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Plants cannot live on CO2 alone

What the science says...

Select a level... Basic Advanced

More Carbon Dioxide in the atmosphere is not necessarily good for plants.

Climate Myth...

CO2 is plant food

Earth's current atmospheric CO2 concentration is almost 390 parts per million (ppm).  Adding another 300 ppm of CO2 to the air has been shown by literally thousands of experiments to greatly increase the growth or biomass production of nearly all plants.  This growth stimulation occurs because CO2 is one of the two raw materials (the other being water) that are required for photosynthesis.  Hence, CO2 is actually the "food" that sustains essentially all plants on the face of the earth, as well as those in the sea.  And the more CO2 they "eat" (absorb from the air or water), the bigger and better they grow. (source: Plants Need CO2)

At a glance

Have you ever tried growing vegetables in a container? If you are a newbie who wants to give it a try, you will quickly become familiar with the following point. With many species and varieties, it's a lot easier to grow them in a well-tended bed than in a bucket.

Most vegetables grow best in a bed of mature, nutrient rich soil that has had regular addition of compost over the years. The only things you need to do are watering them when it's dry and picking off the slugs. But in a bucket, even with a lot of compost from the garden centre, plants often struggle without the help of regular feeds of liquid additives to boost things along. Such feeds include various nitrogen compounds, phosphorus, potassium, iron, zinc and other essential trace-metals.

The purists among us prefer not to expend hard-earned cash on such feeds because they are expensive - defeating the whole object of grow-your-own which is to produce good vegetables cheaply. Managing that precious commodity, topsoil, so that it is productive year upon year is what we do instead. To be a successful gardener, looking after your soil is probably the most important skill to gain and apply.

But what about the person who thinks like the myth-provider in the box above? They seem to know about photosynthesis. Photosynthesis is the process by which plants extract carbon dioxide from the atmosphere and, using the energy received from sunlight, make it react with water in their cells. The products of that reaction are sugar and oxygen. Oxygen is released back to the atmosphere and the plants stash away the reserves of sugar within their stems, tubers or roots, depending on the species. But our myth-provider seems to think that because photosynthesis only requires CO2 and water, then high levels of both are all that's required for happy plants. How will their garden grow?

Well, basically they are going to find their attempt to grow vegetables immensely frustrating. Increasing the plants' CO2 supply alone and ignoring all the other essential compounds for plant health is a shortcut to unhealthy crops - if they produce any appreciable crop at all. That's the difference between being a good gardener and a hopeless one. The good gardener acts on the basis of the whole big picture, not just one part of it.

Please use this form to provide feedback about this new "At a glance" section. Read a more technical version below or dig deeper via the tabs above!


Further details

An argument made by those who prefer to see a bright side to climate change is that carbon dioxide (CO2) being released by the burning of fossil fuels is actually good for the environment. This conjecture is based on simple and appealing logic: if plants need CO2 for their growth, then more of it should be better. We should expect our crops to become more abundant and our flowers to grow taller and bloom brighter.

However, this "more is better" philosophy is not the way things work in the real world. There is an old saying, "Too much of a good thing can be a bad thing." For example, if a doctor tells you to take one pill of a certain medicine, it does not follow that taking four is likely to heal you four times faster or make you four times better. It's more likely to make you sick.

It is possible to boost growth of some plants with extra CO2, under controlled conditions, such as inside a greenhouse. Based on this, deniers make their claims of beneficial botanical effects in the world at large. Such claims fail to take into account something of critical importance. Increasing the availability of one substance that plants need is insufficient. All other nutrient supplies need to be adjusted correctly too, for benefits to occur. In addition, the claim fails to take into account that a warmer earth will see an increase in deserts and other arid lands, reducing the area available for crops.

Plants cannot live on CO2 alone. A complete, healthy plant metabolism depends on a number of major and trace elements. Just as increasing the amount of starch alone in a person's diet won't lead to a more robust and healthier person, for plants additional CO2 by itself cannot make up for deficiencies of other essentials.

