Elevated carbon dioxide level and plant productivity.

in #stemng6 years ago

Carbon dioxide happens to be an important component in the nutrition of photosynthetic organisms. Inorganic carbon in the form of carbon dioxide combines with water molecules to produce a carbohydrate from which other secondary products such as starch are formed. The process of photosynthesis is impossible without the presence of chlorophyll which absorbs solar radiation that catalyses the splitting of water molecules and the eventual release of the electrons that will drive the remaining process. The entire process is summarized in an equation thus;

6CO2 + 6H2O --------------> C6H12O6 + 6O2

There are two phases of reaction that add up to give the equation of photosynthesis. In the light reaction, water molecule is spliced to release oxygen, adenosine triphosphate (ATP) is synthesized in a chemiosmotic process and finally, nicotinamide adenosine dinucleotide phosphate (NADPH) which functions as an electron carrier is generated. Both ATP and NADPH synthesized in the light reaction are utilized in the second phase, the dark reaction. This is the phase during which carbon dioxide is utilized in the synthesis of carbohydrate as shown by the above equation.


pixabay image:Only the green portions of plants can photosynthesize

Another biological reaction in which carbon dioxide plays an important role is respiration. During this process, organic compounds (synthesized from photosynthesis) are broken down in order to unlock the energy present in them. Carbon dioxide and water are produced as a result, in addition to the energy in form of adenosine triphosphate. Thus;

C6H12O6 + 6O2--------------> 6CO2 + 6H2O

Interestingly, the equation of photosynthesis seems to be a reversal of that of respiration. The end products of photosynthesis are the starting products of respiration while the end products of respiration are the starting products of photosynthesis.

Both reactions are part of the important processes that sustain life, although photosynthesis is limited to the organisms belonging to the plant kingdom while respiration takes place in all living organisms. Photosynthesis involves the conversion of solar energy from the sun to chemical energy which is usually locked up in the organic product. Respiration, on the other hand, has to do with the breaking down of organic products and the release of energy within them.

For a plant to survive and continue growing and developing, the rate of producing food must exceed the rate of breaking down food. Both photosynthesis and respiration go on simultaneously in the plant. The difference in the rate of the two reactions is referred to as net productivity/photosynthesis. Hence, plants must have positive net productivity in order to continue living. The two processes, however, are incomplete without carbon dioxide being an important reactant/product.

Over the years and since the ushering in of the era of industrial revolution, the concentration of carbon dioxide in the atmosphere has increased tremendously from as low as 280 ppm in pre-industrial era, to 403 ppm as at years 2016 and 408 ppm as at July, 2018 (although this has been disputed in some corners). According to International Protocols on Climate Change, the atmospheric concentration of CO2 keeps surging at the rate of 1.8 ppm yearly. The reason for this surge in concentration is not far-fetched and has been comprehensively discussed in various scientific quarters and articles.


It keeps rising! CC BY-SA 3.0, Link

One would ordinarily expect that a surge in the atmospheric level of carbon dioxide is supposed to cause an increase in the rate of photosynthesis and perhaps a decrease in respiration rate due to the internal partial pressure of the gas in the body of the plant. In fact, several scientific investigations have reported an increase in plant's productivity as a result of artificial elevation of CO2 in the ambient air. In 2016, Lamani et al. reported a direct positive correlation between elevated CO2 and photosynthetic rate in Santalum album, a plant species rich in heartwood and essential oil. In a similar experiment conducted by some Japanese researchers in 2017, Chinese yam and rice were found to have higher productivities with elevated CO2 levels, although the effect was more pronounced in yam than in rice. On the other hand, respiration rates was found to be hindered with elevated level of the gas in soy bean cultivars. However, the later event has been a major source of controversy among scientists.

The reports on Santalum album, Chinese yam and rice only acknowledged CO2 as the sole determiner of the rate of photosynthesis/productivity. This might not be entirely true in that both water and CO2 (along with some other biotic factors) play important role as the reactants in the biochemical process. Would an increase in ambient CO2 level without a corresponding increase in water really result in an increased rate of photosynthesis? This question was somehow illuminated on by some Chinese researchers in 2014 where they reported that only interactive effects of an elevated CO2 level and water could bring about an increase in productivity in maize.

