He's a mit grad and harvard post grad. He also created a world wide free site for people who are less fortunate, so they can learn mandatory kindergarden to high school curriculums.
But just adhesion doesn't explain capillary action. If it were the case, then the height that the water could rise to would be independent of the tube's length. But that would mean a perpetual fountain if the tube was short enough, which is not what we see. It also has to do with air pressure being lower inside the tube because of the small space that impedes high velocity air particles. Inside the tube there's a gradient of pressure, with a minimum in the middle of it, and normal air pressure at the ends.
sorry for comenting on an old coment but can you please give some sort of sorce because i tried finding what you tallked about, but couldnt find anything. thank you
Ivan Miholić its actually pretty much logic, you don’t need a source for it. But what the OP didn’t point is that due to capillary action, there is a force extered either upward or downward. And THIS force is balanced out by the PRESSURE exerted on or by the OTHER OPEN END. This is why equilibrium is achieved even though there are two open ends on which atmospheric pressure is acting. Because its the liquid weight that balances out the capillary rise/fall, not the atmospheric pressure. Hope it clears something up for ya.
If the capillary action in any given system is strong enough for a liquid to defy gravity, then that liquid will not suddenly start to adhere to gravity once it reaches the end of the glass tube. The glass tube keeps it from progressing any further once it's reached the end, and the water is not about to spill over (adhering to gravity), because if the water is capable of spilling over at that point, then it wouldn't have been capable of climbing to that point in the first place.
went to take a poop and put some tp in the water so it wouldn't splash. was interested by how the water climbed the tp as I was placing it, so I decided to once and for all look up how capillary action works. ended up being one of the most informative poops I've ever taken thanks to this video 👍
Very informative video, thanks. Do you have time to answer a question for me? I have a small vessel filled with water. A thin tube (1.5mm inner diameter) hangs an arbitrary distance below the surface and the top is attached to a valve that allows me to release ink into the water. When the valve is open, ink flows freely. When I close the valve, a vacuum is created at the top of the tube, so the flow of ink stops. However, through what I assume is capillary action, water from the vessel is pulled into the tube, apparently displacing ink, which then leaks into the vessel. This continues until all of the ink in the tube has leaked out. My question is, is there any way to prevent this leakage from happening? I cannot change the viscosity of either the ink or the water. The tube could be modified if that would help, but not to the extent of using a much larger diameter tube. I hope you find this question interesting and I'd be most appreciative if you can answer it. Thanks very much!
I have 2 questions? One what draws water to paper towel and 2 why doesn't capillary action happen on the other side of the of the tube (The outer area).
Answering ur first q..... In simple terms, water really likes to wet certain surfaces (e.g. your paper towel fibers), and is willing to do so against a small amount of gravity. If you have lots of wettable surface area per volume of water, then the water can be pulled up quite a distance.. basically adhesion is occuring here when it happens water will tend to spread over the surfaces of the other material, even climbing against gravity to do so. Cohesion among the water molecules will drag along those water molecules not in direct contact with the material, and surface tension will hold the water together as it adheres to the surface. Adhesion may be strong enough to raise the water against gravity.
I have 1 question; as capillarity is due to adhesion then while calculating capillary rise, why we take surface tension in free body diagram instead of adhesive force
At the equilibrium, the already adhesived water molecules at the top pull the ones on the surface next to those tangentially with force per unit length equals to T of water/air. Hence mg=2 pi r T cos (theta).
Isn't water basically magnetic (a water molecule seems to be a very tiny magnet to me), because of the positive and negative charges involved, pray tell, Sir?
He mentions the biggest clue for you, simply that thermal energy boosts the water to a higher gravitational potential energy, but in doing so it looses momentum/ kinetic energies so what you will see is a loss of temperature in the system directly related to the increase in gravitational potential energy.
So if I had a tube made of something that Mercury "Adheres to" stronger than it does itself; would it have a concave meniscus? and be sucked up the tube (a tiny bit because it's heavy)? I think yes, so that means capillary action relies on not only the size of the tube, but the liquid and tube materials used!?!?!?! Huh....Whut?
Plastics are kinda a complicated chemistry topic and often times there are entire courses at unis on polymers, but basically because the short answer to your question that there are many different kinds of plastics made up of different chains of elements called polymers. There are many types of plastics, but a plastic water container is likely a different kind of plastic than the plastic of a comb. If that doesn't help: think about the idea that polymers can be made up of tons of different constituents and amounts of constituents -- like carbon, hydrogen, oxygen, nitrogen, sulfur, chlorine, fluorine, phosphorus, silicon, etc. These all have different differences in polarities across molecules.