What would be the effects of an increase of CO2 on agriculture and plant growth in general?

  1. CO2 enhanced plants will also need extra water both to maintain their larger growth and to compensate for greater moisture evaporation from their tissues as the heat increases. Where will the water come from? In many places rainwater is not sufficient for current agriculture and the aquifers they rely on are running dry (Zwarteveen et al. 2021; overview of the global situation at Encyclopedia of Earth here.

    On the other hand, precisely as predicted by climate research, we are experiencing more intense storms with increased rainfall rates throughout much of the world. One might think that this should be good for agriculture. But no: when rain falls in short, intense bursts it does not have time to soak into the ground. Instead, most of it quickly runs off into creeks, then rivers, and finally out into the ocean, often carrying away large amounts of soil and fertiliser in the process.

  2. Unlike Nature, conventional agriculture does not self-fertilise soils by recycling all dead plants, animals and their waste. Instead we need to add artificial fertilisers to the soil all the time. Those chemicals are produced by energy-intensive processes mostly fed by hydrocarbons, especially natural gas. Increasing the need for such fertilisers competes for supplies of natural gas, creating friction between other needs and the manufacture of fertilisers. This will ultimately drive up the price of food.

  3. Although the situation is complex and varies from one plant-group to another, too high a concentration of CO2 may cause a reduction of photosynthesis (Long et al. 2004). There is also evidence from the geological past of major damage to a wide variety of plant species from a sudden rise in CO2 (Currano et al. 2008; Delucia et al. 2008; Fig. 1). Higher concentrations of CO2 also reduce the nutritional quality of some staples, such as wheat (Bloom et al. 2010).

     Fossil leaf damage from the early Eocene

    Figure 1: Fossil leaf damage from the early Eocene series, around 55 million years ago. At that time, Earth experienced a rapid jump in global CO2 levels that raised temperatures across the planet. Now, researchers studying plants from that time have found evidence that the rising temperatures boosted the foraging activity of insects. As modern temperatures continue to rise, it is considered likely that the planet will see increasing crop damage and forest devastation. Source: Science Daily; Feb. 15, 2008 and Currano et al. 2008).

  4. The worse problem by far is that increasing CO2 will raise temperatures. This will make the world's arid climatic zones shift towards the poles. However, soil conditions at higher latitudes will not necessarily support productive agriculture. Extensive and intensive management will be required. Long-term research has also looked at how plants respond to a high-CO2 environment. While some plants exhibit a brief and promising burst of growth, other effects such as the "nitrogen plateau" soon truncate this benefit.

  5. Plants raised with enhanced CO2 supplies and strictly isolated from insects behave differently than if the same approach is tried in an otherwise natural setting. For example, when the growth of soybeans is boosted out in the open, this creates changes in plant chemistry that makes these specimens more vulnerable to insects, as Fig. 2 shows.

     Plant defences go down as carbon dioxide levels go up.

    Figure 2: Plant defences go down as carbon dioxide levels go up. Soybeans grown at elevated CO2 levels attract many more adult Japanese beetles than plants grown at current atmospheric carbon dioxide levels. Science Daily; March 25, 2008 and Delucia et al 2008. (Credit: Photo courtesy of Evan Delucia)

In conclusion, even assuming there are any positive impacts on agriculture in the short term, such impacts are highly likely to be overwhelmed by the negative impacts of climate change. Added CO2 will likely shrink the geographical range available to plants while increasing the size of deserts. It will also increase the requirements for water and soil fertility, both things already coming under pressure. It will increase plant damage from insects. Increasing CO2 levels would therefore only be beneficial within highly controlled spaces with other nutrient requirements adjusted accordingly.

