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US farmers struggle to plant crops amid extreme floods attributed to Climate Change

Extreme floods and the ongoing trade war have serverely impacted corn and soy crops in the US.

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Corn Crop
Photo by Todd Trapani.

Farmers in the US Midwest have been using the Twitter hashtag #NoPlant19 to document the floods as a result of one of the wettest springs on record.

There is a short window of opportunity – early June at the latest – in which farmers can plant corn before high temperatures and lack of rain leads to crop failure.

By May 28th, only 58 percent of expected corn planting had been completed according to the USDA-National Agricultural Statistical Service (NASS). Last year, this figure was 92 percent. Soybeans stand at just 28 percent.

Studies show that rising global temperatures due to human-caused global warming results in increased precipitation in some areas of the United States.

From the US Fourth National Climate Assessment: “Annual precipitation in the Midwest has increased by 5% to 15% from the first half of the last century (1901–1960) compared to present day (1986–2015)”. Winter and spring precipitation are important to flood risk in the Midwest and are projected to increase by up to 30% by the end of this century. Heavy precipitation events in the Midwest have increased in frequency and intensity since 1901 and are projected to increase through this century.”

A recent study found the damaging effects extreme rainfall has on crops: “Excessive rainfall as damaging to corn yield as extreme heat, drought”. “Excessive rainfall can affect crop productivity in various ways, including direct physical damage, delayed planting and harvesting, restricted root growth, oxygen deficiency and nutrient loss”.

Climate change could have servere consequences for global food systems if emissions continue to rise. The IPCC warns that crop yield decreases of between 10-25% may be widespread by 2050.

A trade war with China has also started to impact farmers, with China refusing to buy US crops such as soy.

Overall, this has resulted in a 3-year high for corn prices.

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Negative effects of Earth’s rising CO2 on plants and crops vastly outweigh positives according to overwhelming peer-reviewed evidence

Global food security is under threat according to a new UN report, and it’s compounded by extensive research that contradicts the tired climate denial claim that CO2 is good for plants.

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Photo by John Towner

A new IPCC report on land use concludes that global food security is under threat by human-caused climate change and rising CO2. This has been known for a long time, but the 2019 report will renew discussion about the agricultural challenges that humanity faces in a warming world. The report is preceded by overwhelming peer-reviewed research that rising CO2 is bad news for plants and crops. Let’s take a look at why the negatives vastly outweigh the positives.

1. CO2 fertilization is greening Earth

Firstly, we’ll acknowledge the positive that is widely quoted by climate skeptics. Yes, it is true that carbon dioxide fertilization is greening Earth. Plants with enough nutrients in the soil will green in response to increased CO2. However, there is a lot more to it. Is the fact that plants are greening really that beneficial? What about their nutrient content? Why are CO2 levels still rising? What impact will global temperature increases have? Now we’ll look at all the other impacts that rising CO2 has on plants and crops.

  1. Zhu, Z, et al. (2016). University of Exeter. Greening of the Earth and its drivers.
2. CO2 levels are still rising, while plants are becoming less effective carbon sinks

One might expect that plants would soak up all the extra CO2 caused by the burning of fossil fuels, after all, plants need CO2 to survive. But they are not, CO2 levels are still rising rapidly. Plants are struggling to be the carbon sinks we take for granted.

  1. See the Keeling Curve for current and past CO2 levels.
  2. Hubau, W, et al. (2020). Nature. Asynchronous carbon sink saturation in African and Amazonian tropical forests.
  3. Büntgen, U, et al. (2019). Nature. Limited capacity of tree growth to mitigate the global greenhouse effect under predicted warming.
  4. Brienen, R. (2015). Nature. Long-term decline of the Amazon carbon sink.
3. Rising CO2 is causing global heating and extremes of heat, drought, and flooding

The effects of global heating include rising temperatures and increasing extremes of heat, drought, and flooding.

A lack of water is devastating for plants and crops and is the “most important stress factor limiting plant life”. It reduces photosynthesis: Plants will slow down their production systems, close their stomatal pores (see 7.), and produce less chlorophyll. It causes protein synthesis issues: Plant proteins are drastically reduced, leading to gene alteration, and membrane disturbances that affect lipids crucial for plant growth. It also causes Wilting-Tugor Pressure.

