Pests of soyabean_Binomics_IdentificationDr.UPR.pdf
AQUIB ASSIGNMENT
1. COMMUNITY METABOLISM
Energy flow & primary productivity
Primary producers (usually plants and other photosynthesizers) are the
gateway for energy to enter food webs.
Productivity is the rate at which energy is added to the bodies of a group of
organisms (such as primary producers) in the form of biomass.
Gross productivity is the overall rate of energy capture. Net productivity is
lower, adjusted for energy used by organisms in respiration/metabolism.
Energy transfer between trophic levels is inefficient.
Ecological pyramids are visual representations of energy flow, biomass
accumulation, and number of individuals at different trophic levels.
Introduction
Well, our beautiful planet would definitely look barren and sad. We would
also lose our main source of oxygen (that important stuff we breathe and rely
on for metabolism). Carbon dioxide would no longer be cleaned out of the
air, and as it trapped heat, Earth might warm up fast. And, perhaps most
problematically, almost every living thing on Earth would eventually run out
of food and die.
In almost all ecosystems, photosynthesizers are the only "gateway" for
energy to flow into food webs (networks of organisms that eat one another).
If photosynthesizers were removed, the flow of energy would be cut off, and
the other organisms would run out of food. In this way, photosynthesizers lay
the foundation for every light-receiving ecosystem.
2. Producers are the energy gateway
Plants, algae, and photosynthetic bacteria act as producers. Producers are
autotrophs, or "self-feeding" organisms, that make their own organic
molecules from carbon dioxide. Photoautotrophs like plants use light energy
to build sugars out of carbon dioxide. The energy is stored in the chemical
bonds of the molecules, which are used as fuel and building material by the
plant.
The energy stored in organic molecules can be passed to other organisms in
the ecosystem when those organisms eat plants (or eat other organisms that
have previously eaten plants). In this way, all the consumers, or heterotrophs
("other-feeding" organisms) of an ecosystem, including herbivores,
carnivores, and decomposers, rely on the ecosystem's producers for energy.
If the plants or other producers of an ecosystem were removed, there would
be no way for energy to enter the food web, and the ecological community
would collapse. That's because energy isn't recycled: instead, it's dissipated as
heat as it moves through the ecosystem, and must be constantly replenished.
Because producers support all the other organisms in an ecosystem, producer
abundance, biomass (dry weight), and rate of energy capture are key in
understanding how energy moves through an ecosystem and what types and
numbers of other organisms it can sustain primary productivity and
secondary productivity.
3. Primary productivity
In ecology, productivity is the rate at which energy is added to the bodies of
organisms in the form of biomass. Biomass is simply the amount of matter
that's stored in the bodies of a group of organisms. Productivity can be
defined for any trophic level or other group, and it may take units of either
energy or biomass. There are two basic types of productivity: gross and net.
To illustrate the difference, let's consider primary productivity (the
productivity of the primary producers of an ecosystem).
4. Gross primary productivity, or GPP, is the rate at which solar energy is
captured in sugar molecules during photosynthesis (energy captured per unit
area per unit time). Producers such as plants use some of this energy for
metabolism/cellular respiration and some for growth (building tissues).
Rate of energy loss to metabolism and maintenance. In other words, it's the
rate at which energy is stored as biomass by plants or other primary
producers and made available to the consumers in the ecosystem.
Plants typically capture and convert about 1.3 -1.6 % of the solar energy
that reaches Earth's surface and use about a quarter of the captured energy for
metabolism and maintenance. So, around 1%of the solar energy reaching
Earth's surface (per unit area and time) ends up as net primary productivity.
Net primary productivity varies among ecosystems and depends on
many factors. These include solar energy input, temperature and
moisture levels, carbon dioxide levels, nutrient availability, and
community interactions (e.g., grazing by herbivores ) These factors
affect how many photosynthesizers are present to capture light energy
and how efficiently they can perform their role.
In terrestrial ecosystems, primary productivity ranges from about 2000 g
/ m² / yr in highly productive tropical forests and salt marshes to less
than 100g / m²/ yrin some deserts. You can see how net primary
productivity changes on shorter timescales in the dynamic map below,
which shows seasonal and year-to-year variations in net primary
productivity of terrestrial ecosystems across the globe.
5. How does energy move between trophic levels?
Energy can pass from one trophic level to the next when organic molecules
from an organism's body are eaten by another organism. However, the
transfer of energy between trophic levels is not usually very efficient.
