Glyphosate’s Role in Preserving the Environment and Biodiversity
As the population grows, the agricultural industry is continuously working to grow healthy crops with less impact on the environment. That means using less land and natural resources, preserving biodiversity, reducing greenhouse gas emissions and helping to ensure that soils stay rich with nutrients.
Explore some of the key environmental benefits of glyphosate, revealed through extensive research on its impacts:
Honey bees and other insects play an essential role in the production of many crops.
This is because many crops are not wind-pollinated but depend heavily on pollinating insects. Almonds are almost entirely dependent upon honey bee pollination, and without honey bees, there would be far fewer blueberries, squash, watermelon and other fruits to harvest. It’s why farmers – and the broader agricultural industry – work so hard to protect honey bees through a variety of partnerships and initiatives.
It may sound surprising, but global honey bee populations have actually increased by 65 percent since the early 1960s.1 And their continued growth is really important.
Honey bees face a number of challenges ranging from disease and forage, to the Varroa mite, to poor nutrition and weather. And because they are so critical to the environment, there has been much discussion about whether glyphosate-based herbicides could harm important pollinators and other beneficial arthropods.
In a study evaluating the potential effects of plant protection products at worst-case exposure rates under field conditions,
Glyphosate products have been extensively tested in the laboratory and in the field to evaluate potential toxicity to honey bees. This extensive testing has found, when used according to the label, that glyphosate products pose no acute or chronic adverse effects to honey bees.3,4,5 For example, a comprehensive study by Thompson et al (2014) found no adverse effects on adult bee survival or bee brood survival or development in honeybee colonies treated with glyphosate, even at levels that exceed environmentally realistic exposures.
In addition, regulatory authorities, such as the European Food Safety Authority (EFSA)6 and the U.S. Environmental Protection Agency (EPA)7, conduct comprehensive evaluations to ensure crop protection products, such as glyphosate, can be used safely for the environment. As part of this process, the regulatory authorities specifically evaluate the potential for effects on non-target organisms, including honey bees.7 Regulatory authorities only approve products that pose no unreasonable risk to the environment.
What researchers have also found is that by using glyphosate, farmers can ensure more productive harvests while using less land. This is a result of decreased competition, because weeds compete with crops for nutrients, water, sunlight and space. By decreasing the amount of land needed to grow crops, farmers can preserve the important habitat and forage area that honey bees and other insects, birds, frogs and beneficial organisms need to thrive.
Extensive tests have been conducted to examine the potential impacts of glyphosate on wildlife. These studies play an essential role in governmental safety reviews of glyphosate and collectively they demonstrate that glyphosate’s approved uses do not pose a threat to the health of animal wildlife.
Glyphosate products have been trusted for use in protected habitats such as the Galapagos Islands and the Florida Everglades to protect the native flora from invasive weed species.
We aim to ensure bountiful harvests while preserving the environment.
Through our work developing innovative products and solutions, we promote and are constantly seeking to improve sustainable farming practices.
Tillage, which involves turning over the soil, has been practiced as a form of weed control for generations. While tillage can be effective in controlling weeds, it also releases greenhouse gases stored in the soil and contributes to erosion – which can rob the soil of nutrients, make it difficult for soil to absorb water and cause runoff. Precise application of glyphosate-based herbicides can help farmers to leave the soil intact, producing measurable environmental benefits that are contributing to a more sustainable future.
Glyphosate has become a very useful tool for protecting soil fertility. One of the greatest benefits of glyphosate is its ability to foster healthier soils by reducing the need for tillage (or plowing).
By using glyphosate-based herbicides, farmers can leave their soil intact while the previous year’s crop residue or organic matter remains on top of the soil. This significantly increases the amount of nutrients and microbes – tiny bacteria that assist plants as they grow – in the soil. In addition to creating a thriving environment for plant roots, using no-till and reduced till practices has been shown to reduce soil erosion by as much as 60 to 90 percent.12,13
We all contribute to climate change, which is caused by high levels of greenhouse gases like carbon dioxide that build up in the atmosphere and absorb the sun’s heat.
In agriculture, the use of tilling, fertilizers, fuel and other tools emits greenhouse gases. But unlike other industries, agriculture is uniquely capable of removing just as many – or more – greenhouse gases than it emits. All it takes is the right tools and solutions for healthy crops.
