{"id":85,"date":"2020-07-21T15:12:28","date_gmt":"2020-07-21T15:12:28","guid":{"rendered":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/part\/food-and-water-for-a-growing-population\/"},"modified":"2020-07-21T15:12:28","modified_gmt":"2020-07-21T15:12:28","slug":"food-and-water-for-a-growing-population","status":"publish","type":"part","link":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/part\/food-and-water-for-a-growing-population\/","title":{"raw":"Food and water for a growing population","rendered":"Food and water for a growing population"},"content":{"raw":"Progress continues in the fight against hunger, yet an unacceptably large number of people lack the food they need for an active and healthy life. The latest available estimates indicate that about 795 million people in the world \u2013 just over one in nine \u2013still go to bed hungry every night, and an even greater number live in poverty (defined as living on less than $1.25 per day). Poverty\u2014not food availability\u2014is the major driver of food insecurity. Improvements in agricultural productivity are necessary to increase rural household incomes and access to\u00a0available food but are insufficient to ensure food security. Evidence indicates that poverty reduction and food security do not necessarily move in tandem. The main problem is lack of economic (social and physical) access to food at national and household levels and inadequate nutrition (or hidden hunger). Food security not only requires an adequate supply of food but also entails availability, access, and utilization by all\u2014people\u00a0of all ages, gender, ethnicity, religion, and socioeconomic levels.\n\nFrom Agriculture to Food Security<\/strong>\n\nAgriculture and food security are inextricably linked. The agricultural sector in each country is dependent on the available natural resources, as well as the politics that govern those resources.\u00a0Staple food crops\u00a0<\/strong>are the main source of dietary energy in the human diet and include things such as rice, wheat, sweet potatoes, maize, and cassava.\n\nFood security<\/strong>\n\nFood security is essentially built on four pillars:\u00a0availability<\/strong>,\u00a0access<\/strong>,\u00a0utilization<\/strong>\u00a0and\u00a0stability<\/strong>. An individual must have access to sufficient food of the right dietary mix (quality) at all times to be food secure. Those who never have sufficient quality food are\u00a0chronically food insecure<\/strong>.\n\nWhen food security is analyzed at the national level, an understanding not only of national production is important, but also of the country\u2019s\u00a0access<\/strong>\u00a0to food from the global market, its foreign exchange earnings, and its citizens\u2019 consumer choices. Food security analyzed at the household level is conditioned by a household\u2019s own food production and household members\u2019 ability to purchase food of the right quality and diversity in the market place. However, it is only at the individual level that the analysis can be truly accurate because only through understanding who consumes what can we appreciate the impact of sociocultural and gender inequalities on people\u2019s ability to meet their nutritional needs.The definition of food security is often applied at varying levels of aggregation, despite its articulation at the individual level. The importance of a pillar depends on the level of aggregation being addressed. At a global level, the important pillar is food\u00a0availability<\/strong>. Does global agricultural activity produce sufficient food to feed all the world\u2019s inhabitants? The answer today is yes, but it may not be true in the future given the impact of a growing world population, emerging plant and animal pests and diseases, declining soil productivity and environmental quality, increasing use of land for fuel rather than food, and lack of attention to agricultural research and development, among other factors.\n\nThe third pillar, food\u00a0utilization<\/strong>, essentially translates the food available to a household into nutritional security for its members. One aspect of utilization is analyzed in terms of distribution according to need. Nutritional standards exist for the actual nutritional needs of men, women, boys, and girls of different ages and life phases (that is, pregnant women), but these \u201cneeds\u201d are often socially constructed based on culture. For example, in South Asia evidence shows that women eat after everyone else has eaten and are less likely than men in the same household to consume preferred foods such as meats and fish.\u00a0Hidden hunger<\/strong>\u00a0commonly results from poor food utilization: that is, a person\u2019s diet lacks the appropriate balance of macro- (calories) and micronutrients (vitamins and minerals). Individuals may look well nourished and consume sufficient calories but be deficient in key micronutrients such as vitamin A, iron, and iodine.\n\nWhen food security is analyzed at the national level, an understanding not only of national production is important, but also of the country\u2019s access to food from the global market, its foreign exchange earnings, and its citizens\u2019 consumer choices. Food security analyzed at the household level is conditioned by a household\u2019s own food production and household members\u2019 ability to purchase food of the right quality and diversity in the market place. However, it is only at the individual level that the analysis can be truly accurate because only through understanding who consumes what can we appreciate the impact of sociocultural and gender inequalities on people\u2019s ability to meet their nutritional needs.\n\nFood\u00a0stability\u00a0<\/strong>is\u00a0when a population, household, or individual has access to food at all times and does not risk losing access as a consequence of cyclical events, such as the dry season.\u00a0<\/strong>When some lacks food stability, they have\u00a0malnutrition,\u00a0<\/strong>a lack of essential nutrients. \u00a0This is economically costly because it\u00a0can cost individuals 10 percent of their lifetime earnings and nations 2 to 3 percent of gross domestic product (GDP) in the worst-affected countries (Alderman 2005). Achieving food security is even more challenging in the context of HIV and AIDS. HIV affects people\u2019s physical ability to produce and use food, reallocating household labor, increasing the work burden on women, and preventing widows and children from inheriting land and productive resources.\n\nObesity<\/strong>\n\nObesity means having too much body fat. It is not the same as overweight, which means weighing too much. Obesity has become a significant global health challenge, yet is preventable and reversible. Over the past 20 years, a global overweight\/obesity epidemic has emerged, initially in industrial countries and now increasingly in low- and middle-income countries, particularly in urban settings, resulting in a triple burden of undernutrition, micronutrient deficiency, and overweight\/obesity. There is significant variation by region; some have very high rates of undernourishment and low rates of obesity, while in other regions the opposite is true (Figure 1).\n\nFigure 1. Obesity and undernourishment by region.\n\nHowever, obesity has increased to the extent that the number of overweight people now exceeds the number of underweight people worldwide. The economic cost of obesity has been estimated at $2 trillion, accounting for about 5% of deaths worldwide. Almost 30% of the world\u2019s population, or 2.1 billion people, are overweight or obese, 62% of whom live in developing countries.\n\nObesity accounts\u00a0 for a growing level and share of worldwide\u00a0 noncommunicable diseases, including diabetes, heart disease, and certain cancers that can reduce quality of life and increase public health costs of already under-resourced developing\u00a0 countries. The number of overweight children is projected to double by 2030.\u00a0 Driven primarily by increasing availability of processed, affordable, and effectively marketed food, the global food system is falling short with rising obesity and related poor health outcomes. Due to established health implications and rapid increase in prevalence, obesity is now a recognized major global health challenge.\n

