The Decolorization of Crystal Violet - By MITK12Videos
Transcript
| 00:10 | So we're going to discuss the D . Colorization of | |
| 00:12 | crystal violet . But first maybe we should talk about | |
| 00:15 | what crystal violet is exactly . It's a chemical that | |
| 00:19 | appears to be a dark greenish yellow powder . But | |
| 00:23 | when we mix it with water it turns into a | |
| 00:25 | vibrant violet solution . And at the molecular level , | |
| 00:28 | the crystal violet molecule looks like this . The red | |
| 00:31 | dots in the structure represent the electrons that formed the | |
| 00:34 | chemical bonds . There are also some hydrogen atoms in | |
| 00:38 | the molecule , but they aren't shown here because it | |
| 00:40 | would get very crowded . And we can see that | |
| 00:43 | the more crystal violet powder we add to the water | |
| 00:46 | , the darker the solution becomes . So what is | |
| 00:49 | it about the crystal violet molecule that makes the solution | |
| 00:52 | so very very violent . The answer can be found | |
| 00:56 | in its structure . An interesting aspect of crystal violet | |
| 00:59 | structure is the fact that its entire structure is in | |
| 01:02 | resonance . Now you may be asking yourself what is | |
| 01:05 | resonance , Let's look at a simpler molecule . 1st | |
| 01:10 | . Benzene , which has six carbon atoms and six | |
| 01:13 | hydrogen atoms has two resonant structures . It can be | |
| 01:17 | drawn like this or like this but it doesn't really | |
| 01:22 | exist in either of these forms . The D localized | |
| 01:25 | electrons rotate around the benzene ring so quickly that they | |
| 01:29 | are effectively shared by all the atoms , which creates | |
| 01:33 | 1.5 bonds between carbon atoms instead of alternating single and | |
| 01:37 | double bonds . If we look back at crystal violet | |
| 01:41 | , we can draw many residents structures because electrons are | |
| 01:44 | D localized across the entire molecule . The D localized | |
| 01:48 | electrons caused crystal violet to absorb light in the visible | |
| 01:52 | part of the light spectrum . This is why crystal | |
| 01:55 | violet is colored . But you don't have to take | |
| 01:58 | my word for it . We can actually measure how | |
| 02:01 | crystal violet absorbs light in the laboratory using an instrument | |
| 02:04 | called an ultraviolet visible spectrum odometer . So let's do | |
| 02:09 | that . First . We have to put some of | |
| 02:11 | our solution into a cubit . We then place the | |
| 02:14 | Q . Bet into the holder inside the spectrum odometer | |
| 02:18 | . Now when we take a measurement of our solution | |
| 02:20 | , the spectrum odometer will send a beam of light | |
| 02:23 | through our solution . And whatever wavelength I set For | |
| 02:27 | this experiment , I have set the wavelength range from | |
| 02:30 | 290 nm to 700 nm . And now we can | |
| 02:35 | see the data that the spectrum odometer produced . It | |
| 02:38 | appears that our solution absorbs light over a range of | |
| 02:40 | colors And the peak absorption is at 590 nm . | |
| 02:46 | If we overlay the visible spectrum onto our graph , | |
| 02:49 | it looks like our solution is absorbing the most light | |
| 02:51 | in the yellow range . If it's absorbing light in | |
| 02:55 | the yellow range , why is our solution violet ? | |
| 02:59 | Well we don't see the color the solution absorbs . | |
| 03:03 | We see the colors the solution doesn't absorb and generally | |
| 03:07 | we will see the complementary color of the color of | |
| 03:11 | the solution absorbs the most and the complementary color of | |
| 03:15 | yellow is violet . Now that we know why crystal | |
| 03:19 | violet is violet and how we can measure just how | |
| 03:23 | violent it is . We're ready to explore how did | |
| 03:26 | to colorize it . So again , the answer lies | |
| 03:29 | with its structure . As we discussed before , the | |
| 03:32 | electrons are moving throughout the entire molecule very quickly . | |
| 03:36 | However , the electrons are not spread out evenly . | |
| 03:40 | Since the nitrogen atoms on the outside of the structure | |
| 03:43 | have a higher electro negativity . They pulled the electrons | |
| 03:47 | towards them and away from the center carbon atom . | |
| 03:50 | This leaves the center carbon atom with a slightly more | |
| 03:53 | positive charge . The positive charge of the central carbon | |
| 03:57 | can now attract a chemical species that has a negative | |
| 04:00 | charge . Of course the crystal violet molecule won't react | |
| 04:04 | with just any species . It has to be a | |
| 04:07 | reactive species . A chemical species like hydroxide reacts beautifully | |
| 04:14 | when the hydroxide ion comes close to the central carbon | |
| 04:17 | atom , they reacted form equivalent bond . When this | |
| 04:21 | happens , crystal violet no longer has a positive charge | |
| 04:25 | . Additionally , the new carbon oxygen bond prevents electrons | |
| 04:29 | removing throughout the structure and residents is now limited to | |
| 04:32 | the aromatic greens . So the new structure will no | |
| 04:35 | longer absorb light at 590 nm and it won't produce | |
| 04:40 | a violet color for us to see . So we | |
| 04:42 | have successfully to colorized crystal violet . But let's explore | |
| 04:47 | one last thing . What if we wanted to d | |
| 04:50 | colorize crystal violet even faster , you could probably imagine | |
| 04:54 | that the more hydroxide we put into the solution , | |
| 04:58 | the faster the hydroxide would find the crystal violet molecule | |
| 05:01 | and the faster the solution would be d colorized . | |
| 05:04 | This too can be verified experimentally . So let that | |
| 05:08 | be our last task here we have four solutions . | |
| 05:11 | They all have the same amount of crystal violet in | |
| 05:13 | them but we're going to vary the amount of hydroxide | |
| 05:16 | we put in them . So let's say the solution | |
| 05:18 | on the right has X . Amount of hydroxide . | |
| 05:22 | The next solution will have to X . The next | |
| 05:24 | will have three ex and the last solution on the | |
| 05:27 | left will have six X . So now let's see | |
| 05:30 | how long it takes for the crystal violet two D | |
| 05:32 | . Colorize . In summary , crystal violet appears violet | |
| 06:21 | because the residents in the structure allows it to absorb | |
| 06:24 | light in the visible spectrum . When the crystal violet | |
| 06:28 | molecule finds a hydroxide ion , they react , the | |
| 06:31 | residence is disrupted and the crystal violet can no longer | |
| 06:35 | absorb light in the visible spectrum . Therefore it's be | |
| 06:39 | colorized . |
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