Ten Facts About the Water We Use

Most people have a basic understanding of the importance of water conservation. We’re taught to turn the faucet off while brushing our teeth and not to try and take shorter showers. However, we might not be aware of just how important conserving water is, how it impacts our lives, and how much we need it to survive.

The following is an excerpt from Water in Plain Sight by Judith Schwartz. It has been adapted for the web.

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The Ten Facts

One:

663 million, or one in ten people in the world, lack access to clean water.

Two:

Every ninety seconds a child dies of a water-related disease, usually diarrhea from inadequate drinking water, sanitation or hygiene—death and suffering that is preventable.

Three:

Women and children collectively devote an astounding 125 million hours a day to water gathering, which can mean carrying across long distances heavy vessels of water of dubious quality on their heads or backs. This is time that could be spent on schooling, caring for children or other relatives, and income-yielding work.

Four:

Every inch of water that runs off represents a loss of up to 150 to 200 pounds of [food] production per acre.

Five:

As much as 10 percent of the world’s food is produced by overpumping groundwater.

Six:

A tomato “costs” about thirteen gallons of water, eight ounces of broccoli accounts for 19.5 gallons and, notoriously, an almond requires a gallon per nut.

Seven:

The U.S. Geological Survey reports that California uses more water than any state, though the quantity used has been declining since 1980. Fully 80 percent of California’s developed water supply is used for agriculture. About half of all produce sold in the United States comes from California (primarily the megafarms in the Central Valley), productivity that is highly dependent on irrigation.

Eight:

Over 90 percent of the global heat dynamics and balance is governed by a range of water-based processes.

Nine:

When soil is left bare, water evaporates, carbon oxidizes and microorganisms die. The ground becomes a hot plate and can no longer sustain life. Water runs off the land instead of sinking into it.

Ten:

What’s important is not the quantity of rain a given location receives, but rather how much usable or effective rainfall there is. It doesn’t really matter how much rain falls on a stretch of land, if 90 percent of the water either evaporates or streams away by the next day.

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Prefer audio?

Listen to the following excerpt from the audiobook of Water in Plain Sight.

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Moving Water Across the Landscape

When we hear the term water infrastructure this is what comes to mind: dams, pipes and pumps; tunnels and funnels; systems engineered by human ingenuity.

From copper plumbing found in the Egyptian pyramids to California’s complex water matrix to China’s $62 billion South-North Water Transfer Project (the latter a plan originally envisioned by Mao Zedong that has already displaced 300,000 people), technological fixes have addressed the ongoing challenge of how to bring in water from the source, treat and clean water for use and consumption, and dispense with the foul stuff.

By ensuring ongoing supplies of usable, drinkable, nonfetid water, basic waterworks like aqueducts, drains and latrines are a hallmark of civilization—and hygiene. Without this, a city could flourish only until some virulent, disease-causing agent hit the wells.

My elementary school class once took a field trip to a local water treatment plant. I remember reacting with awe to the deafening factory-scale machinery and concrete vats of turbid water that we looked way down into, like some sort of roiling underworld.

This was the late 1960s, arguably the heyday of techno-optimism, or at least of a certain kind of big-works mechanical can-do.

For the longest time I went along assuming that the fate of the water that we needed to quench our thirst and wash our clothes and sprinkle our lawns was by necessity determined by big, mechanistic systems. The natural world played an incidental role.

It wasn’t until my research led me to think in terms of ecosystems that I gave much thought to how water moves from place to place—and why this has important implications for climate, poverty, politics and biodiversity.

Infrastructure is, to my ear, a cold word, and for this reason I wanted to avoid using it. But I couldn’t find another way to convey the apparatus that supports water processes, the basic undergirding or hardware that enables the system to function.

And the term doesn’t have to refer solely to the built environment—infrastructure can describe natural systems as well.

What do we mean by infrastructure? The structure part suggests form, whereas infra comes from the Latin for “below.” Which brings us once more to what lies at our feet, the soil.

The quality of soil on a piece of land may seem unrelated to water infrastructure. However, Malin Falkenmark of the Stockholm International Water Institute has emphasized that two-thirds of all rain that falls over the continents goes into the soil.

This is in contrast to the lakes, rivers and reservoirs—those blue-colored places on the map—where we assume water will end up. In the 1990s she coined the term green water to represent soil moisture that cycles through plants.

Blue water is the water in rivers, lakes and aquifers that may be drawn on for domestic and agricultural use.

Falkenmark and her colleagues point out that our engineered infrastructure projects, such as dams, irrigation, and water diversion programs, focus on blue water.

Despite representing two-thirds of the world’s freshwater resources, green water has been ignored and subsequently mismanaged. Changes that impede the presence of ground cover, notably desertification and deforestation, have a negative impact on green water.

This is significant because water held in soil is what most directly and efficiently affects a community’s ability to grow food. Indeed, while water planning and policy tend to focus on irrigation, most of the world’s agriculture is rain-fed.

Water as liquid or vapor is always moving into and out of soil and plants, the atmosphere, and natural pools and byways, and so the two systems—green and blue—are interdependent. The work on green and blue water demonstrates how crucial that thin ground layer is to our global water infrastructure, the system underlying the movement of water and the fulfillment of our water needs.

Australian soil scientist Christine Jones describes how a whole landscape approach to water management has to, paradoxically, work on the level of entire catchment areas as well as the tiny raindrop. Any time a raindrop meets the earth, she writes, one of four things can happen. That droplet of water can:

1. Go up, as evaporation (or transpiration through plants)
2. Go sideways, as surface runoff
3. Go down, as deep drainage to be stored in aquifers
4. Be held in the soil before moving in one of the other three directions.

The length of time water remains in the soil where it has fallen is an important factor in the viability of a given watershed, she says.

The trouble today—she’s speaking of Australia but this applies worldwide— is that too much water moves sideways, dragging along topsoil, organic matter and soluble nutrients and depositing it in lakes and rivers.

Because there’s so much bare soil, thanks in part to desertification and fires and other means of undermining soil health, there’s also too much water moving up as evaporation.

This is another way to appreciate what our two videos (Allan Savory on Effective Rainfall) show us. Ray the Soil Guy gave us the water-going-sideways scenario: disturbed soil becomes compacted and loses the pore spaces that would allow water and air to flow.

Unable to infiltrate the soil, the water has no choice but to move horizontally—sideways—and thus we have runoff, and all the problems that entails. Savory’s two uncovered plots saw their water go up: in the course of a hot day in Zimbabwe the four-millimeter rain equivalent evaporated away.

As in the African bush and on and around North America’s industrial farms, all around the world we have problems with water: water shortages and runoff and floods. But maybe we can reframe our challenge as having a keeping-water-in-the-ground problem.

For this is certainly a problem we can do something about. What we need to do is promote land management practices that enhance a part of our water infrastructure that we’ve been treating like dirt: the ground. The surface of the soil shouldn’t have to “hurt like hell.”

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