Suggested Supplementary Reading:<\/strong><\/h3>\nMcMillan, T. 2018.\u00a0How China Plans to Feed 1.4 Billion Growing Appetites<\/a>.\u00a0National Geographic<\/em>. February.\n\nAttribution<\/strong>\n\nEssentials of Environmental Science<\/a>\u00a0by\u00a0Kamala Dor\u0161ner\u00a0is licensed under\u00a0CC BY 4.0<\/a>. Modified from the original\u00a0by Matthew R. Fisher.\n\n \n\n \n\nWater, air, and food are the most important natural resources to people. Humans can live only a few minutes without oxygen, less than\u00a0a week without water, and about a month without food. Water also is essential for our oxygen and food supply. Plants breakdown water and use it to create\u00a0oxygen during\u00a0the process of photosynthesis.\n\nWater is the most essential compound for all living things. Human babies are approximately 75% water and adults are 60% water. Our brain is about 85% water, blood and kidneys are 83% water, muscles are 76% water, and even bones are 22% water. We constantly lose water by perspiration; in temperate climates we should drink about 2 quarts of water per day and people in hot desert climates should drink up to 10 quarts of water per day. Loss of 15% of body-water usually causes death.\n\nEarth is truly the Water Planet. The abundance of liquid water on Earth\u2019s surface distinguishes us from other bodies in the solar system. About 70% of Earth\u2019s surface is covered by oceans and approximately half of Earth\u2019s surface is obscured by clouds (also made of water) at any time. There is a very large volume of water on our planet, about 1.4 billion cubic kilometers (km3) (330 million cubic miles) or about 53 billion gallons per person on Earth. All of Earth\u2019s water could cover the United States to a depth of 145 km (90 mi). From a human perspective, the problem is that over 97% of it is seawater, which is too salty to drink or use for irrigation. The most commonly used water sources are rivers and lakes, which contain less than 0.01% of the world\u2019s water!\n\nOne of the\u00a0most important environmental goals is to provide clean water to all people. Fortunately, water is a renewable resource and is difficult to destroy. Evaporation and precipitation combine to replenish our fresh water supply constantly; however, water availability is complicated by its uneven distribution over the Earth. Arid climate and densely populated areas have combined in many parts of the world to create water shortages, which are projected to worsen in the coming years due to population growth and climate change. Human activities such as water overuse and water pollution have compounded significantly the water crisis that exists today. Hundreds of millions of people lack access to safe drinking water, and billions of people lack access to improved sanitation as simple as a pit latrine. As a result, nearly two million people die every year from diarrheal diseases and 90% of those deaths occur among children under the age of 5. Most of these are easily prevented deaths.\n\nWater Reservoirs and Water Cycle<\/strong>\n\nWater is the only common substance that occurs naturally on earth in three forms: solid, liquid and gas. It is distributed in various locations, called water reservoirs. The oceans are by far the largest of the reservoirs with about 97% of all water but that water is too saline for most human uses (Figure 1).\u00a0Ice caps and glaciers are the largest reservoirs of fresh water but this water is inconveniently located, mostly in Antarctica and Greenland. Shallow groundwater is the largest reservoir of usable fresh water. Although rivers and lakes are the most heavily used water resources, they represent only a tiny amount of the world\u2019s water. If all of world\u2019s water was shrunk to the size of 1 gallon, then the total amount of fresh water would be about 1\/3 cup, and the amount of readily usable fresh water would be 2 tablespoons.\n\nFigure 1. Earth\u2019s Water Reservoirs. Bar chart Distribution of Earth\u2019s water including total global water, fresh water, and surface water and other fresh water and Pie chart Water usable by humans and sources of usable water. Source: United States Geographical Survey Igor Skiklomanov\u2019s chapter \u201cWorld fresh water resources\u201d in Peter H. Gleick (editor), 1993, Water in Crisis: A Guide to the World\u2019s Fresh Water Resources\n\nThe\u00a0water<\/strong>\u00a0(or hydrologic)\u00a0cycle<\/strong>\u00a0(that was\u00a0covered in Chapter 3.2) shows the movement of water through different reservoirs, which include oceans, atmosphere,\u00a0glaciers, groundwater, lakes, rivers, and biosphere.\u00a0Solar energy and gravity drive the motion of water in the water cycle. Simply put, the water cycle involves\u00a0water moving from oceans, rivers, and lakes to the atmosphere by evaporation, forming clouds. From clouds, it falls as\u00a0precipitation (rain and snow) on both water and land. The water on\u00a0land can either return to the ocean by surface runoff, rivers, glaciers, and\u00a0subsurface groundwater flow, or return to the atmosphere by evaporation or\u00a0transpiration<\/strong>\u00a0(loss of water\u00a0by plants to the atmosphere).\n\nFigure 2. The Water Cycle. Arrows depict movement of water to different reservoirs located above, at, and below Earth\u2019s surface. Source: United States Geological Survey\n\nAn important part of the water cycle is how water varies in salinity, which is the abundance of dissolved\u00a0ions in water. The saltwater in the oceans is highly saline, with about 35,000 mg of dissolved\u00a0ions per liter of seawater.\u00a0Evaporation<\/strong>\u00a0(where water changes from liquid to gas at ambient temperatures)\u00a0is a distillation process that produces nearly pure water with almost no dissolved ions. As water vaporizes, it\u00a0leaves the dissolved ions in the original liquid phase. Eventually,\u00a0condensation<\/strong>\u00a0 (where water changes from\u00a0gas to liquid) forms clouds and sometimes precipitation (rain and snow). After rainwater falls onto land,\u00a0it dissolves minerals in rock and soil, which increases its salinity. Most lakes, rivers, and near-surface groundwater have a\u00a0relatively low salinity and are called freshwater. The next several sections discuss important parts of the\u00a0water cycle relative to fresh water resources.\n\nPrimary Fresh Water Resources: Precipitation<\/strong>\n\nPrecipitation levels are unevenly distributed around the globe, affecting fresh water availability (Figure 3). More precipitation falls near the equator, whereas less precipitation tends to fall near 30 degrees north and\u00a0south latitude, where the world\u2019s largest deserts are located. These rainfall and climate patterns are related\u00a0to global wind circulation cells. The intense sunlight at the equator heats air, causing it to rise and cool,\u00a0which decreases the ability of the air mass to hold water vapor and results in frequent rainstorms. Around\u00a030 degrees\u00a0north and south latitude, descending air conditions produce warmer air, which increases its ability to\u00a0hold water vapor and results in dry conditions. Both the dry air conditions and the warm temperatures of\u00a0these latitude belts favor evaporation. Global precipitation and climate patterns are also affected\u00a0by the size\u00a0of continents, major ocean currents, and mountains.\n\nFigure 3. World Rainfall Map. The false-color map above shows the amount of rain that falls around the world. Areas of high rainfall include Central and South America, western Africa, and Southeast Asia. Since these areas receive so much rainfall, they are where most of the world\u2019s rainforests grow. Areas with very little rainfall usually turn into deserts. The desert areas include North Africa, the Middle East, western North America, and Central Asia. Source: United States Geological Survey Earth Forum, Houston Museum Natural Science\n\nSurface Water Resources: Rivers, Lakes, Glaciers<\/strong>\n\nFigure 4. Surface Runoff Surface runoff, part of overland flow in the water cycle Source: James M. Pease at Wikimedia Commons\n\nFlowing water from rain and melted snow on land enters river channels by surface runoff (Figure 4) and groundwater seepage (Figure 5).\u00a0River\u00a0discharge<\/strong>\u00a0 describes the volume of water moving through a river channel over time (Figure 6). The relative contributions of surface runoff vs. groundwater seepage to river\u00a0discharge depend on precipitation patterns, vegetation, topography, land use, and soil characteristics. Soon\u00a0after a heavy rainstorm, river discharge increases due to surface runoff. The steady normal flow of river\u00a0water is mainly from groundwater that discharges into the river. Gravity pulls river water downhill toward\u00a0the ocean. Along the way the moving water of a river can erode soil particles and dissolve minerals. Groundwater also contributes a large amount\u00a0of the dissolved minerals in river water. The geographic area drained by a river and its tributaries is called a\u00a0drainage basin\u00a0<\/strong>or\u00a0watershed<\/strong>. The Mississippi River drainage basin includes approximately 40% of the U.S., a measure\u00a0that includes the smaller drainage basins, such as the Ohio River and Missouri\u00a0River that help to comprise it. Rivers are an important water resource for irrigation of cropland and drinking water for many cities around\u00a0the world. Rivers that have had international disputes over water supply include the\u00a0Colorado (Mexico, southwest U.S.), Nile (Egypt, Ethiopia, Sudan), Euphrates (Iraq, Syria, Turkey), Ganges\u00a0(Bangladesh, India), and Jordan (Israel, Jordan, Syria).\n\nFigure 5. Groundwater Seepage. Groundwater seepage can be seen in Box Canyon in Idaho, where approximately 10 cubic meters per second of seepage emanates from its vertical headwall. Source: NASA\n\nIn addition to rivers, lakes can also be an excellent source of freshwater for human use. They usually receive water from\u00a0surface runoff and groundwater discharge. They tend to be short-lived on a geological time-scale because\u00a0they are constantly filling in with sediment supplied by rivers. Lakes form in a variety of ways including\u00a0glaciation, recent tectonic\u00a0uplift (e.g., Lake Tanganyika, Africa), and volcanic eruptions (e.g., Crater Lake, Oregon). People also create artificial\u00a0lakes (reservoirs<\/strong>) by damming rivers. Large changes in climate can result in major changes in a lake\u2019s size.\u00a0As Earth was coming out of the last Ice Age about 15,000 years\u00a0ago, the climate in the western\u00a0U.S. changed from cool and moist to warm and arid, which caused more than 100 large lakes to disappear.\u00a0The Great Salt Lake in Utah is a remnant of a much larger lake called Lake Bonneville.\n\nFigure 6. River Discharge Colorado River, U.S.. Rivers are part of overland flow in the water cycle and an important surface water resource. Source: Gonzo fan2007 at Wikimedia Commons.\n\nAlthough\u00a0glaciers<\/strong>\u00a0represent the largest reservoir of fresh water, they generally are not used as a water\u00a0source because they are located too far from most people (Figure 7). Melting glaciers do provide a natural source of river water and groundwater. During the last\u00a0Ice Age there was as much as 50% more water in glaciers than there is today, which caused sea level to be\u00a0about 100 m lower. Over the past century, sea level has been rising in part due to melting glaciers. If Earth\u2019s\u00a0climate continues to warm, the melting glaciers will cause an additional rise in sea level.