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Runaway1956 writes in with an excerpt from a story by Judith D. Schwartz that appeared July 30, 2016 in Scientific American — taken from "Water in Plain Sight: Hope For A Thirsty World" ... St. Martin's Press. Copyright 2016.

Irrigation is more than just throwing water on a field—it can be a nuanced chemical conversation between humans and plants

[...] When it comes to irrigation, water is not simply water.

This is dogma to John Kempf, an Ohio farmer who has made a career of improving crop health and agriculture yields. In 2006, Kempf founded the company Advancing Eco Agriculture, a consulting service for farmers that provides testing and analysis of crop specimens and recommends various plant nutrition treatments to improve crop yields.

The sources of water used for crops—be it well, river or reservoir—vary as to the mineral salts that they carry. The degree to which salts are present in water is referred to as "hardness," generally described in terms of grains per gallon. ("Salt" in this context is not what you'd sprinkle on scrambled eggs, but the combination of elements with a positive charge [cation] and negative charge [anion].) Kempf says that poor water quality, specifically water with high levels of calcium carbonate (lime), is a problem not often acknowledged in public discussions of agriculture—but one that affects crop production and, ironically, leads to a higher use of water.

"The level of minerals affects not only plants' ability to absorb water, but also how the plant can absorb nutrition," says Kempf. "Hard water requires more energy, and therefore nutrition, to break it down. When water quality is poor, more water is required." Farms do regularly test for water quality, and he says that when a potential client's water source has more than five grains per gallon he recommends that it be treated.

"When farms irrigate with poor-quality water there are multiple effects," he says. "It ties up all the nutrients that have been applied in the form of fertilizers. It significantly suppresses soil biology. And what often happens is that sodium and calcium bicarbonates accumulate in the soil profile. This leads to salinity."

Please, read the article — it's simply too long to copy/paste here. It goes into some (minor) detail regarding agriculture's problem with nitrogen. That is, there is a lot of nitrogen, but little of it is available to plants. Excess application of nitrogen fertilizers of course end up in the water supplies, in cities, rivers, and oceans.

Once again, we are shown that nature is a delicate balancing act. One that we routinely disrupt, then wonder why our food crops aren't healthy.

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