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AP Chemistry DBQ/Free Response. Perform the following calculations.
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AP Chemistry DBQ/Free Response. Perform the following calculations.
Transcript
- 00:04
Here's your shmoop du jour, brought to you by balloons. Aside from being kicked in a
- 00:08
sensitive area, they're still the number one way to talk in a high-pitched voice.
- 00:15
A party is thrown with balloons. The balloon salesman tells the party planners that he
- 00:19
is out of helium cylinders, but he has a stock of other gases: hydrogen, argon, and chlorine.
- 00:26
The party planners see an unlabeled gas cylinder in the back of the store. They are curious
Full Transcript
- 00:30
as to which gas it is. They fill a balloon to 1 liter and weigh it.
- 00:35
NOTE: We do NOT recommend filling balloons with random, unlabeled gas. These guys are
- 00:40
professional idiots...do not try this at home... Anyway, after subtracting the weight of the
- 00:45
balloon, they find that the weight of the gas in the balloon is 0.819 grams
- 00:50
It is 27 degrees Celsius outside with standard atmospheric pressure. Assume ideal behavior
- 00:57
for all gases. Air has a density of 1.161 grams per Liter under these conditions.
- 01:03
So for Part A, we need to perform the following calculations:
- 01:07
1 - Calculate the density in grams per Liter of hydrogen.
- 01:11
2 - Calculate the density in grams per Liter of argon.
- 01:14
3 - Calculate the density in grams per Liter of chlorine.
- 01:21
First things first: Calculate the density in grams per liter of hydrogen.
- 01:25
Okay, so this problem mentions that we're working with gases, and that we can assume
- 01:29
ideal behavior for all gases. So...we can assume that none of them is going
- 01:33
to be resting their elbows on the dinner table. We should automatically be thinking about
- 01:38
the ideal gas law... PV equals nRT. This law allows us to find certain properties
- 01:44
about an ideal gas...where p equals pressure, v equals volume in liters, n equals number
- 01:50
of moles, R is the ideal gas constant, and T is temperature in Kelvin.
- 01:58
What's an ideal gas, you might ask? It's a hypothetical gas in which atoms are perfectly
- 02:03
elastic and there are no intermolecular attractive forces between molecules. They're all...VERY
- 02:09
attracted to each other. But back to solving the problem.
- 02:14
Ok, so we're given standard atmospheric pressure, which means that P equals 1 atmosphere, the
- 02:20
gas constant R equals .0821, and the temperature equals 27 degrees Celsius.
- 02:27
But we have to convert temperature to Kelvin...
- 02:29
and to do so, we can add 273 to 27...to get 300 Kelvin.
- 02:35
Plugging all these numbers into the equation,
- 02:37
we find that V equals n times .0821 times 300. But that doesn't look anything like density,
- 02:44
which is in units: grams per liter. So what else do we know about hydrogen gas
- 02:49
that can help us? It's molecular weight -- bingo.
- 02:53
We can calculate the molecular weight of hydrogen gas, which is 2 times the weight of two hydrogen
- 02:58
atoms, using the periodic table. This equals 2.106 grams per mole.
- 03:04
Using dimensional analysis, to convert grams per mole into grams per liter, we know that
- 03:08
we have to have moles on the top, and liters on the bottom, which is equivalent to n over V.
- 03:16
Now we know what to do with our ideal gas
- 03:18
law equation. N over V equals 1 over .0821 times 300, or .0406 moles per Liter.
- 03:30
Multiplying this by the molecular weight of hydrogen gas, we can convert our value into density.
- 03:36
So we have .0406 moles per liter times 2.106 grams per
- 03:40
mole equals .0855 grams per liter. But we can't forget about significant figures
- 03:47
either! All the numbers we're given in the problem have three sig figs, so our answer
- 03:52
should have three as well. So great.
- 03:56
Now we just need to do the same thing
- 03:57
for the other 2 calculations... Let's find ourselves the density of argon.
- 04:02
Because we are assuming ideal gas behavior, this calculation will be the same as the calculation
- 04:06
in part 1 to obtain the value for n over v... ... .0406 moles per liter.
- 04:12
For ideal gases, this value is independent of the identity of the gas.
- 04:16
We use the molecular weight of argon -- 39.948 grams per mole...which we can find from the
- 04:22
periodic table again....to convert this value to density.
- 04:26
0.0406 moles per liter times 39.948 grams per mole equal 1.62 grams per liter.