\n\nFigure 7. Mountain Glacier in Argentina Glaciers are the largest reservoir of fresh water but they are not used much as a water resource directly by society because of their distance from most people. Source: Luca Galuzzi \u2013 www.galuzzi.it\n\nGroundwater Resources<\/strong>\n\nAlthough most people in the world use surface water, groundwater is a much larger reservoir of\u00a0usable fresh water, containing more than 30 times more water than rivers and lakes combined. Groundwater is a particularly important resource in arid climates, where surface water may be scarce. In addition, groundwater is the primary water source for rural homeowners, providing 98% of that water demand in\u00a0the U.S..\u00a0Groundwater<\/strong>\u00a0is water located in small spaces, called\u00a0pore space<\/strong>, between mineral grains and fractures in subsurface earth materials (rock or sediment).\u00a0Most groundwater originates from rain or snowmelt, which infiltrates the ground and moves downward until it reaches the\u00a0saturated zone<\/strong>\u00a0(where groundwater completely fills pore spaces in earth materials).\n\nOther sources of groundwater include seepage from surface water (lakes, rivers, reservoirs,\u00a0and swamps), surface water deliberately pumped into the ground, irrigation, and underground wastewater\u00a0treatment systems (septic tanks).\u00a0Recharge areas<\/strong>\u00a0are locations where surface water infiltrates the\u00a0ground rather than running into rivers or evaporating. Wetlands, for example,\u00a0are\u00a0excellent recharge areas. \u00a0A large area of sub-surface, porous rock that holds water is an aquifer. Aquifers are commonly drilled, and wells installed, to provide water for agriculture and personal use.\n\nWater Use in the U.S. and World<\/strong>\n\nPeople need water, oftentimes large quantities, to produce the food, energy, and mineral resources they use. \u00a0Consider, for example, these approximate water requirements for some things people in the developed\u00a0world use every day: one tomato = 3 gallons; one kilowatt-hour of electricity from a thermoelectric power\u00a0plant = 21 gallons; one loaf of bread = 150 gallons; one pound of beef = 1,600 gallons; and one ton of steel\u00a0= 63,000 gallons. Human beings require only about 1 gallon per day to survive, but a typical person in a\u00a0U.S. household uses approximately 100 gallons per day, which includes cooking, washing dishes and clothes,\u00a0flushing the toilet, and bathing. \u00a0The\u00a0water demand<\/strong>\u00a0of an area is a function of the population and other uses of water.\n\nFigure 8. Trends in Total Water Withdrawals by Water-use Category, 1950-2005 Trends in total water withdrawals in the U.S. from 1950 to 2005 by water use category, including bars for thermoelectric power, irrigation, public water supply, and rural domestic and livestock. Thin blue line represents total water withdrawals using vertical scale on right. Source: United States Geological Survey\n\nFigure 9. Trends in Source of Fresh Water Withdrawals in the U.S. from 1950 to 2005 Trends in source of fresh water withdrawals in the U.S. from 1950 to 2005, including bars for surface water, groundwater, and total water. Red line gives U.S. population using vertical scale on right. Source: United States Geological Survey\n\nGlobal total water use is steadily increasing at a rate greater than world\u00a0population growth (Figure 10). During the 20th century global population tripled and water demand grew by a\u00a0factor of six. The increase in global water demand beyond the rate of population growth is due to improved\u00a0standard of living without an offset by water conservation. Increased production of goods and energy entails\u00a0a large increase in water demand. The major global water uses are irrigation (68%), public supply\u00a0(21%), and industry (11%).\n\nFigure 10. Trends in World Water Use from 1900 to 2000 and Projected to 2025 For each water major use category, including trends for agriculture, domestic use, and industry. Darker colored bar represents total water extracted for that use category and lighter colored bar represents water consumed (i.e., water that is not quickly returned to surface water or groundwater system) for that use category. Source: Igor A. Shiklomanow, State Hydrological Institute (SHI, St. Petersburg) and United Nations Educational, Scientific and Cultural Organisation (UNESCO, Paris), 1999\n\nAttribution<\/strong>\n\nEssentials of Environmental Science<\/a>\u00a0by\u00a0Kamala Dor\u0161ner\u00a0is licensed under\u00a0CC BY 4.0<\/a>. Modified from the original\u00a0by Matthew R. Fisher.\n\n \n\n7.2 Water Supply Problems and Solutions Water Supply Problems: Resource Depletion<\/strong>\n\nAs groundwater is pumped from water wells, there usually is a localized drop in the water table around the\u00a0well called a cone of depression. When there are a large number of wells that have been pumping water for\u00a0a long time, the regional water table can drop significantly. This is called\u00a0groundwater mining<\/strong>, which\u00a0can force the drilling of deeper, more expensive wells that commonly encounter more saline groundwater.\u00a0Rivers, lakes, and artificial lakes (reservoirs) can also be depleted\u00a0due to overuse. Some large rivers, such as the Colorado in the U.S. and Yellow in China, run dry in some\u00a0years. The case history of the Aral Sea discussed later in this chapter\u00a0involves depletion of a lake. Finally, glaciers are\u00a0being depleted due to accelerated melting associated with global warming over the past century.\n\nFigure 1. Formation of a Cone of Depression around a Pumping Water Well Source: Fayette County Groundwater Conservation District, TX\n\nAnother water resource problem associated with groundwater mining is saltwater intrusion, where\u00a0overpumping of fresh water aquifers near ocean coastlines causes saltwater to enter fresh water zones. The drop of the water table around a\u00a0cone of depression<\/strong>\u00a0in an unconfined aquifer can change the direction of regional groundwater flow, which could\u00a0send nearby pollution toward the pumping well instead of away from it. Finally, problems of\u00a0subsidence\u00a0<\/strong>(gradual sinking of the land surface over a large area) and\u00a0sinkholes<\/strong>\u00a0(rapid sinking of the land surface over\u00a0a small area) can develop due to a drop in the water table.\n\nWater Supply Crisis<\/strong>\n\nThe\u00a0water crisis<\/strong>\u00a0refers to a global situation where people in many areas lack access to sufficient water, clean water, or both. This section describes the global situation involving water shortages, also called\u00a0water stress<\/strong>. In general, water stress is greatest in areas with very low precipitation (major deserts), large population density (e.g., India), or both. Future global warming could worsen the water crisis by shifting precipitation patterns away from humid areas and by melting mountain glaciers that recharge rivers downstream. Melting glaciers will also contribute to rising sea level, which will worsen saltwater intrusion in aquifers near ocean coastlines.\n\nFigure 2. Countries Facing Water Stress in 1995 and Projected in 2025 Water stress is defined as having a high percentage of water withdrawal compared to total available water in the area. Source: Philippe Rekacewicz (Le Monde diplomatique), February 2006\n\nAccording to a 2006 report by the United Nations Development Programme, 700 million people (11% of the world\u2019s population) lived with water stress. Most of them live in the Middle East and North Africa. By 2025, the report projects that more than 3 billion people (about 40% of the world\u2019s population) will live in water-stressed\u00a0areas with the large increase coming mainly from China and India. The water crisis will also impact food production and our ability to feed the ever-growing population. We can expect future global tension and even conflict associated with water shortages and pollution. Historic and future areas of water conflict include the Middle East (Euphrates and Tigris River conflict among Turkey, Syria, and Iraq; Jordan River conflict among Israel, Lebanon, Jordan, and the Palestinian territories), Africa (Nile River conflict among Egypt, Ethiopia, and Sudan), Central Asia (Aral Sea conflict among Kazakhstan, Uzbekistan, Turkmenistan, Tajikistan, and Kyrgyzstan), and south Asia (Ganges River conflict between India and Pakistan).\n\nSustainable Solutions to the Water Supply Crisis?<\/strong>\n\nThe current and future water crisis described above requires multiple approaches to extending our fresh\u00a0water supply and moving towards sustainability. Some of the longstanding traditional approaches include\u00a0dams and aqueducts.\n\nFigure 3. Hoover Dam, Nevada, U.S. Hoover Dam, Nevada, U.S.. Behind the dam is Lake Mead, the largest reservoir in U.S.. White band reflects the lowered water levels in the reservoir due to drought conditions from 2000 \u2013 2010. Source: Cygnusloop99 at Wikimedia Commons\n\nReservoirs<\/strong>\u00a0that form behind dams in rivers can collect water during wet times and\u00a0store it for use during dry spells. They also can\u00a0be used for urban water supplies. Other benefits of dams and reservoirs are\u00a0hydroelectricity, flood control, and recreation. Some of the drawbacks are evaporative loss of water\u00a0in arid climates, downstream river channel erosion, and impact on the ecosystem including a change from\u00a0a river to lake habitat and interference with migration and spawning of fish.\n\nAqueducts<\/strong>\u00a0can move water from\u00a0where it is plentiful to where it is needed. Aqueducts can be controversial and politically\u00a0difficult especially if the water transfer distances are large. One drawback is the water diversion can cause\u00a0drought in the area from where the water is drawn. For example, Owens Lake and Mono Lake in central\u00a0California began to disappear after their river flow was diverted to the Los Angeles aqueduct. Owens Lake\u00a0remains almost completely dry, but Mono Lake has recovered more significantly due to legal intervention.\n\nOne method that can actually increase the amount of fresh water on Earth is\u00a0desalination<\/strong>, which\u00a0involves removing dissolved salt from seawater or saline groundwater. There are several ways to desalinate\u00a0seawater including boiling, filtration, and electrodialysis. All of these procedures are moderately\u00a0to very expensive and require considerable energy input, making the water produced much more expensive\u00a0than fresh water from conventional sources. In addition, the process creates highly saline wastewater, which\u00a0must be disposed of and creates significant environmental impact. Desalination is most common in the Middle East, where energy from oil is abundant\u00a0but water is scarce.\n\nFigure 4. The California Aqueduct California Aqueduct in southern California, U.S. Source: David Jordan at en.wikipedia\n\nConservation<\/strong>\u00a0means using less water and using it more efficiently. Around the home, conservation can\u00a0involve both engineered features, such as high-efficiency clothes washers and low-flow showers and toilets, as\u00a0well as behavioral decisions, such as growing native vegetation that require little irrigation in desert climates,\u00a0turning off the water while you brush your teeth, and fixing leaky faucets.\n\nRainwater harvesting<\/strong>\u00a0involves\u00a0catching and storing rainwater for reuse before it reaches the ground. Another important technique is\u00a0efficient irrigation,\u00a0<\/strong>which is extremely\u00a0important because irrigation accounts for a much larger water demand than public water supply. Water\u00a0conservation strategies in agriculture include growing crops in areas where the natural rainfall can support\u00a0them, more efficient irrigation systems such as drip systems that minimize losses due to evaporation, no-till\u00a0farming that reduces evaporative losses by covering the soil, and reusing treated wastewater from sewage\u00a0treatment plants. Recycled wastewater has also been used to recharge aquifers.\n