Last updated on 24 December 2023 by John Mason. View Archives

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Myth Deconstruction

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Comments

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Comments 1 to 25 out of 48:

  1. John (JC); I really don't see the need for redundant posts. It's somewhat like the multiple "planets warming" posts that can and have been incorporated into one rebuttal. The general public may have heard of both statements (titles): 1. CO2 is plant food 2. Too much of a good thing is a bad thing. Increasing Carbon Dioxide is not good for plants. Nonetheless, for the sake of streamlining, there should be one rebuttal. Perhaps the title could be changed, in order to capture the attention of the layman whose mind might be more focused on one phrase rather than the other. If you think that re-titling, for the sake of removing redundant posts, is recommended please let me know and I will think of something.
  2. Correction on the above post. Should read: 1. CO2 is plant food. 2. CO2 is good for agriculture. They're the same idea but the layman might search for one phrase versus the other. Hence the possible title change to incorporate both phrases.
  3. Did the title change on the twin post,"Too much of a good thing is a bad thing. Increasing Carbon Dioxide, as 'plant food', is not good for plants."
  4. Villabolo, making an argument that CO2 is merely plant food is understating the fact. Carbon is a fundamental building block for all life forms, plants being about 45% carbon, whilst animals including humans are less than 20%. Interestingly, by comparison the carbon content of coal ranges from about 30% in low rank coals such as lignite to 45% to 85% for the most used form of bituminous coal, up to to 98% in anthracite. However what I am interested in is the statement "Higher concentrations of CO2 also reduce the nutritional quality of some staples, such as wheat." Are you able to quantify both the reduced nutritional quality along with any associated increased yields as determined by the better performing varieties that have been tested in open field trials under enriched CO2 conditions?
  5. johnd @ #4: "Are you able to quantify both the reduced nutritional quality..." Johnd; unfortunately my link is to an abstract with a paywall. I could research it, but I don't believe it would be appropriate for a basic level rebuttal. I try to keep basic level rebuttals at a High School level for laymen interested in the subject of GW but not the details or specifics. As for the argument that CO2 is "plant food", that is the phrase that skeptics use in order to give the simplistic idea that more "food" will help all plant life.
  6. "Inputs to Photosynthesis" The first stage involves the photolysis of water by sunlight (this is the only place where oxygen is released to the atmosphere). This diagram: http://www3.sympatico.ca/n.rieck/images/photosynthesis-chloroplast.jpg ...is proof that sunlight (input 1) and water (input 2) are more important than CO2 (input 3) but each ingredient is considered a limiting factor to maximum photosynthetic productivity. "Push vs Pull" Just as eating (push) a protein supplement will not make you muscular unless you exercise (pull) which creates a demand for protein. So simply adding more CO2 (push) will not make photosynthesis run at a higher rate, unless CO2 was the only limiting factor. On top of that, CO2 has risen 24% since I've been alive (395/315) so we should have seen an explosion of plant life as compensation for the additional CO2 but we have not. "Drop in Photosynthesis due to Temperature" There is considerable published evidence showing that C3 photosynthesis production drops by 10% for every "F" degree over 76. Why? The stoma on the underside of leaves is the place where "CO2 enters" and "H20 can escape". At 86F most C3 plants have closed their stomas 100% to stop water loss (but this also stops photosynthesis). C4 and CAM plants have adaptations to deal with higher temperatures but the adaptations come at a cost (some of the solar energy powers the additional molecular machinery). Pineapple is one example of a CAM plant (hint: CO2 is pulled in at night). BTW, 85% of all plants are C3