However, the situation might not be as simple as to follow Le Chatelier's principle or some reaction laws. Carbondioxide needed for photosynthesis enters primarily through the stomata, diffuses through the intercellular air spaces within the leaf and eventually find its way down to the reaction center (dark reaction of photosynthesis). The stomata regulate the absorption and release of carbon dioxide as well as loss of water (evapotranspiration) from the leaf surfaces.


Structure of stomata By CNX OpenStax - CC BY 4.0, Link

The number of stomata present per unit area of leaf (stomata density) has been known to vary among different species, genus, families, orders, class and different plant divisions. Furthermore, the density has also been reported to vary along with several environmental factors such as sunlight, atmospheric temperature, humidity etc.

The relative importance of carbon dioxide to climate scientists has led to a special interest in the response of stomatal density to changes in the atmospheric concentration of the gas. Several experiments have been conducted and reports have emerged linking the atmospheric concentration of carbon dioxide to the number of stomata on the leaf surface. Although this is purely on species to species basis, the correlation established between the stomatal index and the atmospheric concentration of the gas is being used to estimate the geologic concentration of carbon dioxide through the studies of related plant species.

It has been established that the stomatal density on leaf surfaces decreases in response to elevated carbon dioxide level in the short term, meaning that plants naturally have a way of limiting the amount of carbon dioxide in their systems irrespective of the concentration of the gas in the ambient air. If this were to be true, what mechanism leads to increased photosynthesis as a result of increased concentration of carbon dioxide? Your contributions would be highly appreciated.

Thank you for reading.

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I wonder what is the rate of a photosynthetic process that would be able to be carried out by plants? How long would it take for a plant to convert carbon dioxide into oxygen and how efficient can they provide oxygen to living things. If the concentration of carbon dioxide is on the rise, that would mean the rate at which photosynthesis processes trying to meet the metabolic demand for oxygen is failing year by year, isn't it?

Thanks for your audience. Photosynthetic rate varies from species to species and is limited by several biotic factors. Hence, it is not easy to attach a figure to it. Concerning the efficiency in relation to oxygen production, since plant themselves use oxygen during respiration, it is best calculated as net oxygen production which by all means is related to net productivity. Elevated carbon dioxide level has been found to increase photosynthesis in some species and also reduced respiration in some. It is still an active area of research.

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The so enlarged structure of the stomata really made made me a believer in its dynamic nature (opening and closing during gaseous exchange)
Nature is just wonderful

As regard your question, i might not really be able to give a satisfactory answer but one thing I know for sure is that, the negative feedback loop comes into play in such situations.

Just the way humans body detect that there low sugar level and as such release the glucagon hormone which activate the release and breakdown of glucose from glycogen. There is always a compensatory mechanism to balance deficits

You might be right. These processes have genetic controls and scientists are already investigating the possibilities. Aside from the fact that stomata aperture is dynamic, the number also exhibit a similar trend in relation to ambient carbon dioxide concentration. Thanks for your constructive feedback.

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Thanks utopian

While CO2 can acidify an environment, I am unaware of harm CO2 in potential concentrations does to plants. Rather than limiting the CO2 they uptake, I suspect the reduction in stomatal density observed as CO2 concentrations increase is a result of the plant simply needing fewer to gain necessary CO2 to feed.

There are other limits on plants, including biogenic, which restrict their growth. Ecosystems are complex tradeoffs, and in the Pacific Northwest the apex tree in the forest is the Hemlock, not the Douglas Fir, which grows faster and taller. By tolerating the shade of the Doug Fir, the Hemlock can wait for it's competitor for canopy space to senesce and die, and then assume it's place.

Thanks for an excellent article!

Thanks for your invaluable contributions. I believe there are genetic aspects to these events in the long term. Even with fewer stomata, CO2 level can still rise. Does this mean a time might come when some plant species would have very minute stomata number or even at all? Perhaps no. This means there are complex genetic processes in play which scientists are perhaps yet to understand.

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Great article, thanks for sharing! Photosynthesis also occurs in a curious way in some types of plants, such as MAC; which can use carbon dioxide quite efficiently

You mean CAM? Crassulacean Acid Metabolism. You are quite right with that. CAM plants are very efficient in utilizing carbon dioxide and need a very low concentration of it to function.

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I upvoted your post.

Best regards,
@Council

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While I cannot truly say what led to the increase in the yield of the crop in question, however, I believe everything in life has a means of moderating against excesses. So it makes sense that stomata moderates amount of gaseous carbon dioxide intake.

Such a well writing article sir. Thumb up!

Thanks for such a thoughtful comment bro. It is always my pleasure.