Suggested Supplementary Reading:<\/strong><\/h3>\nWeiss, K.R. 2018.\u00a0Drying Lakes<\/a>.\u00a0National Geographic.\u00a0<\/em>March. p. 108-133.\n\nThis article documents how many lakes across the globe are drying up, the reasons why, and the effect on humans. Overuse and a warming climate threaten lakes that provide sustenance and jobs for humans, while also providing critical habitat for animals.\u00a0<\/em>\n\nAttribution<\/strong>\n\nEssentials of Environmental Science<\/a>\u00a0by\u00a0Kamala Dor\u0161ner\u00a0is licensed under\u00a0CC BY 4.0<\/a>. Modified from the original\u00a0by Matthew R. Fisher.","rendered":"

Progress continues in the fight against hunger, yet an unacceptably large number of people lack the food they need for an active and healthy life. The latest available estimates indicate that about 795 million people in the world \u2013 just over one in nine \u2013still go to bed hungry every night, and an even greater number live in poverty (defined as living on less than $1.25 per day). Poverty\u2014not food availability\u2014is the major driver of food insecurity. Improvements in agricultural productivity are necessary to increase rural household incomes and access to\u00a0available food but are insufficient to ensure food security. Evidence indicates that poverty reduction and food security do not necessarily move in tandem. The main problem is lack of economic (social and physical) access to food at national and household levels and inadequate nutrition (or hidden hunger). Food security not only requires an adequate supply of food but also entails availability, access, and utilization by all\u2014people\u00a0of all ages, gender, ethnicity, religion, and socioeconomic levels.<\/p>\n

