Osmosis is a fascinating process where water molecules move from an area of low solute concentration to an area of high solute concentration through a semipermeable membrane. This movement can be due to mechanical blockage by larger solute particles or the water molecules being attracted to charged solute particles. Osmosis helps regulate the flow of water in and out of cells, which is crucial to their function. Created by Sal Khan.
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- What is the difference between solute and solvent?(21 votes)
- The solute is the substance that is dissolved. The solvent is what is the substance is dissolved in.
Example: dissolving salt in water. Salt is the solute and water is the solvent.(71 votes)
- Where can I learn about osmotic pressure? I'm really struggling with this concept.(20 votes)
- Think about a semi-permeable membrane with a high solute concentration on the right side. This side has more solutes, which through a few mechanisms draws water across the semi-permeable membrane into the right side.
This movement of water towards the high solute side is osmosis, and is technically due to pressure. (This pressure arises from the solutes binding to some of the water molecules so the solute side actually has less unbound water molecules than the solute free side which causes the pressure flow).
Typically the term "osmotic pressure" refers to the pressure needed in the opposite direction to equalize the water movement into the higher solute side.(29 votes)
- if there is 2% solute in the left side and 4% solute in the right, would the water molecules move from left to right or right to left?(5 votes)
- If you mean a 2% salt solution and a 4% salt solution, then water will move from the lower salt concentration to the higher salt concentration - water would move into the 4%, traveling left to right. Osmosis is an attempt to "balance" the salt concentrations by diluting the more concentration side.(26 votes)
- What is the difference between tonicity and osmotic pressure?(6 votes)
- Tonicity is a measure of osmotic pressure.
Now, what is osmotic pressure?
Osmotic pressure is the pressure of solution against semipermeable membrane to prevent water from flowing inward.
Tonicity is a measure of pressure.(15 votes)
- Can anyone explain osmosis in simple words, just to sum it up?
I'm having a hard time understanding it(6 votes)
- Osmosis is travelling of water molecules through a semi-permeable membrane.
When you have a cup of water and cover it with gauze. Then you turn it upside down and start spilling water. Water goes through holes in gauze.
This is extremely simplified to the popint I wonder whether it is correct. In this case, permeability relies on mechanic characteristics, while in nature, usually, it is chemical permeability of cell membranes.(12 votes)
- At min03:20Sal stats talking about how the solute particles mechanically block the gaps of the semipermeable membrane and that's the reason why it's more probable for water molecules from the left to go to the right side of the membrane. But if some of these solute particles are blocking the gaps in the membrane at some times, then how come these bigger particles don't stop molecules of water on the left side from entering the right side of the membrane as much as they stop the water molecules on the right side of the membrane from leaving?(8 votes)
- At5:19, there is a note that the explanation is outdated. Is there another explanation that's more up-to-date?(6 votes)
- If solute molecules have blocked the pores, water won't flow in either direction. So both sides are blocked. Nothing in or out.(5 votes)
- I feel like this question is weird, but how can random movement generate pressure? I understand that there are salt molecules in the solution, but how does it make water move from one side of the membrane to another? Also, in many diagrams, it shows water level being higher on one side than another, which I don't think it is possible due to Pascals Law. I don't think I get a lot of these concepts here.(6 votes)
- If you have ions from salt (or other molecules, like glucose or anything else dissolved), they bounce back off the holes/pores in the membrane on the side they are on. If they are present on both sides, then it occurs more frequently where they are at higher concentration. And as the ricochet off the membrane, they transfer some momentum to the water molecules around them, moving them away from the pore.
If the salt is the same concentrations both sides, the water is pulled away from the pore on average the same amount on both sides. But if there is more salt on one side, the water is less likely to pass through the pore from that side, because it is being pulled away from it.
Does this help a bit?(5 votes)
- What exactly is a particle? Is it just a molecule of a particular substance?
