Secondary Succession

Secondary Succession Definition

One of the two main forms of ecological succession, secondary succession is the process relating to community growth or change that takes place when a habitat is disturbed or damaged.

Whilst primary succession takes place when pioneer species inhabit a newly formed substrate lacking in soil and biotic organisms (such as rock formed from lava flow or areas of glacier retreat), secondary succession occurs on a substrate that has previously supported vegetation but has been altered by processes such as fire, hurricanes, floods or human disturbances.

Secondary succession is usually faster than primary succession because soil and nutrients are already present due to ‘normalization’ by previous pioneer species, and because roots, seeds and other biotic organisms may still be present within the substrate.

Examples of Secondary Succession


Fire is one of the most common causes of secondary succession and is an important component for the renewal and vitality of many types of ecosystem. Fires may either take place naturally, for example when lightning strikes a dry habitat, or may involve controlled, systematic burning of a landscape by humans.

Both the abiotic and biotic components of an ecosystem can be drastically altered by the presence of fire. The most notable abiotic feature that is affected by fire is the soil; CO2, CO and CH4 stored within the organic material is released into the atmosphere during the combustion process; however, this initial loss of nutrients is often counterbalanced and then increased by the decomposition of leftover plant material which leaches N, P and K back in to the soil. 

The moisture retention of the soil also increases due to the reduction of transpiration by plants, and because more water is allowed to reach the soil surface where interception of rain by leaves is greatly reduced or non-existent. Soil pH often rises (more alkaline) after a fire due to the combustion of acids.

After a fire, species start to recolonize an area, beginning the secondary succession process. The first species to colonize are usually fast growing herbaceous plants, such as conifers or ferns, which require high levels of light. These species are often already present in the form of seeds within the soil, or are able to rapidly disperse from nearby areas. 

In time, slow growing, shade-tolerant, woody species begin to suppress the early successional species, which are in-turn replaced or shaded by large trees, eventually leading to the generation of forests and a climax community.

The physical and biotic characteristics of an ecosystem, as well as the level of disturbance (determined by the intensity and frequency of fires), create a mosaic of habitats within an area. 

This mosaic effect allows a more diverse range of species to colonize than in an area that is ecologically stable for a long period of time. The types of plants and animals able to recolonize an area after fire are dependent on the properties of the soil, as well as climate and topography.

Harvesting, Logging and Abandonment of Crop Land

The abandonment of land previously utilized for crops is a common cause of human-induced secondary succession. Land which has been intensively cultivated is often nutrient poor, with the nutrients having been repeatedly removed through harvest or logging. Agricultural processes also often leave the soil vulnerable to high levels of erosion. 

The abandonment of such land allows plants and animals that were previously unable to inhabit the area to colonize. Early succession of vegetation following the abandonment of farmland is responsible for increases in soil organic content, nutrient density and soil porosity. The addition of shrubs and of root systems within the soils, which follow in later succession, acts as a natural barrier against erosion, thereby allowing for restoration of degraded habitats.

The process of secondary succession on human altered landscapes differs to that of succession after a natural event due to the homogenization of soil type and nutrients, especially where artificial fertilizers have been applied. This can lead to the exclusive colonization of an area by generalist species, which slows the succession process and does not allow for such high biodiversity.

Renewal After Disease

If a disease affects all of a certain species within an area, the species is likely to experience a rapid die-off. Although the onset of disease can be a catastrophic event for a particular species, once the living crop has entirely died off and the disease therefore eradicated, if the roots or seeds remain in the soil, the crop can repopulate. Alternatively, the disease can kill enough of a species to allow for invasion by species which may have been previously unable to colonize, which in turn enables a more diverse range of species to inhabit an area.

Gap Dynamics

Although secondary succession can happen on a large scale and have an intense effect on a habitat or ecosystem, it is most common on a small scale. The disturbance and subsequent secondary succession that occurs after a gap is created in a forest canopy, following the death and collapse of a single tree or the loss of a large branch, is known as gap dynamics; the effect is often most prevalent in dense forests. 

The creation of a gap in a canopy allows light to penetrate to the forest floor, giving herbs, shrubs, vines and seedlings an opportunity to exploit the new resource. After a few years, fast growing, taller plants begin to dominate the lower canopy, suppressing the growth of the shade-intolerant species of the lowest canopy level but allowing shade-tolerant species to thrive. Heliophilic (sun-loving) species begin to dominate the top of the canopy after around 75-150 years, while the shade-tolerant species of the lower canopies establish a stable community. This stable state is known as a climax community, and will remain in equilibrium until a new canopy gap is created.

Related Biology Terms

  • Primary Succession – The type of succession that occurs on a new rock or substrate devoid of vegetation or other organisms.
  • Climax Community – The state of relative stability or equilibrium of species composition, occurring when a community does not experience any disturbance for long periods of time.
  • Pioneer Species – The hardy species that are first to colonize a newly disturbed or formed habitat, beginning the process of ecological succession.
  • Ecological Disturbance – A temporary change within a habitat, that causes notable differences to an ecosystem’s biotic or abiotic elements.


What is secondary succession?

Secondary succession is a type of ecological succession that occurs in an area that has been disturbed or disrupted, but where some soil or life remains. Examples of disturbances that can trigger secondary succession include fires, floods, and human activities such as logging or agriculture.

How does secondary succession differ from primary succession?

Primary succession occurs in an area where there is no soil or life present, such as on newly formed volcanic rock or in areas that have been completely denuded by a glacier. In contrast, secondary succession occurs in an area where some soil or life remains after a disturbance.

What are some examples of secondary succession?

Examples of secondary succession include the regrowth of a forest after a fire, the recolonization of a field or meadow after farming activities have ceased, and the restoration of a wetland after it has been drained or filled.

What factors influence the rate and outcome of secondary succession?

The rate and outcome of secondary succession can be influenced by a variety of factors, including the severity and duration of the disturbance, the availability of seeds and propagules, and the presence of invasive species. Additionally, the history of land use and management practices can impact the trajectory of secondary succession.

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