From Agriculture to Food Security<\/strong><\/p>\n

Agriculture and food security are inextricably linked. The agricultural sector in each country is dependent on the available natural resources, as well as the politics that govern those resources.\u00a0Staple food crops\u00a0<\/strong>are the main source of dietary energy in the human diet and include things such as rice, wheat, sweet potatoes, maize, and cassava.<\/p>\n

Food security<\/strong><\/p>\n

Food security is essentially built on four pillars:\u00a0availability<\/strong>,\u00a0access<\/strong>,\u00a0utilization<\/strong>\u00a0and\u00a0stability<\/strong>. An individual must have access to sufficient food of the right dietary mix (quality) at all times to be food secure. Those who never have sufficient quality food are\u00a0chronically food insecure<\/strong>.<\/p>\n

When food security is analyzed at the national level, an understanding not only of national production is important, but also of the country\u2019s\u00a0access<\/strong>\u00a0to food from the global market, its foreign exchange earnings, and its citizens\u2019 consumer choices. Food security analyzed at the household level is conditioned by a household\u2019s own food production and household members\u2019 ability to purchase food of the right quality and diversity in the market place. However, it is only at the individual level that the analysis can be truly accurate because only through understanding who consumes what can we appreciate the impact of sociocultural and gender inequalities on people\u2019s ability to meet their nutritional needs.The definition of food security is often applied at varying levels of aggregation, despite its articulation at the individual level. The importance of a pillar depends on the level of aggregation being addressed. At a global level, the important pillar is food\u00a0availability<\/strong>. Does global agricultural activity produce sufficient food to feed all the world\u2019s inhabitants? The answer today is yes, but it may not be true in the future given the impact of a growing world population, emerging plant and animal pests and diseases, declining soil productivity and environmental quality, increasing use of land for fuel rather than food, and lack of attention to agricultural research and development, among other factors.<\/p>\n

The third pillar, food\u00a0utilization<\/strong>, essentially translates the food available to a household into nutritional security for its members. One aspect of utilization is analyzed in terms of distribution according to need. Nutritional standards exist for the actual nutritional needs of men, women, boys, and girls of different ages and life phases (that is, pregnant women), but these \u201cneeds\u201d are often socially constructed based on culture. For example, in South Asia evidence shows that women eat after everyone else has eaten and are less likely than men in the same household to consume preferred foods such as meats and fish.\u00a0Hidden hunger<\/strong>\u00a0commonly results from poor food utilization: that is, a person\u2019s diet lacks the appropriate balance of macro- (calories) and micronutrients (vitamins and minerals). Individuals may look well nourished and consume sufficient calories but be deficient in key micronutrients such as vitamin A, iron, and iodine.<\/p>\n

When food security is analyzed at the national level, an understanding not only of national production is important, but also of the country\u2019s access to food from the global market, its foreign exchange earnings, and its citizens\u2019 consumer choices. Food security analyzed at the household level is conditioned by a household\u2019s own food production and household members\u2019 ability to purchase food of the right quality and diversity in the market place. However, it is only at the individual level that the analysis can be truly accurate because only through understanding who consumes what can we appreciate the impact of sociocultural and gender inequalities on people\u2019s ability to meet their nutritional needs.<\/p>\n

Food\u00a0stability\u00a0<\/strong>is\u00a0when a population, household, or individual has access to food at all times and does not risk losing access as a consequence of cyclical events, such as the dry season.\u00a0<\/strong>When some lacks food stability, they have\u00a0malnutrition,\u00a0<\/strong>a lack of essential nutrients. \u00a0This is economically costly because it\u00a0can cost individuals 10 percent of their lifetime earnings and nations 2 to 3 percent of gross domestic product (GDP) in the worst-affected countries (Alderman 2005). Achieving food security is even more challenging in the context of HIV and AIDS. HIV affects people\u2019s physical ability to produce and use food, reallocating household labor, increasing the work burden on women, and preventing widows and children from inheriting land and productive resources.<\/p>\n

Obesity<\/strong><\/p>\n

Obesity means having too much body fat. It is not the same as overweight, which means weighing too much. Obesity has become a significant global health challenge, yet is preventable and reversible. Over the past 20 years, a global overweight\/obesity epidemic has emerged, initially in industrial countries and now increasingly in low- and middle-income countries, particularly in urban settings, resulting in a triple burden of undernutrition, micronutrient deficiency, and overweight\/obesity. There is significant variation by region; some have very high rates of undernourishment and low rates of obesity, while in other regions the opposite is true (Figure 1).<\/p>\n

Figure 1. Obesity and undernourishment by region.<\/p>\n

However, obesity has increased to the extent that the number of overweight people now exceeds the number of underweight people worldwide. The economic cost of obesity has been estimated at $2 trillion, accounting for about 5% of deaths worldwide. Almost 30% of the world\u2019s population, or 2.1 billion people, are overweight or obese, 62% of whom live in developing countries.<\/p>\n

Obesity accounts\u00a0 for a growing level and share of worldwide\u00a0 noncommunicable diseases, including diabetes, heart disease, and certain cancers that can reduce quality of life and increase public health costs of already under-resourced developing\u00a0 countries. The number of overweight children is projected to double by 2030.\u00a0 Driven primarily by increasing availability of processed, affordable, and effectively marketed food, the global food system is falling short with rising obesity and related poor health outcomes. Due to established health implications and rapid increase in prevalence, obesity is now a recognized major global health challenge.<\/p>\n

Suggested Supplementary Reading:<\/strong><\/h3>\n

McMillan, T. 2018.\u00a0How China Plans to Feed 1.4 Billion Growing Appetites<\/a>.\u00a0National Geographic<\/em>. February.<\/p>\n

Attribution<\/strong><\/p>\n

Essentials of Environmental Science<\/a>\u00a0by\u00a0Kamala Dor\u0161ner\u00a0is licensed under\u00a0CC BY 4.0<\/a>. Modified from the original\u00a0by Matthew R. Fisher.<\/p>\n

 <\/p>\n

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Water, air, and food are the most important natural resources to people. Humans can live only a few minutes without oxygen, less than\u00a0a week without water, and about a month without food. Water also is essential for our oxygen and food supply. Plants breakdown water and use it to create\u00a0oxygen during\u00a0the process of photosynthesis.<\/p>\n

Water is the most essential compound for all living things. Human babies are approximately 75% water and adults are 60% water. Our brain is about 85% water, blood and kidneys are 83% water, muscles are 76% water, and even bones are 22% water. We constantly lose water by perspiration; in temperate climates we should drink about 2 quarts of water per day and people in hot desert climates should drink up to 10 quarts of water per day. Loss of 15% of body-water usually causes death.<\/p>\n

