High-Nutrient, low-chlorophyll

HNLC stands for "high-[1]^[2] Instead, these regions are limited by low concentrations of metabolizable iron.^[1] There are two popular explanations for the existence of HNLC regions: the iron hypothesis and the ‘grazing control hypothesis'. HNLC regions cover 20% of the world’s oceans in three major areas: equatorial Pacific Ocean, subarctic Pacific Ocean and the Southern Ocean.^[1][2]

Iron hypothesis

The iron hypothesis proposes that a lack of iron in the ecosystem prevents phytoplankton from achieving an algal bloom.^[2] Iron is necessary for nitrogen fixation which is required for the production of amino acids.^[1][3] This iron limitation inhibits the growth of larger phytoplankton, such as diatoms. Instead, HNLC regions are characterized by small phytoplankton flagellates which can take up iron at lower concentrations due to greater surface area to volume ratios.^[3]

Grazing control hypothesis

Small phytoplankton can be preyed upon by micro-zooplankton known as protozoan grazers. Protozoa are capable of reproductive rates equal to or exceeding that of their phytoplankton prey, therefore preventing any significant increase in phytoplankton populations, including blooms.^[3] Since phytoplankton biomass is kept in check, nutrients are never depleted, causing the high nitrate concentrations that define HNLC regions.

Antarctic paradox

The term "Antarctic paradox" is used in ecology to describe the phenomenon that vast areas of the Southern Ocean contain plenty of nutrients for phytoplankton to thrive but still, the phytoplankton do not grow much. These areas have been termed as HNLC (high nitrate, low chlorophyll) areas. Suggested reasons for this are that iron concentrations are low^[4] and deep mixing reduces the amount of light available for photosynthesis.^[5]

See also

• Antarctic krill
• Iron fertilization
• Iron Hypothesis
• John Martin (oceanographer)
• Marine snow
• Primary production

References

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