How inefficient? On average, only about 10% percent of the energy stored
as biomass in one trophic level (e.g., primary producers) gets stored as
biomass in the next trophic level (e.g., primary consumers). Put another way,
net productivity usually drops by a factor of ten from one trophic level to the
next.
For example, in one aquatic ecosystem in Silver Springs, Florida, the net
productivities (rates of energy storage as biomass) for trophic levels were^33
start superscript, 3, end superscript:
Primary producers, such as plants and algae:-7618 kcal/m²/yr
Primary consumers, such as snails and insect larvae:- 1103 kcal/m²/yr
6. Secondary consumers, such as fish and large insects:- 111 kcal/m²/yr
Tertiary consumers, such as large fish and snakes:- 5 kcal/m²/yr
Transfer efficiency varies between levels and is not exactly 10%percent, but
we can see that it's in the ballpark by doing a few calculations. For instance,
the efficiency of transfer between primary producers and primary consumers .
Transfer efficiency = 1103 kcal/m²/yr×100
7618 kcal / m² /yr
Transfer efficiency = 14.5 %
Why is energy transfer inefficient? There are several reasons. One is that not
all the organisms at a lower trophic level get eaten by those at a higher
trophic level. Another is that some molecules in the bodies of organisms that
do get eaten are not digestible by predators and are lost in the predators' feces
(poop). The dead organisms and feces become dinner for decomposers.
Finally, of the energy-carrying molecules that do get absorbed by predators,
some are used in cellular respiration (instead of being stored as biomass. of
pyramids and see how they reflect the structure and function of ecosystems.
7. Ecological pyramids
We can look at numbers and do calculations to see how energy flows through
an ecosystem. But wouldn't it be nice to have a diagram that captures this
Ecological pyramids provide an intuitive, visual picture of how the trophic
levels in an ecosystem compare for a feature of interest (such as energy
flow,biomass, or number of organisms). Let's take a look at these three types
8. Energy pyramids
Energy pyramids represent energy flow through trophic levels. For instance,
the pyramid below shows gross productivity for each trophic level in the
Silver Springs ecosystem. An energy pyramid usually shows rates of energy
flow through trophic levels, not absolute amounts of energy stored. It can
have energy units, such as kcal/m²/yr or biomass unit such as g/m²/yr.
Energy pyramids are always upright, that is, narrower at each successive
level (unless organisms enter the ecosystem from elsewhere). This pattern
reflects the laws of thermodynamics, which tell us that new energy can't be
created, and that some must be converted to a not-useful form (heat) in each
transfer.
Biomass pyramids
Another way to visualize ecosystem structure is with biomass pyramids.
These pyramids represent the amount of energy that's stored in living tissue at
the different trophic levels. (Unlike energy pyramids, biomass pyramids show
how much biomass is present in a level, not the rate at which it's added.)
Below on the left, we can see a biomass pyramid for the Silver Springs
ecosystem. This pyramid, like many biomass pyramids, is upright. However,
9. the biomass pyramid shown on the right – from a marine ecosystem in the
English Channel – is upside-down (inverted).
The inverted pyramid is possible because of the high turnover rate of the
phytoplankton. They get rapidly eaten by the primary consumers
(zooplankton), so their biomass at any point in time is small. However, they
reproduce so fast that, despite their low steady-state biomass, they have high
primary productivity that can support large numbers of zooplankton.
Numbers pyramids
Numbers pyramids show how many individual organisms there are in each
trophic level. They can be upright, inverted, or kind of lumpy, depending on
the ecosystem.
As shown in the figure below, a typical grassland during the summer has a
base of numerous plants, and the numbers of organisms decrease at higher
trophic levels. However, during the summer in a temperate forest, the base of
the pyramid instead consists of a few plants (mostly trees) that are vastly
outnumbered by primary consumers (mostly insects). Because individual
trees are big, they can support the other trophic levels despite their small
numbers.
10. Summary
Primary producers, which are usually plants and other photosynthesizers,
are the gateway through which energy enters food webs.
Productivity is the rate at which energy is added to the bodies of a group of
organisms, such as primary producers, in the form of biomass. Gross
productivity is the overall rate of energy capture. Net productivity is lower:
it's gross productivity adjusted for the energy used by the organisms in
respiration/metabolism, so it reflects the amount of energy stored as biomass.
Energy transfer between trophic levels is not very efficient. Only10% of the
net productivity of one level ends up as net productivity at the next
level.Ecological pyramids are visual representations of energy flow,
biomass accumulation, and number of individuals at different trophic levels