Earth is truly the Water Planet. The abundance of liquid water on Earth\u2019s surface distinguishes us from other bodies in the solar system. About 70% of Earth\u2019s surface is covered by oceans and approximately half of Earth\u2019s surface is obscured by clouds (also made of water) at any time. There is a very large volume of water on our planet, about 1.4 billion cubic kilometers (km3) (330 million cubic miles) or about 53 billion gallons per person on Earth. All of Earth\u2019s water could cover the United States to a depth of 145 km (90 mi). From a human perspective, the problem is that over 97% of it is seawater, which is too salty to drink or use for irrigation. The most commonly used water sources are rivers and lakes, which contain less than 0.01% of the world\u2019s water!<\/p>\n

One of the\u00a0most important environmental goals is to provide clean water to all people. Fortunately, water is a renewable resource and is difficult to destroy. Evaporation and precipitation combine to replenish our fresh water supply constantly; however, water availability is complicated by its uneven distribution over the Earth. Arid climate and densely populated areas have combined in many parts of the world to create water shortages, which are projected to worsen in the coming years due to population growth and climate change. Human activities such as water overuse and water pollution have compounded significantly the water crisis that exists today. Hundreds of millions of people lack access to safe drinking water, and billions of people lack access to improved sanitation as simple as a pit latrine. As a result, nearly two million people die every year from diarrheal diseases and 90% of those deaths occur among children under the age of 5. Most of these are easily prevented deaths.<\/p>\n

Water Reservoirs and Water Cycle<\/strong><\/p>\n

Water is the only common substance that occurs naturally on earth in three forms: solid, liquid and gas. It is distributed in various locations, called water reservoirs. The oceans are by far the largest of the reservoirs with about 97% of all water but that water is too saline for most human uses (Figure 1).\u00a0Ice caps and glaciers are the largest reservoirs of fresh water but this water is inconveniently located, mostly in Antarctica and Greenland. Shallow groundwater is the largest reservoir of usable fresh water. Although rivers and lakes are the most heavily used water resources, they represent only a tiny amount of the world\u2019s water. If all of world\u2019s water was shrunk to the size of 1 gallon, then the total amount of fresh water would be about 1\/3 cup, and the amount of readily usable fresh water would be 2 tablespoons.<\/p>\n

Figure 1. Earth\u2019s Water Reservoirs. Bar chart Distribution of Earth\u2019s water including total global water, fresh water, and surface water and other fresh water and Pie chart Water usable by humans and sources of usable water. Source: United States Geographical Survey Igor Skiklomanov\u2019s chapter \u201cWorld fresh water resources\u201d in Peter H. Gleick (editor), 1993, Water in Crisis: A Guide to the World\u2019s Fresh Water Resources<\/p>\n

The\u00a0water<\/strong>\u00a0(or hydrologic)\u00a0cycle<\/strong>\u00a0(that was\u00a0covered in Chapter 3.2) shows the movement of water through different reservoirs, which include oceans, atmosphere,\u00a0glaciers, groundwater, lakes, rivers, and biosphere.\u00a0Solar energy and gravity drive the motion of water in the water cycle. Simply put, the water cycle involves\u00a0water moving from oceans, rivers, and lakes to the atmosphere by evaporation, forming clouds. From clouds, it falls as\u00a0precipitation (rain and snow) on both water and land. The water on\u00a0land can either return to the ocean by surface runoff, rivers, glaciers, and\u00a0subsurface groundwater flow, or return to the atmosphere by evaporation or\u00a0transpiration<\/strong>\u00a0(loss of water\u00a0by plants to the atmosphere).<\/p>\n

Figure 2. The Water Cycle. Arrows depict movement of water to different reservoirs located above, at, and below Earth\u2019s surface. Source: United States Geological Survey<\/p>\n

An important part of the water cycle is how water varies in salinity, which is the abundance of dissolved\u00a0ions in water. The saltwater in the oceans is highly saline, with about 35,000 mg of dissolved\u00a0ions per liter of seawater.\u00a0Evaporation<\/strong>\u00a0(where water changes from liquid to gas at ambient temperatures)\u00a0is a distillation process that produces nearly pure water with almost no dissolved ions. As water vaporizes, it\u00a0leaves the dissolved ions in the original liquid phase. Eventually,\u00a0condensation<\/strong>\u00a0 (where water changes from\u00a0gas to liquid) forms clouds and sometimes precipitation (rain and snow). After rainwater falls onto land,\u00a0it dissolves minerals in rock and soil, which increases its salinity. Most lakes, rivers, and near-surface groundwater have a\u00a0relatively low salinity and are called freshwater. The next several sections discuss important parts of the\u00a0water cycle relative to fresh water resources.<\/p>\n

Primary Fresh Water Resources: Precipitation<\/strong><\/p>\n

Precipitation levels are unevenly distributed around the globe, affecting fresh water availability (Figure 3). More precipitation falls near the equator, whereas less precipitation tends to fall near 30 degrees north and\u00a0south latitude, where the world\u2019s largest deserts are located. These rainfall and climate patterns are related\u00a0to global wind circulation cells. The intense sunlight at the equator heats air, causing it to rise and cool,\u00a0which decreases the ability of the air mass to hold water vapor and results in frequent rainstorms. Around\u00a030 degrees\u00a0north and south latitude, descending air conditions produce warmer air, which increases its ability to\u00a0hold water vapor and results in dry conditions. Both the dry air conditions and the warm temperatures of\u00a0these latitude belts favor evaporation. Global precipitation and climate patterns are also affected\u00a0by the size\u00a0of continents, major ocean currents, and mountains.<\/p>\n

Figure 3. World Rainfall Map. The false-color map above shows the amount of rain that falls around the world. Areas of high rainfall include Central and South America, western Africa, and Southeast Asia. Since these areas receive so much rainfall, they are where most of the world\u2019s rainforests grow. Areas with very little rainfall usually turn into deserts. The desert areas include North Africa, the Middle East, western North America, and Central Asia. Source: United States Geological Survey Earth Forum, Houston Museum Natural Science<\/p>\n

Surface Water Resources: Rivers, Lakes, Glaciers<\/strong><\/p>\n

Figure 4. Surface Runoff Surface runoff, part of overland flow in the water cycle Source: James M. Pease at Wikimedia Commons<\/p>\n

Flowing water from rain and melted snow on land enters river channels by surface runoff (Figure 4) and groundwater seepage (Figure 5).\u00a0River\u00a0discharge<\/strong>\u00a0 describes the volume of water moving through a river channel over time (Figure 6). The relative contributions of surface runoff vs. groundwater seepage to river\u00a0discharge depend on precipitation patterns, vegetation, topography, land use, and soil characteristics. Soon\u00a0after a heavy rainstorm, river discharge increases due to surface runoff. The steady normal flow of river\u00a0water is mainly from groundwater that discharges into the river. Gravity pulls river water downhill toward\u00a0the ocean. Along the way the moving water of a river can erode soil particles and dissolve minerals. Groundwater also contributes a large amount\u00a0of the dissolved minerals in river water. The geographic area drained by a river and its tributaries is called a\u00a0drainage basin\u00a0<\/strong>or\u00a0watershed<\/strong>. The Mississippi River drainage basin includes approximately 40% of the U.S., a measure\u00a0that includes the smaller drainage basins, such as the Ohio River and Missouri\u00a0River that help to comprise it. Rivers are an important water resource for irrigation of cropland and drinking water for many cities around\u00a0the world. Rivers that have had international disputes over water supply include the\u00a0Colorado (Mexico, southwest U.S.), Nile (Egypt, Ethiopia, Sudan), Euphrates (Iraq, Syria, Turkey), Ganges\u00a0(Bangladesh, India), and Jordan (Israel, Jordan, Syria).<\/p>\n

