High school biology
Flow of energy and matter through ecosystems
See how energy flows and matter is recycled in ecosystems.
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- Where would decomposers be placed on the biomass pyramid?(15 votes)
- Decomposers are typically placed on the side of the pyramid, and not a specific level, since they consume and can be consumed by many of the same organisms. For example, a squirrel eats a mushroom, and the mushroom takes in the squirrel's nutrients when it decomposes.(9 votes)
- What is an omnivore then? Apex predators?(9 votes)
- An omnivore is an organism that eats both plants and animals, and they CAN be apex predators.(3 votes)
- Do decomposers recycle energy and matter? Where does the matter go?(9 votes)
- It goes back to the soil, which provides nutrients for the grass, which provides food for the cow e.t.c.(3 votes)
- Would cannibalism factor into wheter an organism is an apex predator?(6 votes)
- Cannibalism focuses on a different sphere of the hunter vs. the hunted. Often times cannibalism happens because either the species is starved or it is a customary response to what the species does (i.e., the female praying mantis eats the male after reproductive actions).
All in all, I'd say that cannibalism does not have a factor in evaluating if an organism is an apex predator or not.(2 votes)
- what would happen if the bunny or whatever the thing is that the fox ate did not have the energy in it and when the fox ate it, it got no energy and it had not eaten in days?(3 votes)
- the rabbit does not need energy for the fox to get energy from it, the fox gets energy from eating(5 votes)
- How can the tree eat the mushroom🧐(3 votes)
- Trees don't eat mushrooms.
Mushrooms form from fungal mycelial networks in the dirt which decompose organic matter into nutrients. Growing trees, and other plants, can then access these nutrients via their roots.(5 votes)
- Are scavengers like vultures (who find and eat already dead consumers) consumers or decomposers?(4 votes)
- Scavengers are consumers because they act like any other consumer. The only difference is a dead corpse and not living animal being freshly killed.(3 votes)
- And would scavengers be decomposers?(4 votes)
- Not exactly because they again act as predators even though they eat dead meat. First of all, they do not eat the complete corpse, second, they produce waste in the form of stool.
Only microorganisms, worms and bugs act as detritivores.(3 votes)
- Where would decomposers be placed on the biomass pyramid?(4 votes)
- Decomposers are usually placed at special place in pyramid because they break down dead organisms into molecules at every stage of pyramid.(3 votes)
- what are the similarities between the flow of energy and matter through ecosystems?(2 votes)
- I do not know whether you can compare them in those manners. There are no 'similarities' or 'differences' they are just two different things going on at once simultaneously and cannot happen without each other.
You can only say that the difference is that energy cannot be created or destroyed just changes its form and flows. The energy is flowing while the matter is cycling. So you can say that both create cycles...(5 votes)
- [Voiceover] Let's think a little bit how energy flows, and how matter is recycled in an ecosystem. And so the whole time that we go through this video, think about these two ideas. And even after watching this video, look at ecosystems around yourself, even ones that you're a part of and think about how energy flows and how matter's recycled. Let's first think about energy. The energy for most ecosystems originally comes from the Sun. There are other sources of energy, you could think about even moonlight, but that essentially comes from the Sun. But there's also geothermal energy, but the Sun is a source of most energy for most ecosystems we could think of. And how does the ecosystem make use of that energy? How does it get into, how does it that get stored within the ecosystem especially as biomass? Well, it starts with primary producers which are usually going to be plants. They can also be bacteria that are able to photosynthesize, or that are able to take that energy and create biomolecules that store energy from it. And so these are primary producers, these plants in this diagram. Sometimes you'll see them referred to as autotrophs. They are getting their own food from the Sun, from this energy. And once again, how is that energy stored? Well, it's stored in these biological molecules. If you were to zoom in into the molecules in this plant, and this is a huge oversimplification, you'll see all these bonds between these carbons. And to make those bonds requires energy and if you were to break those bonds it could release energy. And you might say, well, where did all these carbons come from that are in this tree? Well, the carbon is coming from the air. Our air has carbon dioxide in it. It has carbon dioxide, so those are the carbons, maybe let me draw some oxygens. So two oxygens for every carbon. And the whole process of photosynthesis is all about fixing that carbon. Let me write that word down. We are fixing that carbon from a gaseous form when it's part of carbon dioxide, into the structure of the plant, into the biological molecules of the plant. So it's storing that energy. Now it's not a perfectly efficient process. Not all of the energy from the Sun is going to be able to be stored. Some of it is being reflected. Even the plant itself as it lives, as it reproduces, as its cells divide, some of that energy is used. And eventually, that energy is released as heat. And you're gonna see this trend a lot in thermodynamic systems, that you're going from one energy, you're using energy to do some work, but in the process, you are going to be producing heat. But this is just the beginning of our energy flow. Now we could think about how that energy now flows to the other actors in the ecosystem. So the next phase, and this is a very simplified diagram or ecosystem that we're thinking about. Most ecosystems are far, far, far more complex. Let's think about the characters that would eat the plants, the