Transcript ALGAE
ALGAE
Algae are emerging to be one of the most promising long-term, sustainable
sources of biomass and oils for fuel, food, and bio-fertilizer. What makes them so
attractive are the large number and wide variety of benefits associated with how
and where they grow.
Nearly all these benefits stem from the fact that these plants have evolved over
billions of years to produce and store energy in the form of oil, and they do this
more efficiently than any other known natural or engineered process.
Algae grow quickly and can double their numbers every few hours, can be
harvested daily, and have the potential to produce a volume of biomass many
times greater than that of our most productive crops.
Algae are both autotrophic (grown using sunlight) and heterotrophic (grown
without sunlight). Algae consumes carbon dioxide (CO2) like any other plant
releasing oxygen (O2) into the atmosphere.
How Do Algae Reproduce?
Single-celled algae typically reproduce asexually by fission or division of a cell into
two or more new cells. Some single-celled algae reproduce sexually, through
either the fusion of two cells or the exchange of genetic material between cells.
Most multi-celled algae reproduce by a process called alternation of generations,
in which one generation reproduces asexually and the next sexually. In one
generation, a cell called a spore develops directly into a new organism.
Benefits of Algae in Agriculture
Algae is a promising new source of sustainable agriculture and improves plant
growth in several ways.
It helps break up clay and compacted soils, assists in transferring micronutrients
from the soil to the plant, enhances water retention, increases seed germination
rates, penetration, and stimulates development of microflora populations in soils.
Algae essentially helps move micronutrients from soil to plant. Its benefits have
been proven both experimentally and in the field.
Clay Disaggregation
Clay particles normally lay together flat, but are
repelled by the negative charges across their face.
Salt (Na+) is present in minor amounts.
Soils with high clay content can become so dense and compact that they may
resist plant rooting. This may happen due to clay compaction or salt overload.
First, when the percentage of clay in the soil is very
high, and especially when an excessive amount of
salt is present, the positive charge on the edge of a
clay particle combines with the negative charge on
the flat surface of another, forming a tight three
dimensional structure as shown.
Clay Disaggregation
Secondly, salt in the soil can neutralized the negative electrical charges
which normally cause clay particles to repel each other.
This salt overload causes clay platelets to attract
each other resulting in soil collapse as shown.
This is a condition seen in irrigated regions world
wide, where soil salinity is a growing problem.
Increased Water Penetration
Algae cells cause the clay particles to stand on end,
allowing water penetration. It accomplishes this in two
ways:
First, it segregates salts and removes them from the
surface of the clay particle. The net negative charge
resulting causes the clay particles to repel each other,
loosening the soil structure.
Second, carbonic acid (H2CO3) molecules bond with the edge of the positively
charged particles and breaks the attractive force between the positive charge at
the edge of a particle and the negative charge or the flat surface of another.
This action, called protective colloidal action, loosens soil, letting roots penetrate
more easily.
Water Sequestration
Algae holds cations in a way they can be more easily
absorbed by a plant's root, improving micronutrient
transference to the plant's circulation system.
Decayed algae slows water evaporation from soils. This is especially important in
soils where clay is not present or in a low concentration, in arid areas, and in
sandy soils without the capability to hold water.
In the presence of water, cations absorbed by algae partially ionize and move a
short distance away. This restores part of the bonded ion's positive attractive
force.
Reduced Water Evaporation
Since water is a dipolar molecule and
electrically neutral, and the algae electrically
negative, the end of the molecule containing
the oxygen atom loosely bonds to the ion. The
hydrogen or negative end of the water
molecule is partially neutralized, and as a
result, increases the hydrogen end's positive
attracting force. The oxygen (or negative) end
of another water molecule bonds with the
hydrogen end and this continues until the
attractive force of the water molecule is
dissipated.
Evaporation is minimized. The oxygen end of another water molecule bonds with
the hydrogen end of another, until the evaporation rate is reduced by 20%
Atmospheric Nitrogen Fixers
Algae are a photosynthetic nitrogen fixing group that survives in wide variety of
habitat, soil and water. They fix atmospheric nitrogen in aerobic condition by
heterocyst, specialized cell, and in anaerobic condition.
This fixed nitrogen can be absorbed by plants and converted to protein and
nucleic acids. Each individual cell of algae typically has a thick, gelatinous cell
wall.
Fertilizer Chelation
Algae have the ability to chelate fertilizer components and increases their release
to plants in an organic form. If you make judicious use of algae and fertilizer, you
will improve the performance of marginally fertile soils, of soils with low native
organic matter, and of crops grown in arid regions.
Microorganism Stimulation
Algae completes their life cycle and becomes a source of phosphate and carbon,
stimulating microflora populations. It also provide sites for microflora to colonize.
The bacteria secrete enzymes which act as catalysts, liberating calcium and
phosphorous from insoluble calcium phosphate, and iron and phosphorous from
insoluble iron phosphate.
Cleaner Irrigation Tape System
The drip irrigation system is a lifeline for high value horticulture/agriculture crops.
However for the success of drip irrigation systems proper maintenance is required.
To keep irrigation tape systems clean, treatment with acid is needed to dissolve
precipitates of lime (calcium carbonate) and calcium residue from fertilizer applied
under high pH conditions in the irrigation system.
Once algae are injected into the irrigation system, it starts releasing carbon
dioxide (CO2). The carbon dioxide and water combine to form Carbonic Acid
(H2CO3). This mild acid dissolves built up lime and calcium residue.
Reviving a plugged drip tape will improve germination, maintaining a homogenous
wet pattern for distributing fertilizer and pesticides.
Lets Call Algae by a Different Name
Bio-Fertilizer
Bio-fertilizer is a substance which contains living microorganisms which, when applied
to seed, plant surfaces, or soil, colonizes the rhizosphere or the interior of the plant
and promotes growth by increasing the supply or availability of primary nutrients to
plants. Bio-fertilizers add nutrients through the natural processes of nitrogen fixation,
solubilizing phosphorus, and stimulating plant growth through the synthesis of
growth-promoting substances. Bio-fertilizers can be expected to reduce the use of
chemical fertilizers.
The microorganisms (algae and bacteria) in bio-fertilizers restore the soil's natural
nutrient cycle and build soil organic matter. Through the use of bio-fertilizers, healthy
plants can be grown, while enhancing the sustainability and the health of the soil.
Therefore, they are extremely advantageous in enriching soil fertility and fulfilling
plant nutrient requirements by supplying the organic nutrients through microorganism
and their byproducts.
Hence, bio-fertilizers do not contain any chemicals which are harmful to the living soil.
Bio-fertilizers provide eco-friendly organic agro-input and
are more cost-effective than chemical fertilizers.
Algae use benefits:
Improves soil structure and aeration.
Improves seed germination.
Improves root development by encouraging deeper penetration.
Improves water penetration and utilization.
Improves fertilizer uptake by chelation.
Stimulates beneficial microorganisms.
Is an organic Bio-Fertilizer.
Provides salt buffering.
Increases soil fertility by releasing nutrients locked in the soil.
Reduces tillage cost by softening the soil.
Provides water lateral movement.
Cleans drip irrigation tape.
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