A trophic pyramid is a diagram showing the relative energy, biomass, or number of organisms at each feeding level of an ecosystem, narrowing toward the top because only about 10% of energy passes from one trophic level to the next.
A trophic pyramid is a picture of where the energy goes in an ecosystem. You stack the feeding levels (trophic levels) on top of each other: producers on the bottom, then primary, secondary, tertiary, and quaternary consumers, with decomposers recycling material throughout. Each level sits on the one below it because every level eats the one beneath it.
Why a pyramid shape and not a rectangle? Because energy gets lost at every transfer. Only about 10% of the energy at one level makes it into the next level. The other 90% is burned off as heat, used for movement, growth, and homeostasis, or never eaten in the first place. So the producer level is huge, and by the time you reach top predators, there's barely any energy left to support them. That's exactly why apex predators are rare. The pyramid is just the 10% rule drawn as a stack.
Trophic pyramids live in Unit 8: Ecology, specifically topic 8.2 Energy Flow Through Ecosystems. They're called out directly as an illustrative example under EK 8.2.C.2, alongside food chains and food webs. The big learning objective is AP Bio 8.2.B, which asks you to explain how energy flows and matter cycles through trophic levels, and AP Bio 8.2.C, which asks how changes in energy availability ripple through populations, communities, and ecosystems. The pyramid is the tool that makes both of those concrete. It also connects to the course-wide theme of energy and matter: energy flows one way and dwindles (the pyramid), while matter cycles around and around (biogeochemical cycles).
Keep studying AP® Biology Unit 8
Biomass (Unit 8)
Biomass is the total mass of living stuff at a level, and it's one of the things a trophic pyramid can measure. Most pyramids are widest at the producer level because that's where the most biomass usually sits.
Autotrophs and Primary Productivity (Unit 8)
Photosynthetic autotrophs capture sunlight and set the size of the whole pyramid. If primary productivity drops, every level above it shrinks too, which is the heart of EK 8.2.C.2.
Biogeochemical Cycles (Unit 8)
Here's the key contrast: energy moves up the pyramid and leaks away, but matter doesn't disappear. Carbon, nitrogen, and water cycle back through decomposers, so matter is conserved even as energy is lost.
Decomposers (Unit 8)
Decomposers don't really fit neatly on the pyramid because they break down dead organisms at every level. They're what returns matter to the soil and atmosphere so the biogeochemical cycles keep turning.
Expect this on multiple-choice questions that test the 10% rule. A classic stem gives you a starting amount of producer energy or biomass and asks how much reaches the tertiary or quaternary consumers. You multiply by 0.1 at each step. For example, a 40% drop in phytoplankton at the base cascades up through every level. You should also know the shape question: pyramids are widest at the bottom (most energy and usually most biomass at the producers) and narrowest at the top. Be ready to explain WHY in free-response style: energy is lost as heat and metabolic work at each transfer, so less is available to support the next level. No released FRQ has used the phrase verbatim, but the underlying logic shows up in any question asking how a change at one trophic level affects the others.
A food web shows WHO eats WHOM, with arrows tracing every feeding connection. A trophic pyramid shows HOW MUCH energy, biomass, or how many organisms exist at each level, and it's always a stacked shape. The web maps relationships; the pyramid maps quantities.
A trophic pyramid stacks feeding levels from producers at the base to top consumers at the peak, getting narrower as you go up.
About 10% of energy transfers from one trophic level to the next, and the other roughly 90% is lost as heat and metabolic work.
The pyramid usually has the most biomass at the producer level because that's where energy enters the ecosystem from autotrophs.
A drop in producers (like phytoplankton) shrinks every level above it, which is why energy availability controls population sizes.
Energy flows one way up the pyramid and dwindles, while matter cycles back around through biogeochemical cycles.
It's a diagram showing the relative energy, biomass, or number of organisms at each trophic level of an ecosystem. It narrows toward the top because only about 10% of energy passes between levels.
Because energy is lost at every transfer. Only around 10% of the energy at one level reaches the next, so each higher level has far less energy available and supports fewer or smaller organisms.
Usually the producers (autotrophs) at the bottom. They capture energy from sunlight first, so they have the most energy and biomass to support everything above them.
A food web shows who eats whom using arrows between organisms. A trophic pyramid shows how much energy or biomass exists at each level. One maps relationships, the other maps quantities.
Multiply by 0.1 (10%) at each step up. If producers have 10,000 units of energy, primary consumers get about 1,000, secondary consumers about 100, and tertiary consumers about 10.
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