  7. It seems a shame that apparently no one informed on global warming is also informed about declining soil fertility. As a result, consequences of declining soil fertility are incorrectly said to be caused by global warming. This article on CO2 is a good example. Depending on their protein requirement to be healthy, plants require a certain level of soil fertility. This soil fertility is based on the minerals necessary to support life. In low soil fertility the plants are primarily carbonaceous or high in carbohydrates with low protein content. As such, they are of little use to support animal life in health. As soil fertility is increased, the protein content of the plants is increased as a percentage of the dry matter and the carbohydrate content is decreased. This allows a greater density of animal life per acre. Plants being damaged by insects indicate malnourished plants that are growing in soil that cannot meet their protein requirements. Increase the soil fertility and you won't need to worry about insect damage. Adding NPK only to soil to increase fertility only creates an unbalanced soil that causes the grower to go back to the same guy who sold the grower the NPK for the poisons to treat the symptoms of the low soil fertility, i.e. the insects doing the damage, the weeds out competing the crop and the diseases the plants are getting. When it rains in conditions of high soil fertility, the top soil acts as a blanket allowing the rain to soil into the soil and thereby to gradually go down into the subsoil raising the water table. In conditions of low soil fertility the shallow surface top soil not only absorbs little water from a rainfall, it actually often seals the surface so that very little water penetrates during a rainfall and this runoff often causes erosion of the soil itself. Downstream the drainage from a large land area can often result in floods. Later in the year the complaint is about a lack of rainfall and high temperatures and the increasing severity of droughts. In droughts it is usual for the high heat to damage the protein of the plants more than the lack of water. If the plants are damaged but are not wilting, the problem is the heat, not a lack of water, i.e. corn firing in a drought. Wind or rain are necessary but not sufficient for soil erosion. The "dust bowl" is an example of a result of declining soil fertility. Where can someone learn about the consequences of declining soil fertility and perhaps, as I have, come to the conclusion that blaming consequences of declining soil fertility on global warming is a scientific mistake and we should direct our primary climatic ecological concern to the former, not the latter? "The Albrecht Papers" by the soil scientist, William A. Albrecht, Ph.D.
  8. Soilfertility @ 7, After wading through your post, I find you said
    blaming consequences of declining soil fertility on global warming is a scientific mistake
    Excuse my ignorance, but exactly which scientific papers are you referring to? I cannot recall ever hearing a scientist blame 'consequences of declining soil fertility on global warming'. It sounds suspiciously like a strawman argument to me.
  9. Hi Doug: I said that I have come to the conclusion that blaming consequences of declining soil fertility on global warming is a scientific mistake. I did not say that any scientist has ever written a scientific paper blaming the consequences of declining soil fertility on global warming. I am not aware of any global warming research scientist who has knowledge of the consequences of declining soil fertility that would allow his or her writing of such an paper. What lead to my coming to that conclusion was, as I suggested at the end of my post answering the question I posed, was my reading of papers left by the late soil scientist, William A. Albrecht, Ph.D. In his papers, Albrecht explains many consequences of declining soil fertility. Albrecht did not address global warming as he was dead before global warming became an issue. Around the middle of the last century, Albrecht explained how declining soil fertility was increasing the severity of weather hazards such as floods and droughts. He also explained that the soil fertility controls the erosion of the soil itself with lower soil fertility being the primary cause, not the wind or rain. With respect to CO2, the subject of the article above, he explains how the carbon dioxide dissolving in the rain creates a weak carbonic acid that is beneficial in increasing soil fertility by breaking positive ions necessary for life (such as calcium, magnesium and potassium) out of rocks that contain these elements when such rocks are still in the soil. This certainly suggests how to restore or increase soil fertility when parent rocks containing these minerals have been exhausted from the soil and soil fertility is necessarily declining. If you wish to read an article I wrote I titled "Albrecht on Droughts and Soil Fertility" you can read it here: http://thebovine.wordpress.com/2012/08/11/droughts-and-soil-fertility/ Hopefully it might inspire you to wade through Albrecht's papers which I think will serve you better than wading through a post of mine.
  10. Soilfertility @ 9, you said
    I have come to the conclusion that blaming consequences of declining soil fertility on global warming is a scientific mistake
    I asked you for evidence that scientists have made such a mistake, but you have not produced any. Who, exactly, is making this "scientific mistake"? Where is your evidence? Without support for your allegation, it appears you have constructed a strawman argument. I am sure Albrecht makes some interesting points about soil fertility, but what precisely is the connection with the topic of this thread?