Figure 5. Groundwater Seepage. Groundwater seepage can be seen in Box Canyon in Idaho, where approximately 10 cubic meters per second of seepage emanates from its vertical headwall. Source: NASA<\/p>\n

In addition to rivers, lakes can also be an excellent source of freshwater for human use. They usually receive water from\u00a0surface runoff and groundwater discharge. They tend to be short-lived on a geological time-scale because\u00a0they are constantly filling in with sediment supplied by rivers. Lakes form in a variety of ways including\u00a0glaciation, recent tectonic\u00a0uplift (e.g., Lake Tanganyika, Africa), and volcanic eruptions (e.g., Crater Lake, Oregon). People also create artificial\u00a0lakes (reservoirs<\/strong>) by damming rivers. Large changes in climate can result in major changes in a lake\u2019s size.\u00a0As Earth was coming out of the last Ice Age about 15,000 years\u00a0ago, the climate in the western\u00a0U.S. changed from cool and moist to warm and arid, which caused more than 100 large lakes to disappear.\u00a0The Great Salt Lake in Utah is a remnant of a much larger lake called Lake Bonneville.<\/p>\n

Figure 6. River Discharge Colorado River, U.S.. Rivers are part of overland flow in the water cycle and an important surface water resource. Source: Gonzo fan2007 at Wikimedia Commons.<\/p>\n

Although\u00a0glaciers<\/strong>\u00a0represent the largest reservoir of fresh water, they generally are not used as a water\u00a0source because they are located too far from most people (Figure 7). Melting glaciers do provide a natural source of river water and groundwater. During the last\u00a0Ice Age there was as much as 50% more water in glaciers than there is today, which caused sea level to be\u00a0about 100 m lower. Over the past century, sea level has been rising in part due to melting glaciers. If Earth\u2019s\u00a0climate continues to warm, the melting glaciers will cause an additional rise in sea level.<\/p>\n

Figure 7. Mountain Glacier in Argentina Glaciers are the largest reservoir of fresh water but they are not used much as a water resource directly by society because of their distance from most people. Source: Luca Galuzzi \u2013 www.galuzzi.it<\/p>\n

Groundwater Resources<\/strong><\/p>\n

Although most people in the world use surface water, groundwater is a much larger reservoir of\u00a0usable fresh water, containing more than 30 times more water than rivers and lakes combined. Groundwater is a particularly important resource in arid climates, where surface water may be scarce. In addition, groundwater is the primary water source for rural homeowners, providing 98% of that water demand in\u00a0the U.S..\u00a0Groundwater<\/strong>\u00a0is water located in small spaces, called\u00a0pore space<\/strong>, between mineral grains and fractures in subsurface earth materials (rock or sediment).\u00a0Most groundwater originates from rain or snowmelt, which infiltrates the ground and moves downward until it reaches the\u00a0saturated zone<\/strong>\u00a0(where groundwater completely fills pore spaces in earth materials).<\/p>\n

Other sources of groundwater include seepage from surface water (lakes, rivers, reservoirs,\u00a0and swamps), surface water deliberately pumped into the ground, irrigation, and underground wastewater\u00a0treatment systems (septic tanks).\u00a0Recharge areas<\/strong>\u00a0are locations where surface water infiltrates the\u00a0ground rather than running into rivers or evaporating. Wetlands, for example,\u00a0are\u00a0excellent recharge areas. \u00a0A large area of sub-surface, porous rock that holds water is an aquifer. Aquifers are commonly drilled, and wells installed, to provide water for agriculture and personal use.<\/p>\n

Water Use in the U.S. and World<\/strong><\/p>\n

People need water, oftentimes large quantities, to produce the food, energy, and mineral resources they use. \u00a0Consider, for example, these approximate water requirements for some things people in the developed\u00a0world use every day: one tomato = 3 gallons; one kilowatt-hour of electricity from a thermoelectric power\u00a0plant = 21 gallons; one loaf of bread = 150 gallons; one pound of beef = 1,600 gallons; and one ton of steel\u00a0= 63,000 gallons. Human beings require only about 1 gallon per day to survive, but a typical person in a\u00a0U.S. household uses approximately 100 gallons per day, which includes cooking, washing dishes and clothes,\u00a0flushing the toilet, and bathing. \u00a0The\u00a0water demand<\/strong>\u00a0of an area is a function of the population and other uses of water.<\/p>\n

Figure 8. Trends in Total Water Withdrawals by Water-use Category, 1950-2005 Trends in total water withdrawals in the U.S. from 1950 to 2005 by water use category, including bars for thermoelectric power, irrigation, public water supply, and rural domestic and livestock. Thin blue line represents total water withdrawals using vertical scale on right. Source: United States Geological Survey<\/p>\n

Figure 9. Trends in Source of Fresh Water Withdrawals in the U.S. from 1950 to 2005 Trends in source of fresh water withdrawals in the U.S. from 1950 to 2005, including bars for surface water, groundwater, and total water. Red line gives U.S. population using vertical scale on right. Source: United States Geological Survey<\/p>\n

Global total water use is steadily increasing at a rate greater than world\u00a0population growth (Figure 10). During the 20th century global population tripled and water demand grew by a\u00a0factor of six. The increase in global water demand beyond the rate of population growth is due to improved\u00a0standard of living without an offset by water conservation. Increased production of goods and energy entails\u00a0a large increase in water demand. The major global water uses are irrigation (68%), public supply\u00a0(21%), and industry (11%).<\/p>\n

Figure 10. Trends in World Water Use from 1900 to 2000 and Projected to 2025 For each water major use category, including trends for agriculture, domestic use, and industry. Darker colored bar represents total water extracted for that use category and lighter colored bar represents water consumed (i.e., water that is not quickly returned to surface water or groundwater system) for that use category. Source: Igor A. Shiklomanow, State Hydrological Institute (SHI, St. Petersburg) and United Nations Educational, Scientific and Cultural Organisation (UNESCO, Paris), 1999<\/p>\n

Attribution<\/strong><\/p>\n

Essentials of Environmental Science<\/a>\u00a0by\u00a0Kamala Dor\u0161ner\u00a0is licensed under\u00a0CC BY 4.0<\/a>. Modified from the original\u00a0by Matthew R. Fisher.<\/p>\n

 <\/p>\n

7.2 Water Supply Problems and Solutions Water Supply Problems: Resource Depletion<\/strong><\/p>\n

As groundwater is pumped from water wells, there usually is a localized drop in the water table around the\u00a0well called a cone of depression. When there are a large number of wells that have been pumping water for\u00a0a long time, the regional water table can drop significantly. This is called\u00a0groundwater mining<\/strong>, which\u00a0can force the drilling of deeper, more expensive wells that commonly encounter more saline groundwater.\u00a0Rivers, lakes, and artificial lakes (reservoirs) can also be depleted\u00a0due to overuse. Some large rivers, such as the Colorado in the U.S. and Yellow in China, run dry in some\u00a0years. The case history of the Aral Sea discussed later in this chapter\u00a0involves depletion of a lake. Finally, glaciers are\u00a0being depleted due to accelerated melting associated with global warming over the past century.<\/p>\n

Figure 1. Formation of a Cone of Depression around a Pumping Water Well Source: Fayette County Groundwater Conservation District, TX<\/p>\n

