Production: Too Much and Too Little

There is a great range in agricultural production around the world. Some countries, using high technology and advanced methods, produce more through agriculture than they need or can use, while others—underdeveloped and poorer—never produce enough to sustain their populations.

The farming systems that maintained ancient civilizations in Asia Minor or in the New World are incapable of supporting populations in those areas today. In underdeveloped Africa, farming techniques are improving but are not even as advanced as those of the ancient Babylonians or the Incas.

Nations with more advanced agriculture often attempt to help such areas improve farm productivity. This aid is often invaluable, but sometimes questionable for the long term. Agricultural systems are intimately connected to places and peoples. Propelling such areas into modern agricultural cropping techniques may be a shock to the local culture. Advanced technologies may not be advisable under the climatic and soil conditions of the area. The native method is often a marvel of ingenuity developed over many generations through intimate contact with a unique situation. There may be no bumper crops, but the wonder is that there is any crop at all.

Many countries in the Western Hemisphere consistently produce more food than they use. The surpluses are stored in granaries and warehouses for later use or sale to other countries. Storing the surpluses costs money because giant bins and huge buildings must be built and maintained. Techniques for reducing spoilage and loss to pests add to the cost.

As farmers continue to seek the greatest possible yield for the most reasonable cost, advanced agriculture is becoming as elaborate and as complicated as other modern industries. In the United States and in other wealthy nations where population is not yet a burden, the cost of labor is relatively high and is the limiting factor in production. Thus there has been more and more mechanization and automation.

Feeding the World

In general, the world is no better fed today than decades ago. The world's population is growing at an alarming rate, and agriculture has just barely kept up with it. Despite overproduction in some nations, perhaps one out of six persons throughout the world is undernourished. Some studies show that as much as half of the world's population may be suffering from malnutrition or starvation.

Distribution of agricultural surpluses to areas of deficiency seems an ideal solution. But it is far more difficult than it seems. The surpluses currently produced by agriculturally advanced countries are often given to school lunch programs, to families on public assistance, and to welfare institutions within the nations themselves. Food and fiber crops are sold abroad for foreign currencies to improve the producing country's balance of trade.

Even if the food could be easily distributed to other nations, the costs for transporting it run high. Some nations may complain that others ruin their markets by giving a commodity away or selling it at cut-rate prices. These problems, too, must be carefully weighed against the benefits to poorer countries.

Government's Role

Because agriculture is so important to a nation's well-being, governments have always been concerned with it. For example, the United States and Canada have long produced surpluses that complicate their economies. Surpluses tend to lower prices to farmers and seriously endanger the agriculture industry. Governments have instituted systems of price supports to maintain a fair price when surpluses cause prices to drop. The system in the United States is a good example. A government program supports the prices paid to farmers for grains, soybeans, cottonseed and other oilseeds, peanuts, cotton, tobacco, butter, cheese, dried milk, wool, mohair, and honey.

Support prices are based on parity, which is the ratio between the prices farmers receive for their crops and the prices they must pay for things they need. The government selected the period from 1910 to 1914 as a time when farm prices were in a fair ratio with farming costs. This is the base period now used to determine parity prices.

The idea is to assure farmers that what they get for a bushel of wheat will buy the same amount of, say, seed as it did in the years of the base period. If prices drop too far below this ideal the government can help in a number of ways. For example, it may buy much of a surplus at parity prices. Governments have instituted a wide variety of other controls for prices and, also, for farm output, mainly at the request of the farmers themselves. Farm prices tend to fluctuate more than other prices do, and the incomes of farmers fluctuate along with farm prices.

Various measures for maintaining farm prices and incomes include tariff or import levies, import quotas, export subsidies, direct payment to farmers, and limitations on production. All of these measures are useful and are used to some extent by most developed countries. An important example of such a program is the soil-bank plan, which aimed at limiting production while improving farmland. The soil-bank plan was passed by the United States Congress in 1956. It allowed a farmer to withdraw land from production for three-, five-, or ten-year periods and receive rental payments from the government for doing so. The farmer planted such land with grass, trees, or other vegetation that would help prevent erosion and aid fertility. New soil-bank rentals ended in 1960.

The European Economic Community (EEC) established a common agricultural policy (CAP) for its member nations, called the Common Market countries. The aim is to create free trade for individual commodities within the community. When production of a commodity exceeds EEC consumption, the EEC may buy the excess for storage, pay to have it reprocessed, or export it to countries outside the Common Market. In this way the EEC can maintain its members' farm prices at levels equal to or even higher than those in such market-competitive nations as the United States and Canada.