  11. Hi Doug: I was commenting on numbers 1,3,4,5 and 6 in the list of "...the effects of an increase of CO2 on agriculture and plant growth in general". I was not commenting on any topic on this thread. I thought comments were invited to made on the article itself. In the article I wrote for "The Bovine" titled, "Albrecht on Droughts and Soil Fertility" I have included references to where in Albrecht's papers I came across the evidence. I am not going to retype that article here. If you have any interest whatsoever in challenging the evidence provided by Albrecht you might just go and read the article and then tell me where I am wrong. Ignoring evidence does not refute it. I don't know the name of the person who wrote this article but the person's lack of knowledge of the consequences of declining soil fertility has resulted in the mistake of blaming more carbon dioxide in the air for consequences that are actually caused by declining soil fertility. In conditions of higher soil fertility there would be no need to plant trees and trees would grow better free from insect and disease problems and they would thereby do a better job of removing carbon dioxide from the air and they would make better firewood. If you knew that agriculture produces food for yield at the expense of its nutritional value, would you be concerned? If you would be concerned about this, that would give you another reason to wade through Albrecht's papers which would serve you better than wading through any post of mine.
  12. Soilfertility @11, you introduced your original comment by saying, "... consequences of declining soil fertility are incorrectly said to be caused by global warming." Your evidence of this is that certain predicted consequences of global warming are also predicted consequences of reduced soil fertility. You proceed to make the unjustified assumption that any observed feature that is predicted as a consequence of both global warming and of decreased soil fertility is in fact only a consequence of reduced soil fertility. Your argument fails at that point. Your assumption is unjustified. It appears to be worse, however. You point out that decreased soil fertility can result in increased floods and drought due to, respectively increased water runoff, and decreased water retention. You then simply assume the increased floods and droughts actually experienced are due to reduced soil fertility without providing evidence of that reduces soil fertility at the locations of said floods and droughts, or even checking rainfall figures to see if they have changed over time (they have). So not only do you assume that decreased soil fertility is the proper explanation without examining the evidence, you do so even when it is against the evidence.
  13. Soilfertility @ 11, I am still puzzled by your comments. Where in points 1,3,4,5 and 6 in the list, is there a scientific error? You are the one asserting there has been a scientific mistake. No-one is disputing the rôle of soil impoverishment on plant growth. Exactly what error(s) are you claiming?
  14. Hi Tom: Your assumption that my argument "fails at that point" is unjustified. Why? You have failed to review Albrecht's evidence. If you would only have read the article I mentioned on "The Bovine", it would have directed you to Albrecht's article, the basis for the article on "The Bovine". Albrecht's article, titled "Droughts-- The Soil As Reasons For Them", is chapter 23 in Volume I of "The Albrecht Papers". This is the first paragraph from his article: "When one follows the meteorological reports rather regularly since most of us talk about the weather, at least when the radio reports it for us daily, one might well be asking with serious concern, 'How come that we keep on breaking flood records, heat records, past records for droughts or for extent of long-time rain free periods and other weather records?' Are the meteorological conditions changing for the worse, or are the biological manifestations of weather, labeled as drought, merely intensified and on the increase as reciprocal to some other factor under serious decline through which the same meteorological disturbances are magnified in their detrimental aspects? We have larger floods and we have more severe droughts as the records truly report. But should we not examine these in relation to the soil for possibly more comprehensive explanations of them and our reduction or prevention of the disasters?" From the introduction to the chapter: "This paper was read before the 11th Annual Meeting of the American Institute of Dental Medicine, Palm Springs, California, 1954." "The Albrecht Papers" Volume I has been reprinted and is now titled, "Albrecht's Foundation Concepts" and is available from Acres, U.S.A. Also at Acres, U.S.A. there is an article available for download by Albrecht titled, "The Drought Myth--An Absence of Water is Not the Problem. It is available in this list of articles- http://www.acresusa.com/toolbox/articles.htm