Another water resource problem associated with groundwater mining is saltwater intrusion, where\u00a0overpumping of fresh water aquifers near ocean coastlines causes saltwater to enter fresh water zones. The drop of the water table around a\u00a0cone of depression<\/strong>\u00a0in an unconfined aquifer can change the direction of regional groundwater flow, which could\u00a0send nearby pollution toward the pumping well instead of away from it. Finally, problems of\u00a0subsidence\u00a0<\/strong>(gradual sinking of the land surface over a large area) and\u00a0sinkholes<\/strong>\u00a0(rapid sinking of the land surface over\u00a0a small area) can develop due to a drop in the water table.<\/p>\n

Water Supply Crisis<\/strong><\/p>\n

The\u00a0water crisis<\/strong>\u00a0refers to a global situation where people in many areas lack access to sufficient water, clean water, or both. This section describes the global situation involving water shortages, also called\u00a0water stress<\/strong>. In general, water stress is greatest in areas with very low precipitation (major deserts), large population density (e.g., India), or both. Future global warming could worsen the water crisis by shifting precipitation patterns away from humid areas and by melting mountain glaciers that recharge rivers downstream. Melting glaciers will also contribute to rising sea level, which will worsen saltwater intrusion in aquifers near ocean coastlines.<\/p>\n

Figure 2. Countries Facing Water Stress in 1995 and Projected in 2025 Water stress is defined as having a high percentage of water withdrawal compared to total available water in the area. Source: Philippe Rekacewicz (Le Monde diplomatique), February 2006<\/p>\n

According to a 2006 report by the United Nations Development Programme, 700 million people (11% of the world\u2019s population) lived with water stress. Most of them live in the Middle East and North Africa. By 2025, the report projects that more than 3 billion people (about 40% of the world\u2019s population) will live in water-stressed\u00a0areas with the large increase coming mainly from China and India. The water crisis will also impact food production and our ability to feed the ever-growing population. We can expect future global tension and even conflict associated with water shortages and pollution. Historic and future areas of water conflict include the Middle East (Euphrates and Tigris River conflict among Turkey, Syria, and Iraq; Jordan River conflict among Israel, Lebanon, Jordan, and the Palestinian territories), Africa (Nile River conflict among Egypt, Ethiopia, and Sudan), Central Asia (Aral Sea conflict among Kazakhstan, Uzbekistan, Turkmenistan, Tajikistan, and Kyrgyzstan), and south Asia (Ganges River conflict between India and Pakistan).<\/p>\n

Sustainable Solutions to the Water Supply Crisis?<\/strong><\/p>\n

The current and future water crisis described above requires multiple approaches to extending our fresh\u00a0water supply and moving towards sustainability. Some of the longstanding traditional approaches include\u00a0dams and aqueducts.<\/p>\n

Figure 3. Hoover Dam, Nevada, U.S. Hoover Dam, Nevada, U.S.. Behind the dam is Lake Mead, the largest reservoir in U.S.. White band reflects the lowered water levels in the reservoir due to drought conditions from 2000 \u2013 2010. Source: Cygnusloop99 at Wikimedia Commons<\/p>\n

Reservoirs<\/strong>\u00a0that form behind dams in rivers can collect water during wet times and\u00a0store it for use during dry spells. They also can\u00a0be used for urban water supplies. Other benefits of dams and reservoirs are\u00a0hydroelectricity, flood control, and recreation. Some of the drawbacks are evaporative loss of water\u00a0in arid climates, downstream river channel erosion, and impact on the ecosystem including a change from\u00a0a river to lake habitat and interference with migration and spawning of fish.<\/p>\n

Aqueducts<\/strong>\u00a0can move water from\u00a0where it is plentiful to where it is needed. Aqueducts can be controversial and politically\u00a0difficult especially if the water transfer distances are large. One drawback is the water diversion can cause\u00a0drought in the area from where the water is drawn. For example, Owens Lake and Mono Lake in central\u00a0California began to disappear after their river flow was diverted to the Los Angeles aqueduct. Owens Lake\u00a0remains almost completely dry, but Mono Lake has recovered more significantly due to legal intervention.<\/p>\n

One method that can actually increase the amount of fresh water on Earth is\u00a0desalination<\/strong>, which\u00a0involves removing dissolved salt from seawater or saline groundwater. There are several ways to desalinate\u00a0seawater including boiling, filtration, and electrodialysis. All of these procedures are moderately\u00a0to very expensive and require considerable energy input, making the water produced much more expensive\u00a0than fresh water from conventional sources. In addition, the process creates highly saline wastewater, which\u00a0must be disposed of and creates significant environmental impact. Desalination is most common in the Middle East, where energy from oil is abundant\u00a0but water is scarce.<\/p>\n

Figure 4. The California Aqueduct California Aqueduct in southern California, U.S. Source: David Jordan at en.wikipedia<\/p>\n

Conservation<\/strong>\u00a0means using less water and using it more efficiently. Around the home, conservation can\u00a0involve both engineered features, such as high-efficiency clothes washers and low-flow showers and toilets, as\u00a0well as behavioral decisions, such as growing native vegetation that require little irrigation in desert climates,\u00a0turning off the water while you brush your teeth, and fixing leaky faucets.<\/p>\n

Rainwater harvesting<\/strong>\u00a0involves\u00a0catching and storing rainwater for reuse before it reaches the ground. Another important technique is\u00a0efficient irrigation,\u00a0<\/strong>which is extremely\u00a0important because irrigation accounts for a much larger water demand than public water supply. Water\u00a0conservation strategies in agriculture include growing crops in areas where the natural rainfall can support\u00a0them, more efficient irrigation systems such as drip systems that minimize losses due to evaporation, no-till\u00a0farming that reduces evaporative losses by covering the soil, and reusing treated wastewater from sewage\u00a0treatment plants. Recycled wastewater has also been used to recharge aquifers.<\/p>\n

Suggested Supplementary Reading:<\/strong><\/h3>\n

Weiss, K.R. 2018.\u00a0Drying Lakes<\/a>.\u00a0National Geographic.\u00a0<\/em>March. p. 108-133.<\/p>\n

This article documents how many lakes across the globe are drying up, the reasons why, and the effect on humans. Overuse and a warming climate threaten lakes that provide sustenance and jobs for humans, while also providing critical habitat for animals.\u00a0<\/em><\/p>\n

Attribution<\/strong><\/p>\n

Essentials of Environmental Science<\/a>\u00a0by\u00a0Kamala Dor\u0161ner\u00a0is licensed under\u00a0CC BY 4.0<\/a>. Modified from the original\u00a0by Matthew R. Fisher.<\/p>\n","protected":false},"parent":0,"menu_order":6,"template":"","meta":{"pb_part_invisible":false,"pb_part_invisible_string":""},"contributor":[],"license":[],"class_list":["post-85","part","type-part","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/pressbooks\/v2\/parts\/85","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/pressbooks\/v2\/parts"}],"about":[{"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/wp\/v2\/types\/part"}],"version-history":[{"count":0,"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/pressbooks\/v2\/parts\/85\/revisions"}],"wp:attachment":[{"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/wp\/v2\/media?parent=85"}],"wp:term":[{"taxonomy":"contributor","embeddable":true,"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/wp\/v2\/contributor?post=85"},{"taxonomy":"license","embeddable":true,"href":"https:\/\/pressbooks.ccconline.org\/accecosphereenvironmental\/wp-json\/wp\/v2\/license?post=85"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}