characters that would eat the primary producers, and we call the folks that eat the primary producers, we call them primary consumers. So this bunny, or this squirrel right over here, they are primary consumers. They consume the primary producers. And why do they consume them? Why does a bunny eat the grass? Well, because it gets energy from those bonds in the biological molecules, from those carbon bonds, and other bonds. And it's able to use that energy to grow itself, to reproduce, to live, to run around, and it also stores some of that energy in its own biomass. And once again, this process is not very efficient. Going from one layer of trophic to another layer of trophic, you only have about 10%, 10% of the energy gets transferred or gets stored in the next layer. Why only 10%? Well, because not all of the plants get eaten. The whole process of eating plants, digesting plants, some of the energy gets pooped out, gets pooped out because the primary consumer here, or the consumer isn't able to get all of it out of the actual biological molecules. And so overall, it's an inefficient process. Now, we're not done yet. We still have energy stored in the biological molecules of this primary consumer that someone might be interested in. And we know that in many ecosystems there are things that like to eat rabbits or even squirrels. And in this drawing it will be this fox. And this fox because it eats primary consumers, we would call it a secondary consumer. The secondary consumer. And you could keep going on with this if there were some character out here. Let's say there's some guy who likes to eat foxes. That's a knife in his hand that he uses to go after the foxes with. Well, so the fox could go to him, and once again, why is he eating foxes? Well, he wants that energy in that fox, and actually it's not just about molecules. We'll talk about matter in a second. He wants the energy and the matter from the fox to grow and live himself. And so this character would be called a tertiary consumer. Tertiary consumer. And if there's no one who wants to eat him, well then he would be considered an apex consumer, or an apex predator. And these characters that eat other animals, we've talked about it before, they're called carnivores. But let me just say, he's the apex. And apex, we're really thinking about the top of the food chain. That's why they're called, that would be called an apex consumer, or an apex predator. But we're not done yet because at some point all of these characters, whether we're talking about the trees, the bunnies, the fox, this character who likes to eat foxes, they're going to die. And that energy just doesn't disappear. In general, you're going to see, energy is conserved and it flows from one place to another. That energy is then going to be used by these characters right over here, which we call decomposers. They can take all that leftover energy and that dead carcass or even in the poop, and they can make use of it, once again, for them to live, for them to reproduce. And then by breaking that down, they can release a lot of those nutrients and the matter that's used. And once again, the matter's recycled, once again, to be used by the plants. So it creates this really nice cycle. And the important thing to realize is that it comes in as light that energy gets transferred as we go through the different layers of trophic. And it's not a completely efficient process, and a lot of that energy, especially as these organisms live, and reproduce, and run around gets released as heat. Now we've focused a lot on the energy, let's think a little about the matter. I've already touched on it, but the matter is recycled. There isn't, at least the way that we've set this up, there isn't new matter that is entering or leaving these ecosystems or being magically created or magically destroyed. As I mentioned, when you look at a leaf on a plant growing, or a tree growing, or a leave of grass growing, that matter isn't just coming out of nowhere, it's coming out of, it's just a different form, or maybe the best way to put it, that matter was always there in the form of carbon dioxide. The plant is just using that energy from the Sun to fix that carbon from a gas form into a solid form. And it's able to use that energy to form bonds between the carbons in these biological molecules that actually store energy. And the plant can use that energy to grow and as we've talked about, things that eat the plants, or things that eat the things that eat the plants can use that energy. And as we talked before, the carbon dioxide comes in these plants. And maybe this arrow might be a little bit misleading, so let me erase that for now. But we release oxygen, O2. That oxygen, and we've seen that as part of the photosynthesis process, that oxygen is used by the animals to metabolize these biological molecules. We studied that in biology in respiration. And the matter itself, as we say, we have this carbon right over here. When it gets eaten, well then that becomes part of the bio molecules inside of this bunny, and when the bunny uses any of these biological molecules as a source of energy so it's able to break those bonds through respiration. Well, then that carbon gets released in the form of carbon dioxide, so maybe this is a better way. Oh, actually it was already drawn right over here. And so the important thing to realize is that energy is flowing, light from the Sun comes in, it's slow, you know all this action goes on, and then it gets released as heat on almost every step, but the matter itself, it's always been there. All of the atoms in our body, on Earth, it's just constantly being recycled. It's actually was generated inside of stars many, many billions of years ago, and we just keep reusing it over, and over, and over again. It gets recycled from one form to another, even after all of these actors die, the decomposers break them down into simple inorganic molecules. As we talked about before, that can then be used as the plants in conjunction with the carbon from the air and the light from the Sun and water that it gets through its roots to start that process all over, all over again.