And that’s without taking into account the greenhouse gas emissions released from the fuel and energy consumed by tilling machinery. In 2014 alone, a decrease in tillage led to a reduction in carbon emissions equivalent to removing nearly 2 million cars from the road.14
No-till and reduced tillage practices are key to keeping water safe and conserving this precious resource.
When farmers don’t till, they help the soil retain water and moisture levels. More moisture in the ground means less runoff and more water readily available for crops, which in turn reduces the need for irrigation.
Based on research and monitoring data, glyphosate does not pose a hazard to human health through surface water or drinking water and there is no evidence of any persistent groundwater contamination by glyphosate.15-30 Glyphosate has a unique combination of qualities that allow it to bind strongly to the soil, making it unlikely to leach into groundwater. And, it degrades over time into naturally occurring substances like carbon dioxide, nitrogen and phosphate.31
Like farmers, we think in generations. We aim to ensure bountiful harvests today and leave the planet and our communities in better shape for our children and the generations to come. In addition, we have a robust stewardship program in place to understand and minimize any potential negative impact on human health or the environment.
Here’s how those safety measures are established: When a new herbicide – or any crop protection product – is introduced to the market, regulatory agencies closely scrutinize not only the effects that a product has on its target, but also the peripheral effects it may have on non-target areas, pests, animals, people and more. Only after a thorough assessment of each of these categories can farmers use a new product. And, most importantly, in many countries this scrutiny is recurring, as regulators routinely review such products and the scientific literature supporting their safety profiles.
In the past 40 plus years, hundreds of studies have been conducted on glyphosate and reviewed by the EPA as researchers work to identify potential negative effects on humans or the environment.
The information obtained in glyphosate studies and the studies of other crop protection products is then used to establish how, when and where a product can be used safely.
Here are some of the stewardship measures currently in place:
A crucial element of product stewardship is the development of clear label instructions, which outline very specific measures to reduce water contamination risks. Regulatory authorities conduct comprehensive evaluations in order to develop these product label instructions. The protection of water on farms and downstream is vitally important. Although glyphosate binds strongly to soil particles and organic matter and is metabolized by microorganisms, farmers go to great lengths to avoid any potential spray drift and run-off.
Many farmers participate in training and certification programs to help ensure they are up-to-date on best practices for using crop protection products effectively and sustainably.
The FAO International Code of Conduct for the Distribution and Use of Pesticides32 sets out the principles of product stewardship, which are required to protect human health and the environment, while improving the productivity, sustainability and livelihoods of farmers.
1 http://www.fao.org/faostat/en/#data/QA [Retrieved February 12, 2019]
2 https://www.ncbi.nlm.nih.gov/pubmed/24616275 [Retrieved February 12, 2019]
3 Ferguson, F. 1988. Long term effects of systemic pesticides on honey bees. Bee keeping in the year 2000: Second Australian and International Beekeeping Congress, Surfers Paradise, Gold Coast, Queensland, Australia, July 21-26, 1988. Editor: John W. Rhodes. Pages: 137-141.
4 Burgett, M. and Fisher, G. 1990. A review of the Belizean honey bee industry: Final report prepared at the request of The Belize Honey Producers Federation. Department of Entomology, Oregon State University, Corvallis, Oregon.
5 Thompson HM, Levine SL, Doering J, Norman S, Manson P, Sutton P, von Mérey G. (2014) Evaluating exposure and potential effects on honeybee brood (Apis mellifera) development using glyphosate as an example. Integr Environ Assess Manag. 2014 Feb 25. doi: 10.1002/ieam.1529
6 https://efsa.onlinelibrary.wiley.com/doi/epdf/10.2903/j.efsa.2015.4302 [Retrieved February 12, 2019]
7 https://www.regulations.gov/document?D=EPA-HQ-OPP-2009-0361-0077 [Retrieved February 12, 2019]
8 https://link.springer.com/chapter/10.1007/978-1-4612-1156-3_2 [Retrieved February 12, 2019]
10 Buddenhagan, C.E. (2006) ” The successful eradication of two blackberry species Rubus megalococcus and R. adenotrichos (Rosaceae) from Santa Cruz Island, Galapagos, Ecuador, Pacific Conservation Biology Vol. 12: 272-78.
