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AP Chemistry 2.1 Rearrangements and Reorganization of Atoms. What is the percent yield for this reaction?
Transcript
- 00:04
Here’s your Shmoop du jour, brought to you by decaffeinated coffee, also known as a cruel, [Man drinks decaf coffee]
- 00:09
cruel joke.
- 00:10
Here’s today’s question:
- 00:12
In the early 1900s, scientist Ludwig Roselius popularized the use of benzene (C6H6) to decaffeinate
- 00:21
coffee, which led to the production of Sanka®.
Full Transcript
- 00:24
Although this process is no longer used today, as, benzene is carcinogenic, this compound
- 00:30
has many other important industrial uses.
- 00:32
In the following reaction, 25.0 g of benzene, C6H6, reacts with excess HNO3, which results [Chemical reaction appears]
- 00:41
in 19.7 g C6H5NO2.
- 00:45
What is the percent yield for this reaction?
- 00:49
And here are your potential answers:
- 00:52
The first thing we should do is figure out what we’re actually being asked. [Student raises hand to answer question]
- 00:56
We have a feeling there’s a whole lot of fluff in this one.
- 00:59
We don’t care about this Ludwig van Benzthoveen guy and whatever company his blasphemously [Beethoven sipping coffee]
- 01:04
undercaffeinated coffee created, we just want to know about the reaction.
- 01:09
So the important part of the question is just the last two sentences, the equation, and
- 01:13
the answers.
- 01:14
Boom, boom, boom, cut all that unnecessary stuff out of your life. [unnecessary part of question disappears]
- 01:17
Okay, so it’s asking us about the percent yield and giving us grams going into and out
- 01:22
of a reaction.
- 01:23
And by grams, we mean the unit, not the delicious cracker. [Man takes cracker and person uses wand to make it disappear]
- 01:27
Yeah, we were disappointed, too.
- 01:28
Because this is a question involving specific amounts of chemicals reacting, before we even
- 01:32
think about how to solve it, we’re going to convert everything to moles.
- 01:36
All of our given values are in grams, so let’s convert from grams to moles by using the molar
- 01:40
mass.
- 01:41
Which means we have to calculate the molar mass.
- 01:42
The molar mass of benzene is 6 times the atomic weight of Carbon, 12.01 grams per mole from
- 01:46
the periodic table, plus 6 times the atomic weight of Hydrogen, 1.01 grams per mole, which
- 01:52
gives us 78.12 grams per mole.
- 01:56
The molar mass of C6H5NO2 is 6 times the atomic weight of carbon plus 5 times the atomic weight [molar mass appears]
- 02:01
of hydrogen plus the atomic weight of Nitrogen, 14.01 grams per mole, plus 2 times the atomic
- 02:08
weight of Oxygen, 16.00 grams per mole, which gives us 123.12 grams per mole.
- 02:14
Whew.
- 02:15
Still with us?
- 02:16
Now, let’s calculate the moles of each substance so we can stop talking about weight so much. [Benzene and nitrobenzene on balance scales]
- 02:20
It’s making the molecules self-conscious…
- 02:24
To find the moles of each substance, we take the mass in grams and divide by the molecular
- 02:29
weight.
- 02:30
This is 25.0 grams over 78.12 grams per mole for benzene, giving us 0.320 moles of benzene. [moles calculation appears]
- 02:38
For C6H5NO2, it’s 19.7grams over 123.12 grams per mole giving us 0.160 moles of C6H5NO2.
- 02:48
Time to mop your brow. [Worker wipes away sweat from brow]
- 02:50
We did it.
- 02:51
Wait… what was the question?
- 02:53
Oh right.
- 02:54
Percent yield.
- 02:55
And that’s not a matter of how often one chemical let’s another one pass at an intersection. [Car stops at a yield sign]
- 02:59
It’s how much product you got out of a reaction.
- 03:03
Specifically, how much product you actually get as a percentage of what you could have
- 03:06
gotten if everything went perfectly.
- 03:08
Because, like life, things in chemistry don’t always go perfectly. [Scientist eating a cookie]
- 03:14
In this reaction, we see the same number of benzenes and C6H5NO2 molecules on either side
- 03:18
of the reaction, so each time we use a benzene we make a C6H5NO2.
- 03:24
This means we could ideally make as many moles C6H5NO2 as we had moles of benzene to start
- 03:30
with, which we calculated to be 0.320.
- 03:32
To calculate the percent yield, we take the moles we actually got over the moles we could [percent yield equation appears]
- 03:37
have gotten, 0.160 over 0.320, and multiply by 100.
- 03:41
This gives us a 50 percent yield for the reaction.
- 03:44
Which isn’t a great result, but it is our answer.
- 03:48
If your lap supervisor is disappointed, you can offer him a cookie. [Man offers supervisor a cookie]
- 03:50
Or 20.
- 03:51
But no more.
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