  15. Soilfertility @14, your response has simply confirmed my point. First, you respond by quoting Albrecht from 1954, having previously made the point that "Albrecht did not address global warming as he was dead before global warming became an issue". If he did not address global warming, then he cannot have analysed which of two potential causes (global warming or loss of soil fertility) has had the greatest impact on changes in climatology. Ergo, if you are basing your claims on Albrechtson (as clearly you are), you have not shown of any particular droughts, floods, temperature rises, etc that loss of soil fertility rather than global warming is responsible. You specifically mention an article by Albrechtson titled "The Drought Myth--An Absence of Water is Not the Problem". Well, in Southwestern Australia an absence of water is clearly the problem: What is missing in Southwestern Australia is water falling from the sky as frequently, something that is not under the control of soil fertility. Southwestern Australia is a good test case, because the connection between winter rainfall and climate change is straightforward; there has been no appreciable loss of soil fertility (probably the opposite as agriculture in the region is based on irrigation turning desert into wheat fields); and Albrechtson almost certainly never studied the region. Yet because of his studies of the dustbowl you expect his explanation to trump straightforward science in Southwestern Australia. I look forward to your evidence based proof that the decline in rainfall in Southwestern Australia is caused by declining soil fertility, or your acknowledgement that your assumption that any consequence predicted by both global warming and decreased soil fertility is explained by decreased soil fertility alone.
  16. Hi Tom: Where did I say that Albrechtson (sic) analysed which of two potential causes has had the greatest impact on changes in climatology? When I said he was dead before global warming became an issue, I assumed the reader would realize that, of course, it would have been therefore impossible for him to make such an analysis. Have you read the article I wrote or "The Drought Myth--An Absence of Water is Not the Problem"? I can understand if you have not yet read "Droughts-- The Soil As Reasons For Them" as you might not find the book in your local library and you might need to purchase it and have it sent to you. I cannot understand, however, if you have not yet read either my article or "The Drought Myth--An Absence of Water is Not the Problem" or both as they are both available on the internet. If you wish to challenge my position on causes and cures for increasing severity of droughts and floods, read the evidence that has caused me to come to my conclusions and refute that evidence.
  17. Soilfertility @ 14
    "This paper was read before the 11th Annual Meeting of the American Institute of Dental Medicine, Palm Springs, California, 1954."
    A reading in front of a Dental Medicine meeting does not constitute peer review. As Tom pointed out, Albrecht wrote his work without referring the the then-extant body of work on global warming, so there is no reason to believe that he came to any valid conclusions about the phenomena he reported. To claim, as you do, that current science is mistaken because a person who did not know about global warming wrote a paper without mentioning it, is wrong-headed. To cut to the chase, can you post one single factoid Albrecht wrote about, which current science is mistaken about? Hint: don't expect others to do your research for you, as you are currently doing by making vague claims about it all being explained in Albrecht's paper and your article. Instead, reply with quotes from and references to the information you are relying on and remember to include quotes from and references to the scientific publications that show current science is mistaken. The onus is on you to provide evidence. Remember, extraordinary claims require extraordinary proofs.
  18. From Volume I of "The Albrecht Papers", "It's the Soil That Feeds Us", subsection 2 "more fertility means more cover, stable soil and less erosion". I quote Albrecht's words: "When soils erode, our first reaction prompts us to take up the fight against running water. Much like when some disease comes over out body, we think first about 'fighting' the microbes. When we break a bone, we put the limb in splints. Similarly when a field is broken down by gulleys, we line it up with terraces. Whether it is our soil or our body that is in trouble, we fail to realize the preceding but gradual weakening of our body or bones and of the soil body, too. The weakening occurs long before the noticeable disaster of the fracture or the gulley befalls us. Broken bones too often are the result of malnutrition for a long time ahead