11 Toth, L.A. (2007) “Establishment of Submerged Aquatic Vegetation in Everglades Stormwater Treatment Areas: Value of Early Control of Torpedograss (Panicum repens)” J. Aquat. Plant Manage. 45: 17-20
12 USDA-NRCS. 2012. Assessment of the effects of conservation practices on cultivated cropland in the Upper Mississippi River basin. http://www.nrcs.usda.gov/Internet/FSE_DOCUMENTS/stelprdb1042093.pdf [Retrieved June 17, 2016]
13 https://www.ars.usda.gov/ARSUserFiles/20902500/DavidHuggins/NoTill.pdf [Retrieved February 12, 2019]
14 http://www.pgeconomics.co.uk/pdf/2016globalimpactstudymay2016.pdf [Retrieved February 12, 2019]
15 Horth, H., Blackmore, K. 2009. Survey of Glyphosate and AMPA in groundwaters and surface waters in Europe, WRc UC8073.01
16 Borggaard O.K., Gimsing A.L., (2008) Fate of glyphosate in soil and the possibility of leaching to ground and surface waters: a review. Pest Manag Sci 64:441-458
17 Ctgb (2002): http://www.ctb-wageningen.nl/ in the pesticide database (select all pesticides) under Roundup Dry registration number 11229N – prolongation of authorisation of 15/03/2002
18 EGEIS toolbox http://egeis.org/Farenhorst, A., S.K. Papiernik, I. Saiyed, P. Messing, K.D. Stephens, J.A. Schumacher, D.A. Lobb, S. Li, M.J. Lindstrom and T.E. Schumacher. 2008.
19 Herbicide sorption coefficients in relation to soil properties and terrain attributes on a cultivated prairie. J Environ Qual 37: 1201-1208
20 Fomsgaard, I.S.; Spliid, N.H.; Felding, G. (2003) Leaching of pesticides through normal tillage and low tillage soil – A lysimeter study – II. Glyphosate. J. Env. Sci Health B B38(1):19-35
21 Gjettermann, B., C.T. Petersen, C.B. Koch, N.H. Spliid, C. Grøn, D.L. Baun and M. Styczen. 2009. Particle-facilitated Pesticide Leaching from Differently Structured Soil Monoliths. J. Environ. Qual. 38: 2382-2393.
22 Grundmann, S., Dörfler, U., Ruth, B., Loos, C., Wagner, T., Karl, H., Munch, J.C., Schroll, R. (2008) Mineralization and transfer processes of 14C-labeled pesticides in outdoor lysimeters. Water Air Soil Pollut: Focus 8:177-185
23 Horth, H. 2012. Survey of Glyphosate and AMPA in groundwaters and surface waters in Europe – Update 2012
24Jadas-Hecart A., Morin, G., Communal P-Y., (2010) Aminophosphonates des lessives : une potentielle source d’AMPA ? Unpublished Report; article in preparation
25 Jönsson J. (2010) Removal of glyphosate and AMPA by water treatment, Unpublished Report UC8154v2; article in preparation
26 Jönsson J (2012) Review of sustainable water treatment, Unpublished Report UC8408V2; article in preparation
27 Klier, C., S. Grundmann, S. Gayler and E. Priesack. 2008. Modelling the Environmental Fate of the Herbicide Glyphosate in Soil Lysimeters. Water, Air, & Soil Pollution: Focus 8: 187-207
28 Laitinen, P., S. Rämö, U. Nikunen, L. Jauhiainen, K. Siimes and E. Turtola. 2009. Glyphosate and phosphorus leaching and residues in boreal sandy soil. Plant and Soil 323: 267-283.
29 Stadlbauer, H., J. Fank and G. Lorbeer. 2005. Lysimeteruntersuchungen zur Verlagerung von Glyphosate im Lichte der Anwendung von Pflanzenschutzmitteln zur Beseitigung von winterharten Grundecken. [Lysimeter investigations on the removal of glyphosate in light of the application of pesticides for the removal of winter green cover.]. Pages 131-136 in 11. Lysimetertagung, Lysimetrie im Netzwerk der Dynamik von Ökosystemen Raumberg-Gumpenstein, Austria
30 WFD-UKTAG (2012) Proposed EQS for Water Framework Directive Annex VII substances : glyphosate http://www.wfduk.org/sites/default/files/Media/Glyphosate%20-%20UKTAG.pdf
31 Giesy, J.P., Stuart. Dobson, and Keith .R. Solomon. 2000. Ecotoxicological risk assessment for Roundup herbicide. Reviews in Environmental Contamination and Toxicology. 167:35-120.
32 http://www.fao.org/fileadmin/templates/agphome/documents/Pests_Pesticides/Code/CODE_2014Sep_ENG.pdf [Retrieved February 12, 2019]