Similarly, extreme flooding is not good news either: the water has little time to soak into the ground and instead washes away large amounts of soil and fertilizer.

Many plants and crops are also far less productive when faced with heat stress. For example, there is a significant reduction in maize yield for each day above 32 °C.

  1. Li, Y, et al. (2019). University of Illinois Urbana-Champaign. Excessive rainfall leads to maize yield loss of a comparable magnitude to extreme drought in the United States.
  2. Zhu, K, et al. (2016). Stanford University. Nonlinear, interacting responses to climate limit grassland production under global change.
  3. Liu, B, et al. (2016). Nanjing Agricultural University. Similar estimates of temperature impacts on global wheat yield by three independent methods.
  4. Hatfield, J, et al. (2015). United States Department of Agriculture. Temperature extremes: Effect on plant growth and development.
  5. Williams, C. (2014). Clark University. Heat and drought extremes likely to stress ecosystem productivity equally or more in a warmer, CO2 rich future.
  6. Silva, E, et al. (2013). Drought and Its Consequences to Plants – From Individual to Ecosystem.
  7. Hawkins, E. (2012). Increasing influence of heat stress on French maize yields from the 1960s to the 2030s.
  8. Battisti, D and Naylor, R. (2009). Historical Warnings of Future Food Insecurity with Unprecedented Seasonal Heat.
4. Crops are becoming less nutritious with a decrease in iron, zinc and protein

A decrease in the iron, zinc and protein content of crops as a result of rising CO2 and global heating has been observed by scientists around the world. Nutrient deficient countries will be disproportionately affected.

An increase in artificial fertilizer use is required. However, artificial fertilizer has other environmental impacts including emissions from ammonia and nitrous oxide, and a decrease in soil quality. It is also unaffordable for poorer farmers in third world countries.

  1. Beach, R, et al. (2019). International Food Policy Research Institute. Combining the effects of increased atmospheric carbon dioxide on protein, iron, and zinc availability and projected climate change on global diets: a modelling study.
  2. Zhu, C, et al. (2018). University of Tokyo. Carbon dioxide (CO2) levels this century will alter the protein, micronutrients, and vitamin content of rice grains with potential health consequences for the poorest rice-dependent countries.
  3. Myers, S, et al. (2014). Harvard University. Increasing CO2 threatens human nutrition.
  4. Loladze, I. (2014). Catholic University of Daegu. Hidden shift of the ionome of plants exposed to elevated CO2 depletes minerals at the base of human nutrition.
  5. Henao, J and Baanante, C. A. (1999). International Fertilizer Development Center, Alabama. Estimating Rates of Nutrient Depletion in Soils of Agricultural Lands of Africa.
5. The fertilization effect diminishes when nutrient limits are reached

A common argument in favour of rising CO2 is that farmers increase CO2 levels in their greenhouses to improve plant growth. However, this is because farmer greenhouses are controlled environments. The correct nutrients, water, and temperatures are provided in addition to the CO2.

Unfortunately there is no way to provide the correct amount of nutrients, water, and local temperatures across the entire planet. When uncontrolled plants and forests run out of nutrients, the fertilization effect is diminished.

Again, farmers can apply more artificial fertilizer to their crops, but as explained in section 4, this is not sustainable.

There is plenty of research on the nitrogen and phosphorus limitations of plants.

  1. Craine, J, et al. (2018). University of Maryland. Isotopic evidence for oligotrophication of terrestrial ecosystems.
  2. Wang, Z, et al. (2017). Auburn University. Phosphorus Limitation on CO2 Fertilization Effect in the Terrestrial Ecosystems.
  3. Martins, R, et al. (2017). Universidade Federal de Goiás. Effects of increasing temperature and, CO2 on quality of litter, shredders, and microorganisms in Amazonian aquatic systems.
  4. Weider, W, et al. (2015). Nature Geoscience. Future productivity and carbon storage limited by terrestrial nutrient availability.
  5. Norby, R, et al. (2010). Oak Ridge National Laboratory. CO2 enhancement of forest productivity constrained by limited nitrogen availability.
  6. LeBauer, D and Treseder, K. (2008). Ecology. Nitrogen limitation of net primary productivity in terrestrial ecosystems is globally distributed.
6. Rising CO2 is causing plants to thicken their leaves and become less efficient at sequestering carbon

The leaves of plants are becoming thicker in response to rising CO2, which may sound like a positive, but it’s not. The photosynthesis productivity and evapotranspiration of plants is reduced and their role as a carbon sink along with it, leading to even higher global temperatures.