This is painful to watch. The silica surface is nothing like this guy thinks it is, it is completely covered with hydroxyl groups, in fact you have to go to high temperatures to get rid of them and they reappear instantly when exposed to the ambient environment. The wetting and the capillary forces are caused by the water hydrogen bonding to the silanols (Si-OH) groups on the surface.
The 13yr old voice in my head says: Imma start callin’ my junk Freddy Mercury because it’s bulging! The 17yr old nerd voice in my head says: My bulge puts the Hg in Huge!
This dude must be brilliant. He teaches all the lessons on the website.
true thing
Yes true thing
I immediately subscribed without hesitation. this dude explains so well without using convoluted language. this is actually helping me
Very understandable. you must be some kind of hero c:
+Shouri No, Sal Khan is just some dude who says things.
Davarman he's a MIT graduate and Harvard post graduate...need to say anything more?
He's a mit grad and harvard post grad. He also created a world wide free site for people who are less fortunate, so they can learn mandatory kindergarden to high school curriculums.
God bless this man. I understood it crystal clear. Many many thanks.
Amazing , one thing I love about this lecture is that he illustrate everything with the help of basic concepts.
Leave it to chemistry to change completely the way i look at a paper towel
@iroxursox1234567 WHAT?!
Lamp look it up sis
But just adhesion doesn't explain capillary action. If it were the case, then the height that the water could rise to would be independent of the tube's length. But that would mean a perpetual fountain if the tube was short enough, which is not what we see. It also has to do with air pressure being lower inside the tube because of the small space that impedes high velocity air particles. Inside the tube there's a gradient of pressure, with a minimum in the middle of it, and normal air pressure at the ends.
sorry for comenting on an old coment but can you please give some sort of sorce because i tried finding what you tallked about, but couldnt find anything. thank you
Ivan Miholić its actually pretty much logic, you don’t need a source for it. But what the OP didn’t point is that due to capillary action, there is a force extered either upward or downward. And THIS force is balanced out by the PRESSURE exerted on or by the OTHER OPEN END. This is why equilibrium is achieved even though there are two open ends on which atmospheric pressure is acting. Because its the liquid weight that balances out the capillary rise/fall, not the atmospheric pressure. Hope it clears something up for ya.
If the capillary action in any given system is strong enough for a liquid to defy gravity, then that liquid will not suddenly start to adhere to gravity once it reaches the end of the glass tube. The glass tube keeps it from progressing any further once it's reached the end, and the water is not about to spill over (adhering to gravity), because if the water is capable of spilling over at that point, then it wouldn't have been capable of climbing to that point in the first place.
Thank you for the additional information! I feel stupid that I did not think about this on my own.
I’m taking Fluids Mechanics this semester and I really need to understand this forces. Thank you so much Saul!!!!!
*Sal
went to take a poop and put some tp in the water so it wouldn't splash. was interested by how the water climbed the tp as I was placing it, so I decided to once and for all look up how capillary action works. ended up being one of the most informative poops I've ever taken thanks to this video 👍
Woah! You are a bloody good teacher
you just saved a random guy's surface chem final, thank you
Clearly explained! Thank you!
That so cool. I never realized it is the positive polarity of the glass that attracts the negative polarity of the water to it.
Thanks Sal!
This fire mixtape on capillary action is better than that other fire mixtape about balancing chemical equations.
dont ever take me seriously
thank u brother u saved me
dude thanks so much this helped me alot to understand my last lecture :)
mr khan is the king of the world
This is really impressive
Thank you so much Sir
good explanation
thanks
damn good video, never thought this is why water sticks to most surface
I love this channel! Thanks for the free info! I find this so cool
Very good video!
Thank u verrrry much Sir
Excellent - well explained!
You made realize how stupid my university professors are. Never in my life I have learned so much. Thank you. You are my idol.
Thank u sir
Thanks a lot sir
Very informative video, thanks. Do you have time to answer a question for me? I have a small vessel filled with water. A thin tube (1.5mm inner diameter) hangs an arbitrary distance below the surface and the top is attached to a valve that allows me to release ink into the water. When the valve is open, ink flows freely. When I close the valve, a vacuum is created at the top of the tube, so the flow of ink stops. However, through what I assume is capillary action, water from the vessel is pulled into the tube, apparently displacing ink, which then leaks into the vessel. This continues until all of the ink in the tube has leaked out. My question is, is there any way to prevent this leakage from happening? I cannot change the viscosity of either the ink or the water. The tube could be modified if that would help, but not to the extent of using a much larger diameter tube.
I hope you find this question interesting and I'd be most appreciative if you can answer it. Thanks very much!
Brilliant
Khancave
I have 2 questions? One what draws water to paper towel and 2 why doesn't capillary action happen on the other side of the of the tube (The outer area).