- 04:35
Okay, and now for the density of chlorine. Same deal, but this time we use the molecular
- 04:39
weight of chlorine - 70.905 grams per mole. We can multiply .0406 times 70.905 to get
- 04:47
2.88 grams per liter.
- 04:52
OK...Now for part B of this question...
- 04:55
Assuming the party planners want their balloons to float, which of the three listed gases
- 04:59
should they purchase? Justify your answer.
- 05:04
Well, if we ever want something to float in
- 05:06
another, we need the thing we want to float to have a LOWER density than the other.
- 05:14
Since air has a density of 1.161 grams per Liter, as given in the problem...we want the
- 05:19
gas that has a density less than that....
- 05:21
Hydrogen has a density of 0.0855 grams per Liter, so that's our answer!
- 05:31
Time for Part C...
- 05:33
Let's take question 1 first... what is the molecular weight and the identity of the gas
- 05:37
in the unlabeled cylinder, assuming it is monatomic and acts as an ideal gas?
- 05:44
Ok...so this question is asking us to figure out the molecular weight and identity of the
- 05:48
unknown gas. We're given that the weight of the gas in the balloon is 0.819 grams.
- 05:53
But molecular weight is in the unit: grams per mole...so all we have to do is figure
- 05:57
out the number of moles, using the ideal gas law again, PV equals nRT.
- 06:03
Rearranging the equation to find moles, n equals PV divided by RT.
- 06:10
We have all the information we need to solve: standard pressure -- P equals 1 atmosphere...
- 06:16
volume -- V equals 1 Liter, gas constant -- (R = 0.0821 liters atmospheres over moles times
- 06:24
Kelvin), and temperature -- T equals 300 Kelvin.
- 06:28
We plug in the numbers and solve for n:
- 06:30
1 times 1 over .0821 times 300 equals .0406 moles.
- 06:38
So the molecular weight is grams per mole.... .819 grams divided by .0406 moles equals 20.2
- 06:44
grams per mole. Looking at the periodic table, the element
- 06:47
with that molecular weight is Neon.
- 06:51
Now the question wants to know...will it float?
- 06:54
Well, like part B of this question, the key to figuring out if a gas will float is if
- 06:59
it is less than the density of air. The density of neon is in grams per liter...so
- 07:06
.819 grams divided by 1 liter is .819 grams per liter.
- 07:11
0.819 grams per liter is less than 1.161 grams per liter...so yeah, it totally floats!
- 07:20
Finally... Part D... Question 1 of part D... Write the balanced,
- 07:25
net ionic equation for the reaction that occurs when chlorine gas is bubbled into a solution
- 07:30
of sodium bromide. Alright, to be honest, we know this question
- 07:33
is kinda unrelated to the rest of the problem. But sometimes the test makers are like that,
- 07:37
and we just have to... deal with it. So to find the net ionic equation, we first have to start
- 07:41
with the balanced molecular equation. Chlorine gas into sodium bromide...chlorine
- 07:46
gas is a diatomic molecule, so we have Cl2. The formula for sodium bromide is NaBr.
- 07:55
This is an example of a single displacement chemical equation...so the chlorine replaces
- 07:59
the bromide to make sodium chloride gas and bromine gas...which is a diatomic molecule.
- 08:06
So we have two bromine atoms, not just one. To balance this equation, we can add a 2 in
- 08:11
front of the sodium bromide and 2 in front of the NaCl.
- 08:16
To find the net ionic equation, we have to break all the soluble electrolytes into their
- 08:21
ions... ...which means the sodium ions on both sides
- 08:24
need to be taken out of their salts.
- 08:28
Just like a normal math equation, we can cancel
- 08:30
out the two sodium ions on the left and right...and we're left with chlorine gas plus 2 bromide
- 08:35
ions, which makes bromine gas and 2 chlorine ions.
- 08:40
Number 2 in part D. Last question...asks us which species is oxidized in the equation.
- 08:48
Well, oxidation occurs when an element becomes positive because they are LOSING electrons.
- 08:53
Good for them. We don't become positive when we lose ANYTHING.
- 08:58
If we look at our net ionic equation, the bromide ions are being oxidized because, on
- 09:02
the left, they have a negative charge, but then after the ions react with the chlorine
- 09:06
gas, they have no charge. They are becoming more positive, or being oxidized!
- 09:11
Phew. So thanks for hanging in there with us for that one. It was a beast.
- 09:15
Hello? Oh...don't tell us we have to say all that all over again...
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