloride in purified $\small H_{2}O$ . What volumes of the original solution and purified , respectively, are needed to make the new solution?

Answer

This is a typical dilution problem. The first step is to recognize that this is a dilution question. Whenever figuring out how to go from a higher concentrated solution to a lower concentrated solution, it is a dilution problem. The main equation to use here is:

$\small (Concentration_{1})$ $\small (Volume_{1})$ $\small = (Concentration_{2})(Volume_{2})$

or

$C_{1}V_{1} = C_{2}V_{2}$

or

$\small M_{1}V_{1}=M_{2}V_{2}$

When plugging in the numbers, make sure to assign the correct volumes and concentrations. Think of one side of the equation describing the 0.9% $\left(\frac{w}{v}\right)$ solution of sodium chloride and the other side describing the 0.45% solution of sodium chloride.

$0.45\cdot500=0.9\cdot V_2$

$\small V_{2}$ is the amount of the original solution needed to make the new 0.45% solution. However, we need to add water to the solution to dilute it. To find how much water is needed, subtract:

$\small 500mL - 250mL=250mL$ of water.

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Question

How many significant figures does the number 42,000,000 have?

Answer

42,000,000 has two significant figures because of the rule that states that trailing zeroes are never significant unless there is a decimal point. For example, if the number given was "42,000,000." it would be eight significant figures.

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Question

Write the number 42,000,000 in scientific notation using the correct number of significant figures.

Answer

The correct answer is . This is found by moving the decimal place to the left 7 times in order to get one digit to the left of the decimal, and the rest of the digits to the right. The answer just has two significant figures because that is the number of significant figures in the original number.

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Question

Convert the number into standard notation, with the correct number of significant figures.

Answer

To convert into standard notation we must move the decimal two places to the right because of the exponent of "2" above the 10. Then we re-write the number with the decimal in the new space. All of the digits that were in the original scientific notation must be accounted for. Thus, our answer must have six significant figures.

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Question

Solve. Account for significant figures.

Calculate using the correct number of significant figures:

Answer

The answer is 500 because our rules of significant figures state that when two numbers are multiplied our answer can only have as many significant figures as our number with the fewest significant figures. In this case 5.02 has three significant figures, but 100 only has 1 significant figure. Therefore our answer can only have 1 significant figure.

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Question

Solve and account for significant figures.

Calculate using the correct number of significant figures:

Answer

The answer is 13.18 because the rules for adding and subtracting significant figures state that the answer can only be precise up to the least precise digit from the numbers that were added/subtracted. In this case 2.12 is only precise to the hundredth place, and therefore our answer can only go to the hundredth place.

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Question

Find the volume that of carbon dioxide will occupy if it's density is $1.75 \frac{g}{mL}$ .

Answer

Remember: $D = \frac{m}{V}$

Rearrange the equation to solve for volume:

$V = \frac{m}{D}$

Plug in the values given in the problem:

$V = \frac{36.9g}{(1.75 \frac{g}{mL})} = 21.0857 mL$

However, we must take into account significant figures. Because both our given values have 3 significant figures, our answer must have 3 significant figures.

Therefore after rounding the correct answer is:

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Question

Working in the laboratory, a student finds the density of pure aluminum to be $2.850 \frac{g}{cm^3}$ . The accepted value for the density of aluminum is $2.699 \frac{g}{cm^3}$ . What was the student's percent error?

Answer

To find the percent error, the formula is:

$\text{percent error} = \frac{|\text{accepted value - experimental value}|}{(\text{accepted value})} * 100$

Therefore we plug in the values given:

$\frac{|2.699 - 2.850|}{(2.699)} * 100 = 5.595%$

Therefore, the correct answer including significant figures is

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Question

A student experimentally determines the specific heat of water to be $4.25 \frac{J}{gK}$ . He then looks up the accepted value and finds that it is $4.18 \frac{J}{gK}$ . What was the student's percent error?

Answer

The formula for percent error is:

$\text{percent error} = \frac{|\text{accepted value - experimental value}|}{(\text{accepted value})} * 100$

Plug in the given values and solve:

$\frac{|4.18 - 4.25|}{(4.18)} * 100 = 1.67%$

Therefore, after accounting for significant figures the correct answer is

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Question

The table shows the data obtained by three groups when finding the boiling point of methanol. The accepted value is $78.5^\circ C$ . Is group A precise, accurate or both?

Answer

Group A's values are precise because the data values are all close to each other, but it is not accurate because it none of them is near the accepted value.

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Question

The table shows the data obtained by three groups when attempting to find the boiling point of methanol. The accepted value is $78.5^\circ C$ . Is group C precise, accurate, both, or neither?

Answer

Group C is precise because all of their values are close to one another. Their data is also accurate because their values are all near the accepted value. Therefore group C is both accurate and precise.

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Question

Place the following metric prefixes in order from smallest to largest:

k, M, m, n

Answer

Remember the saying "King Henry Died by Drinking Chocolate Milk". This is referencing the order of metric prefixes: kilo, hecto, deca, deci, centi, milli. Or in their abbreviations: k, h, da, d, c, m.

