CO2 fertilization effect

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The CO2 fertilization effect or carbon fertilization effect causes an increased rate of photosynthesis while limiting leaf transpiration in plants. Both processes result from increased levels of atmospheric carbon dioxide (CO2).[1][2] Earth System Models (ESMs), Land System Models (LSMs), and Dynamic Global Vegetation Models (DGVMs) are used to investigate and interpret vegetation trends related to increasing levels of atmospheric CO2.[3][4] However, the ecosystem processes associated with the CO2 fertilization effect remain uncertain and therefore are challenging to model.[5]

The carbon fertilization effect varies depending on plant species, air and soil temperature, and availability of water and nutrients.[3][6] Net primary productivity (NPP) might positively respond to the carbon fertilization effect.[7] Although, evidence shows that enhanced rates of photosynthesis in plants due to CO2 fertilization do not directly enhance all plant growth, and thus carbon storage.[3]

Terrestrial ecosystems have reduced atmospheric CO2 concentrations and have partially mitigated climate change effects.[8] The response by plants to the carbon fertilization effect is unlikely to significantly reduce atmospheric CO2 concentration over the next century due to the increasing anthropogenic influences on atmospheric CO2.[2][3][9][10] Earth's vegetated lands have shown significant greening since the early 1980s[11] largely due to rising levels of atmospheric CO2.[12][13][14][15] However, the direct causes of increased vegetation are still widely debated, demonstrating the need for continuous, long-term data collection and analysis on responses to the carbon fertilization effect.[16]

Studies led by Trevor Keenan from the Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab) show that, from 2002 to 2014, plants appear to have gone into overdrive, starting to pull more CO2 out of the air than they have done before. The result was that the rate at which CO2 accumulates in the atmosphere did not increase during this time period, although previously, it had grown considerably in concert with growing greenhouse gas emissions. Keenan concluded “Unfortunately, this increase is nowhere near enough to stop climate change.”[17]

Theory predicts the tropics to have the largest uptake due to the carbon fertilization effect, but this has not been observed. The amount of CO2 uptake from CO2 fertilization also depends on how forests respond to climate change, and if they are protected from deforestation.[18]

How plants store CO2[]

Through photosynthesis, plants use CO2 from the atmosphere, water from the ground, and energy from the sun to create sugars used for growth and fuel.[19] While using these sugars as fuel releases carbon back into the atmosphere (photorespiration), growth stores carbon in the physical structures of the plant (i.e. leaves, wood, or non-woody stems).[20] With about 19 percent of Earth’s carbon stored in plants,[21] plant growth plays an important role in storing carbon on the ground rather than in the atmosphere. In the context of carbon storage, growth of plants is often referred to as biomass productivity.[20][22][23] This term is used because researchers compare the growth of different plant communities by their biomass, amount of carbon they contain.

Increased biomass productivity directly increases the amount of carbon stored in plants.[20] And because researchers are interested in carbon storage, they are interested in where most of the biomass is found in individual plants or in an ecosystem. Plants will first use their available resources for survival and support the growth and maintenance of the most important tissues like leaves and fine roots which have short lives.[24] With more resources available plants can grow more permanent, but less necessary tissues like wood.[24]

If the air surrounding plants has a higher concentration of carbon dioxide, they may be able to grow better and store more carbon[25] and also store carbon in more permanent structures like wood.[20] Evidence has shown this occurring for a few different reasons. First, plants that were otherwise limited by carbon or light availability benefit from a higher concentration of carbon.[26] Another reason is that plants are able use water more efficiently because of reduced stomatal conductance.[27] Plants experiencing higher CO2 concentrations may benefit from a greater ability to gain nutrients from mycorrhizal fungi in the sugar-for-nutrients transaction.[28] The same interaction can may also increase the amount of carbon stored in the soil by mycorrhizal fungi.[29]

Free-Air CO2 Enrichment (FACE) experiments[]

The ORNL conducted FACE experiments where CO2 levels were increased above ambient levels in forest stands.[30] These experiments showed:[31]

  • Increased root production stimulated by increased CO2, resulting in more soil carbon.
  • An initial increase of net primary productivity, which was not sustained.
  • Faster decline in nitrogen availability in increased CO2 forest plots.
  • Change in plant community structure, with minimal change in microbial community structure.[32]
  • Enhanced CO2 cannot significantly increase the leaf carrying capacity or leaf area index of an area.[32]

FACE experiments have been criticized as not being representative of the entire globe. These experiments were not meant to be extrapolated globally. Similar experiments are being conducted in other regions such as in the Amazon rainforest in Brazil.[33]

Decreases in minerals and impacts on human nutrition[]

Empirical evidence shows that increasing levels of CO2 result in lower concentrations of many minerals in plant tissues. Doubling CO2 levels results in an 8% decline, on average, in the concentration of minerals.[34] Declines in magnesium, calcium, potassium, iron, zinc and other minerals in crops can worsen the quality of human nutrition. Researchers report that the CO2 levels expected in the second half of the 21st century will likely reduce the levels of zinc, iron, and protein in wheat, rice, peas, and soybeans. Some two billion people live in countries where citizens receive more than 60 percent of their zinc or iron from these types of crops. Deficiencies of these nutrients already cause an estimated loss of 63 million life-years annually.[35][36]

References[]

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