to make them weak. Coffee and toast don't maintain bone strength. Unsteadiness in muscle may have come along with the weakening skeleton to bring on the fall as well as the weak and broken bones. In like matter, the exhaustion of the strength of the soil, its fertility, weakens the soil body to make erosion the consequence. That such are the facts for the soil body is suggested by the experimental plots on Sanborn Field at the Missouri College of Agriculture. That field, after 62 years [in 1960] of its recorded behaviours, is a sage in telling us what the experiences of the soil body mean in bringing on what can be 'old age' of it. Two plots have been planted to corn each year since 1888. Professor J.W. Sanborn outlined the use of six tons of barnyard manure annually on one of these, while the other was expected to go forward in corn production with no soil treatment. Fortunately these two plots are alongside each other. There is a good sod border on three sides, or in the direction water might run on these seemingly level areas. All of the crop, namely grain and fodder, is removed. Outside the return of the fertility in six tons of manure on the one plot, the management and history of these two classic soils has been exactly the same. That the removal of the fertility without return on any on the 'no treatment' plot has weakened the soil body to make it erosive is now clearly evident. Had the sod border not protected this plot, its soils--like so much from the rest of Missouri--would now be resting in the Gulf of Mexico near New Orleans. After that soil body is turned by the plow, a single rain is enough to hammer it flat, to seal over the soil's surface, to prevent infiltration of the rainwater, and to bring on erosion of that fraction of the surface so readily and so highly dispersed into slush by the raindrops. Where manure had been going back regularly each year, naturally there was a different soil body. It stood up under the rain and maintained its 'plow-turned' condition in spite of the rain. It was the same rain that was so damaging to the other plot. One could not blame the rain for any damage here on this manure plot. Instead, the rain brought benefit. Its water went deeper into the soil. It soaked a deeper layer and built up the stored water supply for the summer. The surface soil is cooler by 10 degrees in the summer than the companion plot. Here is a different soil body that behaves different under the same rainfall. It doesn't erode. The rills of running water begin at the line that divides the two plots. Narrow as these two plots are, there are rills on the 'no treatment', but none on the 'treated' plot. The former might seem to be a call to 'fight' the running water. The latter is not. Fortunately the 'strength' of the soil body against erosion in this case is also the 'strength' of the soil for crop production. It is also the 'strength' for soil granulation or good soil structure. The corn yield is still twice as large on the plot with manure as that on the plot without it. Weeds grow on the former after corn roots are deep enough to be beyond their use of the nitrates whcih accumulate on the surface to invite the weeds. There weeds are a nice 'winter cover'. They are one that comes without any cost. The granulation of the soil of the manured plot is so much better under laboratory test than that of the unmanured one, that water goes into the soil three times as rapidly. Also, it moves about four times as much volume of water down through and does not plug itself up quickly to stop water movement into the soil. Here is 'strength' of granulation. It is the 'strength' of the soil body under the hammering effects of the falling rain. It is the 'hidden' strength, and the very same strength that gives the bigger yields of crops. That 'strength' is the fertility. This fertility is distributed withing the inorganic as well as the organic fraction of the soil. Here is quiet testimony that we ought to see that the weak soil body, and the erosion of it, are brought on because we have removed the fertility, or the creative power, by which any soil naturally keeps itself in place and grows nutritious crops at the same time. Our weakening soil body is suggesting that gradually weakening human bodies are resulting from it." The observations made comparing these two plots speak to increased water runoff making floods more severe, the lack of water in the soil or subsoil making the consequences of a period of little or no rainfall a more severe drought and to how a soil, weakened by a loss of fertility, would be more severely eroded by either wind or rain. As a result, regardless of your belief as to the cause of more severe droughts, floods and soil erosion, would the better approach to mitigate the damage caused by these problems be to lower the average temperature of the planet by reversing global warming or to figure out how to restore the lost fertility to the soil?
