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First teaching 2015

Last exams 2025

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Pioneer & Climax Communities (DP IB Environmental Systems & Societies (ESS))

Revision Note

Alistair Marjot

Written by: Alistair Marjot

Reviewed by: Bridgette Barrett

Pioneer & Climax Communities

What are pioneer communities?

  • In pioneer communities (i.e. in the early stages of succession), gross productivity is low due to the unfavourable initial conditions and low density of producers (low gross primary productivity)

  • However, the proportion of energy lost through community respiration is also relatively low

  • This means that net productivity in pioneer communities is relatively high

  • This allows the pioneer community system to grow and accumulate biomass

What are climax communities?

  • In climax communities (i.e. in the later stages of succession), gross productivity may be relatively high, due to a high density of producers (high gross primary productivity) and consumers (high gross secondary productivity)

  • However, this relatively high gross productivity is balanced by the large amounts of energy lost from the climax community system through respiration

  • This causes the net productivity of a climax community to approach 0

  • As this happens, the productivity–respiration (P:R) ratio approaches 1

    • This ratio reaches 1 when biomass and energy is being produced by the system at the same rate as it is being used

    • If the ratio >1, then excess energy and biomass is being produced

    • If the ratio <1, then more biomass and energy is being consumed than is being produced

    • To reach a stable (climax) community, there has to be an equilibrium between the community production and the community respiration

  • There is no one cl­­imax community, but rather a set of alternative stable states for a given ecosystem

    • What the climax community eventually looks like depends on a large variety of factors, including climate, the local soil properties, and a range of random events that can occur over time (e.g. extreme weather events, human interventions) 

      2-4-4-pioneer-and-climax-communities-a-1
      2-4-4-pioneer-and-climax-communities-b

Changes occurring in a community as it develops from a pioneer community into a climax community through the process of succession

Comparison of Pioneer and Climax Communities

Feature

Pioneer Communities

Climax Communities

Stage in succession

Early stages

Later Stages

GPP

Low

High

NPP as a % of GPP

High

Low

Species Richness and Diversity

Low

High

Niches

Fewer, wider

Many, narrow

Size of organisms

Small

Large

Species composition

Fewer species, adapted to harsh conditions

More species, adapted to stable conditions

Total biomass (amount of organic matter)

Low

 High

Soil depth

Shallow

Deep

Soil quality

Poor (little nutrients and organic material)

High (nutrient-rich and full of organic matter)

Growth rate

Rapid

Slower

Energy flow

Simple and linear

Complex and cyclic

Nutrient cycling

Less efficient, open system (external inputs)

More efficient, closed system (nutrients are recycled)

Dominant organisms

Lichens, mosses, algae, bacteria, and fungi

Woody plants, trees, and shrubs

Stability

Unstable, prone to disturbance and colonisation

Stable, resistant to disturbance and colonisation

Examples

Pioneer species like lichens and mosses on rocks

Ancient oak forests

Reproductive Strategies

Density-dependent and Density-independent Factors

  • In ecology, population growth and regulation are influenced by a range of biotic and abiotic factors. Some of these factors are influenced by the population density, while others are not

  • Density-dependent factors include factors such as competition, predation, parasitism, and disease

  • As the population density increases, the impact of these factors becomes more significant, resulting in a decline in the population growth rate

  • In this way, density-dependent factors acts as negative feedback mechanisms, leading to the stability and regulation of populations

  • Density-independent factors include natural phenomena such as floods, fires, hurricanes, and droughts, as well as anthropogenic activities like pollution, deforestation, and climate change

  • These factors affect the population growth rate irrespective of the population density, so their impact is similar across all populations regardless of their density

r-strategist Species

  • r-strategists are characterised by having a high reproductive rate, small body size, early maturity, and short lifespan

  • They are adapted to unstable and unpredictable environments and tend to be found in pioneer communities

  • These species tend to have a high growth rate and reproduce quickly, producing large numbers of offspring with little investment in each

  • They have a lower survival rate, but their high reproductive rate enables them to quickly recolonize and establish themselves after disturbances

  • Examples of r-strategist species include cockroaches, flies and some small mammal species

  • Populations of r-strategists are controlled by density-independent factors


Photo by MOHD AZRIEN AWANG BESAR on Unsplash 

Flies are r-strategists

K-strategist Species

  • K-strategists are characterised by having a low reproductive rate, large body size, late maturity, and long lifespan

  • They are adapted to stable and predictable environments and tend to be found in climax communities

  • These species tend to have a lower growth rate but invest more in each offspring, resulting in a higher survival rate

  • They are better able to withstand disturbances, allowing them to persist in stable environments

  • Examples of K-strategist species include large mammals

  • Populations of K-strategists are controlled by density-dependent factors

Photo by Glen Carrie on Unsplash

Large mammals such as rhinos are K-strategists

 

Comparison of r- and K-strategist Species

Feature

r-strategist species

K-strategist species

Reproductive rate

High

Low

Body size

Small

Large

Maturity

Early

Late

Lifespan

Short

Long

Growth rate

High

Low

Investment in offspring (parental care)

Low

High

Survival rate

Low

High

Level of specialisation

Generalist species

Specialist species

Controlled by

Density-independent factors

Density-dependent factors

Adapted to

Pioneer communities

Climax communities

Examples

Annual plants, insects, small mammals

Large mammals, trees, some reptiles

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Alistair Marjot

Author: Alistair Marjot

Expertise: Biology & Environmental Systems and Societies

Alistair graduated from Oxford University with a degree in Biological Sciences. He has taught GCSE/IGCSE Biology, as well as Biology and Environmental Systems & Societies for the International Baccalaureate Diploma Programme. While teaching in Oxford, Alistair completed his MA Education as Head of Department for Environmental Systems & Societies. Alistair has continued to pursue his interests in ecology and environmental science, recently gaining an MSc in Wildlife Biology & Conservation with Edinburgh Napier University.

Bridgette Barrett

Author: Bridgette Barrett

Expertise: Geography Lead

After graduating with a degree in Geography, Bridgette completed a PGCE over 25 years ago. She later gained an MA Learning, Technology and Education from the University of Nottingham focussing on online learning. At a time when the study of geography has never been more important, Bridgette is passionate about creating content which supports students in achieving their potential in geography and builds their confidence.