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The natural
succession of species is the vehicle through which life flows in time
and space.
The Earth and the sun complement each other. The vegetation and animal
life of our planet Earth convert the energy from the sun into organic
compounds. Each living being has a unique function that contributes either
directly to this process through plant, bacteria and green algae photosynthesis
and chemosynthesis, or, indirectly, through successive transformation,
intermediation, transport, optimisation, and acceleration processes. Excessive
solar energy transformed into organic compounds is deposited in swamps
(in time becoming carbon compounds) and in tropical oceans (with time
forming hydrocarbons and gas).
E. Götsch explains that life is organized in systems everywhere.
As time progresses life increases and becomes more complex resulting in
more elaborate systems (synthroptic processes) that are not static; on
the contrary, they are very dynamic.
The "colonizers" which can be found in soils that have been
destroyed, cliffs and overexploited sites, take the first step. For example,
the first to colonize barren rocks are bacteria that create the necessary
conditions for the development of moss and lichens. In turn, when they
have created the conditions that favour the development of other more
demanding species, pioneer plants start to develop, initiating the next
stage, the first Accumulation Systems.
Accumulation Systems are characterized by including plant
species with a wide carbon/nitrogen ratio. The lignin content of the organic
matter is high and; consequently, the decomposition of organic matter
such as leaves and ligneous parts is slow (accumulation of energy –
organic matter).
The fruits produced by trees found in the lignin system are not edible
by men or large animals. They are home to insects noxious to human beings,
small animals such as mice, poisonous snakes and small birds. As living
conditions are improved through the dynamics of life itself (succession
processes), other species that form part of the following Accumulation
Systems begin to appear.
It's easier for life to reach this state in soils which originated from
young granite rocks or basalt. Living conditions in the intermediary system
are better, given the closer Nitrogen/Carbon relation, the improved fruits
and seeds and the medium sized animals.
Abundance Systems are found at the peak of the complexity
chain. Normally, they are found in cilia and alluvial forests, in riverbeds
and hydrographical basins. These systems are the habitat of large animals
and its vegetation is characterized for the close Carbon/Nitrogen links.
The species found in the Abundance Systems are characterized for their
large fruits, rich in carbohydrates, fat and protein that are able to
support large animals. In order to survive, mankind, being a large animal,
needs the conditions prevalent in abundance systems.
Transformation processes in these abundance systems are intensive and
the flow of carbon is very high (greater activity of micro-organisms).
Within each of the systems described before there is a sequence regarding
the dominance of the different consortiums of species.
The consortiums that characterize the different stages are the following:
The degree of development
each system achieves is characterized by the development stage of the
predominant species considered in the natural succession. Thus, each system
has its own consortium of pioneer, secondaries and primary organisms,
that are also subject to variations depending on the ecological characteristics
of the site.
The principles of natural succession are, however, the same for all ecosystems.
Understanding the principles of natural succession and the species associated
to them in each stage and in each ecosystem is the key to achieving a
successful management of dynamic and stratified agricultural and forest
systems.
1. Pioneers
(up to 6 month)
After eliminating the primary layer of vegetation (as a result of slash
and burn practices, or when an emerging tree falls, leaving an empty space)
many pioneer plants and other species corresponding to the next succession,
begin to grow.
The majority of our short cycle crops belong to the pioneer group of the
Abundance System: Corn, Rice, Sweet Potatoes, Soybean, Beans, Squashes,
Tomatoes, Watermelon.
2. Secondary I (six month up to two years), II (two years up to
15 years)
The secondary vegetation is born along with the pioneers, dominating the
latter after one or two years. The secondary vegetation includes species
with different life cycles (two, fifteen, eighty years, approximately).
The most renowned species of secondary species with a short life cycle
(two to 15 years) in the Alto Beni Region of Bolivia are the following:
Manioc, Pineapple, Sugar Cane, Banana, Cecropias, Balsa wood, Ingas ssp.,
Cardamomo, Passion Fruit, Morera, Curcucma, Toco (Schizolobium amazónicum),
and others.
3. Secondary III with long life cycle (15 years up to 80 years)
Some of the species that form part of forests in process of becoming primary
forests are presented below - what we call a primary forest is also a
system who is in transition and subject to change.
Asaí (Euterpe ssp.), Pejibeye (Bactris gassipaes), Motacú
(Scheelea princeps) Oranges and other citric plants, Jacaratia cf. digitata,
Eritrina ssp., Guazuma ulmifolia, Jackfruit (Artocarpis altilis, Artocarpis
heterophylla), Guanabano - Tree, Soursop (Anona muricata), Lime, native
mandarin, Avocado (Persea americana).
4. Primary (> 80 years)
The primary consortium is composed by species of the "primary forest"
that dominate the secondary III species. Eventually, they become the upper
stratums and the trees emerging from the forest. The pioneers and the
different secundary species are born along with the primary species. For
the primaries to prosper they must be raised by the first.
Some examples of species found in a primary forest and of primary crops
of the Abundance System in Alto Beni are the following: Cocoa, Copuazú
(Theobroma grandiflora), Achachairú (Rheedia ssp.), Coffee, Cashew,
Mahogany (Swietenia macrophylla), Ceiba (Ceiba ccp.), Ochóo (Hura
crepitans), Ficus ssp., Rubber (Hevea brasiliensis), Brazil nut (Bertholletia
excelsa), Garlic tree (Gallesia integrifolia), etc.
Within a succession, in order to achieve a primary forest, none of the
stages of the natural succession can be left out. However, even if none
of the stages can be skipped, a proper intervention can accelerate some
of these processes.
In order to guarantee a successful and productive agroforestry
system, all species that form part of the system - at a given place, at
a given moment - should be planted.
Not respecting the natural succession process has consequences
Currently, we slash and burn primary forests in order to create adequate
conditions for our "pioneers". When we are no longer able to
grow these pioneers the land is left to rest, favouring the development
of species characteristic of the secondary forest. After 5 or 7 years
the secondary forest is slashed and burned and, once again, we grow species
that belong to the pioneer consortium. Depending on the soil and climate
conditions and as a consequence of this practice, the Abundance
System is degraded into an Advanced Accumulation
or even worse, a Poor Accumulation System. Pioneer species
of Abundance Systems are not able to grow in Accumulation
Systems. For a while, then, we insist in growing these crops
in adverse conditions, using chemicals and pesticides that simulate the
conditions prevalent in abundance systems, until the ecosystem is so degraded
that no crop of interest to us will be successful.
At this stage, many farmers plant pioneers of a secundary system such
as grasses. In the end they are expelled by pioneers of the lower secundary
Systems (e.i.: sujo - Imperata spp.). When this point is reached the soil
can no longer sustain cattle. As a consequence of the degradation of the
soils and ecosystems, natural disasters such as droughts, floods and hurricanes
begin to occur.
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