  19. Soilfertility @ 18, nothing in your post seems to support your claim that scientists are mistaken in any way about the effects of global warming. At last, though, you ask a direct question that can be answered:
    would the better approach to mitigate the damage caused by these problems be to lower the average temperature of the planet by reversing global warming or to figure out how to restore the lost fertility to the soil?
    That's a no-brainer: lower the average temperature of the planet back to what it should be without our insane injection of greenhouse gasses into the atmosphere, by magically removing the excess of those gasses; that way we not only counter the effects on our soils, but also bring other systems back into balance (e.g: stop the acidification of the oceans). Second best choice: hold the current levels of greenhouse gasses, by drastically slowing our emissions. Why? Because we can repair soils in a suitable climate at our leisure, but we can do nothing about them in the climate we are creating. Putting fertility back into the soil will not save us from the future we are creating.
  20. Soilfertility: Are you serious when you suggest we should throw away decades of climate science based on a paper presented to a bunch of dentists in the 1950's??? You assert that these unreveiwed claims from 60 years ago are worth more than the considered opinion of thousands of scientists in the IPCC report? Why have no current soil scientists stepped to the plate with this data if it is so good??? Please provide an up to date citation or your basic point is useless. You are not being serious with your wild claims that a single scientist, who was not peer reviewed, in 1960 is right and everyone else is wrong. Provide current data to support your wild claims.
  21. Michael Sweet @20, Albrecht (50 years ago) showed that improved soil fertility results in: 1) Improved water retention in the soil, enabling plants planted in that soil to better resist drought; 2) Reduced water runoff during light and moderate rainfall, reducing the risk (but not the possibility of) flooding; 3) Cooler soil temperatures during the day, and no doubt warmer soil temperature at night - probably a result of improved water retention increasing the thermal capacity of the soil. These are, now, well known and uncontroversial results. Soilfertility, not Albrecht, now appears to claim without any support from Albrecht or independent evidence, that improving soil fertility is an adequate mitigation strategy by itself for the effects of global warming. He has previously appeared to claim that loss of soil fertility is in fact responsible for many of the observed consequences of global warming. Again, this is without evidence and certainly without evidence from Albrecht. Soilfertility's claims are, or course, without merit. He provides no evidence of wide spread loss of soil fertility, and modern farming practices attempt to improve soil fertility. Uncultivated land is unlikely to have either lost or gained soil fertility because it is in a near equilibrium state with its environment. Ergo, Soilfertility has no basis beyond mere assertion for any claim that the increased frequency of floods, droughts etc are due to a loss of soil fertility. Equally he has no basis beyond mere assertion for any claim that improving soil fertility would mitigate the effects of climate change. On top of that, his discussion is plainly off topic; repetitive and amounts for the most part to sloganeering. His wall of text quotation @18 probably does not violate additional comments policies, but is clearly contrary to the spirit of them.
  22. There is a refreshingly excellent article on Mongabay.com, quoting scientists who specialize in tropical forests, countering a recent study's disinterpretation as meaning that CO2 rise will result in more tropical rainforests.

  23. The first link in point 3 of the basic explanation is bad.
  24. Given the information presented in the following article, an update of this rebuttal may be in order.

    Climate change making food crops less nutritious, research finds
    High

    CO2 levels significantly reduces essential nutrients in wheat, rice, maize and soybeans, Nature paper reveals

    Damian Carrington, The Guardian, May 7, 2014 

  25. Hey guys, CO2 is not plant food.  It is a reactant along with water for photosynthesis.  The food of plants, as well as everything other living organism,  is glucose which it makes itself through photosynthesis.  More CO2 in the atmosphere would increase photosynthesis, however a plant only gives off oxygen during the light dependent reactions.  It uses oxygen during cellular respiration 24 hours per day.  Therefore, the increase in oxygen in the atmosphere from an increase in CO2 would be more than offset by the increase in the consumption of oxygen when a plant undergoes cellular respiration which happens 24 hours a day. 

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