I know the awnswer to your second question. For capillary action to work, the tube has to be very narrow, or else there's no place to 'bump up'.
Answering ur first q..... In simple terms, water really likes to wet certain surfaces (e.g. your paper towel fibers), and is willing to do so against a small amount of gravity. If you have lots of wettable surface area per volume of water, then the water can be pulled up quite a distance.. basically adhesion is occuring here when it happens water will tend to spread over the surfaces of the other material, even climbing against gravity to do so. Cohesion among the water molecules will drag along those water molecules not in direct contact with the material, and surface tension will hold the water together as it adheres to the surface. Adhesion may be strong enough to raise the water against gravity.
what is the height in case of pressure difference on the both sides of meniscus?
I have 1 question; as capillarity is due to adhesion then while calculating capillary rise, why we take surface tension in free body diagram instead of adhesive force
At the equilibrium, the already adhesived water molecules at the top pull the ones on the surface next to those tangentially with force per unit length equals to T of water/air. Hence mg=2 pi r T cos (theta).
Does this explain the mess caused when liquid sticks to the outer walls, let's say for a cup when it is poured into another container?
I like it
capillary
/kəˈpɪləri/
but i still love this vid definitely
capillar reaction helps us to clean the table #usefull : ))
(i hope you know what i mean)
Yes it form shape
Awesome
5:54 I see it in a plastic tube. Maybe not so pronounced but it's there.
how come he can teach all the subjects ?
I don't understand the case of mercury why is there a depression in case of mercury. Plz explain me🙏🙏🙏
Does capillary action occur inside the capillaries in our body?
Isn't water basically magnetic (a water molecule seems to be a very tiny magnet to me), because of the positive and negative charges involved, pray tell, Sir?
hey the paper towel is also showing the capillary action does it mean that paper also has polarity in it????
Watching Corey Taylor teach fluid mechanics is just amazing.
Aweaome
What happens in the case of mercury and glass then why it is convex form upward?
What is your question?
I have one question then why does distilled water doesn't have enough adhesion instead it forms flat meniscus
why does the oxygen on water has a positive charge? shouldn't be negative?
Hi♡💕💕
+Nikki Liu Hello
+Davarman I don't even remember putting that comment
+Nikki Liu I don't blame you, it was almost a year ago.
+Davarman oh, that's probably why
When the water is climbing the tube it gains potential energy, but where is this energy coming from?
He mentions the biggest clue for you, simply that thermal energy boosts the water to a higher gravitational potential energy, but in doing so it looses momentum/ kinetic energies so what you will see is a loss of temperature in the system directly related to the increase in gravitational potential energy.
So if I had a tube made of something that Mercury "Adheres to" stronger than it does itself; would it have a concave meniscus? and be sucked up the tube (a tiny bit because it's heavy)? I think yes, so that means capillary action relies on not only the size of the tube, but the liquid and tube materials used!?!?!?! Huh....Whut?
it's also how candles work and i think that's very sexy of it
Are paper towels polar in nature??
First comment :)
Lolno
how does he write so effectively with a mouse this is abhuman
He actually got a touch pad writing device
@@sarbagyaratnakhatiwada3159 ak ok i'm an idiot ty XD
surface tension?
Im 14 and i dont understand😊
Why not show actual pictures of the phenomena instead of just talking about it?
I guess you could do the experiments yourself, they’re not that complex
But how come if you take a plastic comb over water, it still has capillary action.
Plastics are kinda a complicated chemistry topic and often times there are entire courses at unis on polymers, but basically because the short answer to your question that there are many different kinds of plastics made up of different chains of elements called polymers. There are many types of plastics, but a plastic water container is likely a different kind of plastic than the plastic of a comb.
If that doesn't help: think about the idea that polymers can be made up of tons of different constituents and amounts of constituents -- like carbon, hydrogen, oxygen, nitrogen, sulfur, chlorine, fluorine, phosphorus, silicon, etc. These all have different differences in polarities across molecules.
That seemed like it was cut short lol
who's here after the pyramid power plant?
i like your dipoles haha
This is painful to watch. The silica surface is nothing like this guy thinks it is, it is completely covered with hydroxyl groups, in fact you have to go to high temperatures to get rid of them and they reappear instantly when exposed to the ambient environment. The wetting and the capillary forces are caused by the water hydrogen bonding to the silanols (Si-OH) groups on the surface.
Why does it happen with other surface like towels, paper, etc.?
The 13yr old voice in my head says: Imma start callin’ my junk Freddy Mercury because it’s bulging!
The 17yr old nerd voice in my head says: My bulge puts the Hg in Huge!
Thanks sir