  1. Kovenock, M and Swann, A. (2018). Leaf Trait Acclimation Amplifies Simulated Climate Warming in Response to Elevated Carbon Dioxide.
  2. Poorter, H, et al. (2009). Utrecht University. Causes and consequences of variation in leaf mass per area (LMA): a meta‐analysis
7. Rising CO2 results in a drier atmosphere due to a decrease in plant pores, in turn reducing global vegetation growth

The density of plant pores through which plants breathe have decreased by 34% in Florida. Plants are reacting to rising CO2 by being more conservative with water. At first glance this may seem like a positive sign that plants are adapting, but it disrupts the hydrologic cycle, resulting in a drier atmosphere and less rainfall. This has the knock-on effect of reducing global vegetation growth.

  1. Yuan, et al. (2019). Science Advances. Increased atmospheric vapor pressure deficit reduces global vegetation growth.
  2. Mankin, J, et al. (2019). Nature Geoscience. Mid-latitude freshwater availability reduced by projected vegetation responses to climate change.
  3. Lammertsma, E, et al. (2011). Indiana University. Global CO2 rise leads to reduced maximum stomatal conductance in Florida vegetation.
  4. Zhao, M and Running, S. (2010). Science. Drought-Induced Reduction in Global Terrestrial Net Primary Production from 2000 Through 2009.
8. Rising CO2 favours certain invasive plants such as flammable cheatgrass

There is no doubt that plants will adapt to climate change, but the question is which ones will survive? As you would expect, it’s the hardy, dominant and weedy species that will survive. These species are mostly troublesome and not very useful, beneficial or nutritious to humans or animals. One example is cheatgrass, which is flammable and fuels wildfires.

  1. Sheppard, C. (2014). Cambridge University. Does Elevated Temperature and Doubled CO2 Increase Growth of Three Potentially Invasive Plants?
  2. Yu, T, et al. (2010). Washington University in St. Louis. Variability in C3-Plant Cell-Wall Biosynthesis in a High-CO2 Atmosphere by Solid-State NMR Spectroscopy.
  3. Smith, D. (2000). Nature. Elevated CO2 increases productivity and invasive species success in an arid ecosystem.
9. Rising CO2 is reducing the protein concentration of pollen essential to bees

Goldenrod pollen is becoming less nutritious due to rising levels of CO2 according to a Purdue University study. Pollen helps bees maintain immunity from pathogens and parasites. According to co-author Jeffery Pettis, research entomologist with the U.S. Department of Agriculture’s Agricultural Research Service: “Declines in pollen protein could potentially threaten bee health, survival, and weaken bees’ ability to overwinter on a continental scale. Previous research shows bees have shorter lifespans when fed lower quality pollen.”

Co-author Jeffrey Dukes, professor of forestry and natural resources and biological sciences said: “The impact of carbon emissions on the nutritional value of our food supply is something people need to be aware of. This issue isn’t just relevant to honeybees and people – it will probably affect thousands or even millions of other plant-eating species around the world. We don’t yet know how they’ll deal with it.”

  1. Ziska, L, et al. (2016). US Department of Agriculture. Rising atmospheric CO2 is reducing the protein concentration of a floral pollen source essential for North American bees.
10. Rising CO2 causes an increase in insects eating plants and a decrease in plant defense against invasive insects

According to plant fossils from the PETM around 55 million years ago, increased insect herbivory was found as a result of rapidly rising CO2. In simple terms, the warmer temperatures meant insects were eating more plants. Compounding this is the impairment of a key component of a plant’s defenses against leaf-eating insects due to elevated CO2.