You also need to know nano (n) which is $10^{-9}$ .

The final one you need to know for this question is Mega (M) which is .

Therefore the correct answer is: n, m, k, M (nano, milli, kilo, Mega).

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Question

$Zn_{(s)}+2HCl_{(aq)}\rightarrow ZnCl_{2}_{(aq)}+H_{2}_{(g)}$

3.2 g Zn and 8.1 g HCl are placed in an open beaker. As the reaction proceeds, the hydrogen gas is allowed to escape, causing the reaction to go to completion.

Which reactant (if either) is in excess, and how many grams of it remain?

Answer

First calculate the number of mols of each reactant:

$\frac{3.2 :g :Zn}{65.38:\frac{g :Zn}{mol :Zn}} = 0.048945 :mol :Zn$

$\frac{8.1 :g :HCl}{36.45:\frac{g :HCl}{mol :HCl}}=0.2222 :mol :HCl$

The ratio of to is 1:2. So, given that we have 0.048945 mol , we only need 0.09789 mol . Since we have more than is needed, is in excess. How much is in excess?

Now convert mols of to grams:

$0.12431:mol :HCl*36.45:\frac{g :HCl}{mol :HCl} = 4.53 :g :HCl$

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Question

25 mL of water at room temperature is vaporized and heated to 515 degrees Celsius in an open system.

$R=0.08206: \frac{L\cdot atm}{mol\cdot K}$

What will the volume of the resulting gas be? Round your answer to the nearest liter.

Answer

The system is open, so the pressure can be assumed atmospheric, e.g. 1 atm.

Using the ideal gas law,

$V=\frac{nRT}{P}$

We need to convert to kelvin.

$T=515^{\circ}C+273.15 = 788.15 :K$

The density of water at room temperature is approximately 1 g/mL, so we have 25 g of water. Convert to mols:

$n=\frac{25:g}{18:\frac{g}{mol}}=1.389 :mol$

Plugging everything in:

$V=\frac{1.389:mol788.15:K0.08206:\frac{L\cdot atm}{mol\cdot K}}{1:atm}=89.83:L \rightarrow90:L$

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Question

A cylindrical metal wire, initially at 100 degrees Celsius, is immersed into a bomb calorimeter containing 100 mL of water at 25 degrees Celsius. After some time, the temperature of the system is homogenous at 35 degrees Celsius.

The wire is 135 cm long with a diameter of 0.1 cm.

$C_{p,water}=4.18:\frac{J}{g^{\circ}C}$

$\rho_{metal}=2.5:\frac{g}{mL}$

What is the heat capacity of the metal? Round your answer to the nearest $\frac{J}{g^{\circ}C}$ .

Answer

First we need to calculate the mass of the wire. We will do this by calculating its volume then multiplying by the density.

$m=\rho V=\rho \pi r^{2}l =2.5:\frac{g}{mL}(0.05:cm)^{2}135:cm =2.651:g$

Next we need to find out how much energy the water gained from the metal wire.

$Q=mC_{p}\Delta T=(100:g)(4.18:\frac{J}{g^{\circ}C})(25^{\circ}C-35^{\circ}C)=-4180:J$

The energy the water gained is equal to the energy the wire lost. This allows us to calculate the heat capacity for the metal:

$4180:J = 2.6507:g*C_{p,metal}(100^{\circ}C-35^{\circ}C)$

$C_{p,metal}=24.26:\frac{J}{g^{\circ}C}\rightarrow 24:\frac{J}{g^{\circ}C}$

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Question

A chemistry student is trying to determine the identity of an unknown gas. If the gas has a molar mass of $120\frac{g}{mol}$ at $50^{o}C$ and , what is the density of this unknown gas under these conditions?

Answer

We are given the pressure, temperature, and molar mass of the gas in the question stem and are asked to determine the density. To do this, we will need to make use of a manipulated form of the ideal gas equation.

To find density, we will need a way to relate the variables given in the question stem to other parameters, namely mass and volume. Since we already have the volume, , contained in the ideal gas equation, we just need a way to find the mass, . We can do this by noting that the number of moles, , can also be written as the mass divided by the molar mass, $\frac{m}{MM}$ . Substituting this in gives us:

$PV = \left ( \frac{m}{MM} \right )RT$

And rearranging, we obtain the density:

$\frac{m}{V}=\frac{P\left ( MM \right )}{RT}=\rho$

But we're not done yet! Remember, we also have to convert the units given for pressure and temperature in the question stem into their proper form. Since we need pressure in terms of atmospheres, and there are in of gas, we can find that:

$1140mmHg\left ( \frac{1atm}{760mmHg} \right )=1.5atm$

Furthermore, we need to convert degrees Celsius into Kelvins.

$50^{o}C+273=323: K$

Now that we have all the units in their correct form, we're finally ready to plug our values into the equation for density:

$\rho=\frac{P\left ( MM \right )}{RT}=\frac{\left ( 1.5atm \right )\left ( 120\frac{g}{mol} \right )}{\left ( 0.08206 \right \frac{L\cdot atm}{mol\cdot K})\left ( 323K \right )}=6.79\frac{g}{L}$

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