I've heard teachers say that particles are just small bits of the substance, but I've never really gotten it.(5 votes)
- A particle is simply a single piece in whatever system you are currently referring to. That piece can be as small as a photon of a beam of light, or as large as a star in a galaxy.(7 votes)
- Let's say that I had two compartments of water, and they're separated by a semipermeable membrane. Now what do I mean by semipermeable membrane? That means they allow some things to go through and not other things. Let's say this semipermeable membrane, it does allow water molecules to pass, and in a few seconds we'll talk about what it does not allow to pass, which makes it semipermeable. Let's just think about what would happen if we just had water molecules on either side. We've already talked about it in the videos on diffusion. The water molecule, since we have an equal concentration on either side, the probability that one of these water molecules goes this way in a certain amount of time is equal to the probability that a water molecule goes from right to left in the same amount of time, and that's because we have equal concentrations. And these things are all bouncing around in all different ways, they all have, they all are, they all have different velocities. They have different speeds and in different directions. We just sort of think about it probabilistically. The probability of going from left to right through one of these gaps is going to be equal to the probability of going right to left in any given period of time. But now let's make this interesting. Let's treat our water as solvent, and let's put some solute in it. So let's dissolve some solute. So let's throw some solute particles here. And I'm gonna make them bigger so you can see they would physically have trouble passing through these gaps. There's other ways where you could have semipermeable membranes that use charge to allow certain things to pass through and not others, but it's easier to visualize the size. Thinking about the membrane as only allowing certain things of certain size to pass through. So let's throw some solute there, and I'll actually throw a little bit of solute here too. I'll do one or two particles right over here, but I'm going to do many more. I'm going to do many more over there on the right hand side. So we have a higher concentration of solute on the right hand side, and this is a semipermeable membrane. You can see even from the size where I drew these gaps these big particles aren't going to be able to go through the membrane. They aren't going to be able to diffuse. If they were allowed to diffuse, then they would just go down their concentration gradient and, in any given moment of time, you would have a higher chance of one of these big particles moving from the right to the left than from the left to the right, 'cause you just have more on the right hand side. But this is a semipermeable, this is a semipermeable membrane. These things aren't just going to be allowed to naturally diffuse. Now all of these big particles, they all have their own unique velocities. So they all have their unique velocities. What do we think is going to happen? Let's just think about the problem. We know that the big particles can't diffuse from one side to another, but what's going to happen to the water molecules? The water molecules on the left hand side, they're not going to be stopped. If they are bouncing in the right way, they can bounce from the left to the right, or they could move from the left to the right through one of these gaps. But what about the ones on the right side? Well, if things are, if they're the just right conditions, if they're the just right conditions maybe this character could move through this, so you're definitely going to have water molecules going back and forth, but I'd argue that ones on the right hand side, there's a lower probability of water molecules from the right hand side moving to the left as from the left hand side moving to the right. And why is that? There's all this interference that play from these big molecules that aren't able to diffuse. These are going to be bouncing around. Sometimes they're going to be even, sometimes you can imagine them even blocking, they're going to be blocking the approach to these openings. If this membrane wasn't here, they wouldn't block the approach, they would just keep on going, but since that membrane is there, they might block it, or they might ricochet off, and while they ricochet off they might push on some water molecules, they might push on some water molecules going in this direction right over there. So an argument can be made that these water molecules, some of them will still make it from right to left, but you have a lower probability of going from right to left as you have from going to left to right. So because of this you would have a net inflow of water from this area where you have a low solute concentration. Remember the solute is the thing that's dissolved in the water. In general, we always consider the solvent to be whatever there's more of. In this case, it's water, and water is probably the most typical solvent, and the solute is whatever there's less of. So the solute is dissolved in the solvent, and so we have a net migration of the water molecules from this solution that has a low solute concentration to one that has a higher solute concentration. This phenomenon we call osmosis. We call this osmosis. There's other arguments for osmosis. It's something that we've observed many, many, many times. If you put something that's used to fresh water, and if it has skin or it has membranes that allows water to pass through it, put it salt water. The kind of famous things like slugs will not do well in the presence of salt because the water inside the slug will do exactly what is happening in this diagram. This mechanism that I just talked about, the molecules that cannot pass through the membrane, blocking the water molecules from going right to left, ricocheting off and maybe causing the ones that are on the right side to maybe move in this direction when they bounce into them. That's one explanation. Another possibility is many times the solute that's being dissolved in water has some charge associated with it. When we think of, say, regular table salt you have sodium, you have sodium ions. Regular table salt is sodium chloride, but when you put it in the water you have sodium ions and you have chloride ions, and you have chloride ions. These are negatives, the chlorides are negative. The sodium ions are positive. Above and beyond doing some of the mechanical blockage that I just talked about, there's also the idea that possibly because they are ionic they have charge, and water has partial charges, they also might stick to more of the water, so the waters that stick to them aren't going to be available to move through the membrane. So what I mean by the water's going to stick to them? Well, when we think about a water molecule, it's an oxygen. It's an oxygen then you have a partially negative charge, and then you have two hydrogens, two, let me write it this way, you have two hydrogens. Right over here, there's a partially positive charge. So there going to be this oxygen end, away from the hydrogens, is going to be attracted to the sodium molecule, and it's going to be less. The sodium molecule can't make it through. This guys going to want to stick to the sodium molecule. You can kind of imagine all of these water molecules sticking to the sodium molecule, which would make it less likely that these would pass from right to left than the ones that are passing from left to right. Similarly, if you have a negatively charged ion like this then you can orient the water the other way, where the partially positive charged hydrogen ends are going to be attracted to the chloride ion right over here. Since the chloride ion might not be able to get through, well, then these molecules that are stuck to it are going to be less likely to flow through. These molecules are going to be more attracted to the chloride or more attracted to the sodium ions than they would be to other water molecules that only have partial charges. These have full charges, so these can't get through. Then maybe it's a lower probability that these are going to get through as well. But the combined effects of all of these, and I'd love if any of y'all to point me to a nice simulation or maybe we'll create one on the Khan Academy computer science program to show this, is that you're going to have a higher probability of the water molecules over here going from left to right than the water molecules over here going right to left, from mechanical blockage and or these big molecules ricocheting off and pushing them in the wrong direction, or because they're just stuck to the big molecules because the big molecules are charged. And that is osmosis.