  1. Deutsch, C, et al. (2018). Science. Increase in crop losses to insect pests in a warming climate.
  2. Currano, E, et al. (2008). Penn State. Sharply increased insect herbivory during the Paleocene–Eocene Thermal Maximum.
  3. Zavala, J. (2008). University of Illinois at Urbana-Champaign. Anthropogenic increase in carbon dioxide compromises plant defense against invasive insects.
11. Human activity in China and India dominates the greening of Earth

According to a recent Nature study, over a third of the greening of Earth is due to humans. The greening in China is from forests (42%) and croplands (32%), but in India is mostly from croplands (82%) with minor contribution from forests (4.4%). The increase in croplands is thanks to fertilizer use and surface and/or groundwater irrigation.

As mentioned above, farmers can increase the use of artificial fertilizer in response to rising CO2, but this is not natural. So if humans planting trees and applying fertilizer is responsible for over a third of greening, then the amount of natural greening due to rising CO2 on uncontrolled plants is far less than previously thought.

  1. Chen, C, et al. (2019). Nature. China and India lead in greening of the world through land-use management.

The content of this article may change to ensure it is up to date with the latest research. If you would like to suggest improvements or contribute to this article, please contact us.

Last Updated: 5th March, 2020

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Linking India’s heat waves and water shortages to Climate Change

Increasing heat waves and droughts are making India’s water crisis even worse.

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India
Photo by Ibrahim Rifath.

INDIA is currently experiencing servere heat waves and water shortages with temperatures reaching 50°C in the Northwest.

Churu, a city in the desert region of Rajasthan, was the hottest place, reaching 50.8°C on June 1st.

Monsoon season typically begins around 1st June, and this year it arrived a week late on India’s southwestern coast, in Kerala, on Saturday 8th June. It could take another few weeks to work its way up the country and replenish the heavily drought-stricken regions.

In the the city of Chennai, several reservoirs used as primary sources of drinking water have dried up. People are relying on water tankers to deliver water at cost. The water scarcity is compounded by the lack of rain in 2018. States such as Maharashtra and Rajasthan are also suffering water shortages.

21 major cities in India are expected to run out of groundwater as soon as 2020, affecting ~100 million people, according to the Composite Water Management Index (CWMI) report. It states that 40% of India’s population will have no access to drinking water by 2030.

Some of the groundwater shortages are due to poor management of supplies, increasing population, and rapid urbanisation. But Climate Change has made the problem worse, and increasingly so in the near future according to serveral studies:

Increasing heat waves, droughts, and floods

A 2013 report from The World Bank states that a decline in monsoon rainfall since the 1950s has been observed, while the frequency of heavy rainfall events has increased. This triggers more frequent droughts as well as greater flooding in large parts of India.

Extended drought periods, and a significant increase in monsoon flows with enhanced flood potential, are predicted for The Ganges, Brahmaputra and Meghna river basins, which serve a population of over 650 million, according to a 2015 study.

A 2010 study by the Postdam Institute for Climate Impact Research (PIK) looked specifically at the Indian city of Hyderabad. Currently the city has a maximum of 5 heat wave days per year. Under the highest emissions scenario this is predicted to jump to 40 days per year by 2100.

In India’s Economic Survey 2017-18, the Sustainable Development, Energy and Climate Change section states: “For the 1981-2010 period, the mean, maximum and minimum temperatures increased almost at an equal rate of around 0.2°C per decade, which is much higher than the trends for the period 1901-2010. Daily rainfall observations during the period 1901-2004 indicate that the frequency of extreme rainfall events (rain rate > 100 mm/day) has a significant positive trend of 6 per cent per decade.”

Increasing heat-related mortality

According to a 2017 study, future climate warming will lead to substantial increases in heat-related mortality, especially in developing low-latitude countries, such as India: “Mean temperatures across India have risen by more than 0.5°C [between 1960 and 2009], with statistically significant increases in heat waves” – “The increase in summer mean temperatures in India over this period corresponds to a 146% increase in the probability of heat-related mortality events of more than 100 people.”

What can be done?

Governments should communicate drought and flood warnings to the population more effectively and sooner – not just information that a drought or flood is occuring, but also a plan of action.

Improvements to drought and flood management are needed. A drought manual was produced in 2016, but its content faced opposition from some states. Another report titled “Good Practices on Drought Management and Response in India” was made available in 2018 by Sphere India.

Rewilding natural basins and improving infastructure for collecting rainwater are especially important in cities such as Bangalore.

Improved water supplies to rural areas – often those that suffer the worst impacts – are needed.

The country also has yet to declare a climate emergency.

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