Agricultural Landmarks

Grazing animals were likely domesticated before plants were tended. Among the earliest animals domesticated were the elk in Scandinavia, the gazelle in the Middle East, and the dog in western North America. Sheep, cattle, and pigs came later.

The first crops probably included grains such as wheat, oats, rye, barley, and millet; and legumes such as peas, lentils, vetch, chick-peas, and horsebeans. Grapes, olives, dates, apples, pears, cherries, and figs were among early domesticated fruits.

Mesopotamia, called the cradle of civilization, influenced all of antiquity, especially Syria and Egypt and perhaps India and China. Its ancient cultures—Sumerian, Babylonian, Assyrian, and Chaldean—developed an increasingly complex and rich agricultural system that freed many people from farming. As a result, the first cities arose in Mesopotamia.

Ancient farming is clearly recorded in Egypt, where it flourished along the Nile. Egyptian farmers developed drainage and irrigation techniques through construction of a system of dikes and canals. During this time farming tools were developed and refined.

Greek influence upon agriculture was the establishment of the science of botany. Roman agricultural practices are well recorded. The earliest writing, from about 200 BC, on farming is Cato's ‘De agricultura', an essay on the practical aspects of crop and livestock management. Up to 200 BC Roman agriculture consisted of farms of one to four acres, intensively managed. Larger farms owned by absentee landowners were developed later, with slaves used to run them. Despite social upheavals in the Roman Empire, its agricultural technology—although inferior to that of the Egyptians—was not equaled in Europe until the Renaissance. The Romans discovered and carefully noted relatively sophisticated techniques such as grafting and budding, crop rotation, and the use of fertilizers. They also originated an early type of greenhouse. (See also Ancient Civilization.)

With the decline of the Roman Empire in the 3rd century AD, the Middle East and the Far East became the centers of technological advance, especially between AD 500 and 1500. Crop growing was based on extensive production in large fields and intensive production in small gardens. There were common pastures for the cattle or other domestic animals.

The usual method of crop farming was a fallow system, in which one third of the land was not planted each year, to restore soil fertility. Fields were partitioned into strips that were rotated among the tenant farmers. Strip farming gave way ultimately to an enclosed system, with individual farmers responsible for their own lands. Crop rotation and improved plowing techniques evolved.

By the end of the Middle Ages, most of the tillable land of Europe was cleared, drained, and in cultivation. At that time the transition from medieval to modern agricultural practices began. This transition is called the agricultural revolution. New foods entered European farming. During the 16th century the potato and maize (corn), imported from the New World, and rice, introduced earlier from Asia, came under cultivation in Europe.

The classification of agriculture into agronomy, horticulture, and forestry has been traced to medieval times. Agronomy came to refer to the growing of grains and forage plants, or field crops. Horticulture developed from small garden plots that provided fruits and herbs as well as ornamental plants for the medieval manor. Forestry developed from the wild lands that produced timber for the landowner and supported game animals hunted by the nobles.

As feudalism ended, technology was developing and agricultural methods, tools, and products were improving. New industries arose, creating markets for such crops as sugarcane, hemp, flax, vegetable oils, and dyes. The growing of grapes for wine became a key industry. New farming systems of enclosed fields, crop rotation, and feeding animals in stalls became more efficient with time. Mechanization was beginning for agriculture. Plows, seed sowers, threshers, and harvesters were introduced.

Farming in the Economy

Most of the farmers throughout the world live in underdeveloped countries and practice subsistence farming. They raise just enough plants and tend just enough animals for their own needs and have little, if anything, to trade for other goods. This type of farming hinders a nation's development. More productive agriculture has played a major part in the growth of developed countries. Typically, a country's development depends upon its ability to produce a surplus of food to maintain a nonfarming labor force in its urban areas. Put another way, the economic development of a nation requires a growing nonfarm labor force, and so the diminishing farm community must produce more food with fewer hands. Many countries find it difficult to reach this goal.

Agricultural systems have developed in response to tradition, geographic area, type of crop, and level of technology. They are also shaped by many factors not obviously related to them. Farming in North America, for example, developed out of traditional farming in the Old World. Corn was soon seen to be a valuable crop and became the dominant grain raised. Tobacco, cotton, and rice, which require many hands to tend, stimulated slavery.

The United States was originally an agricultural nation. In 1800, 90 percent of the working population was engaged in farming. By the 1980s, only about 5 percent worked on farms, but each worker produced enough for more than 20 people. In contrast, in India and other poorer countries a typical farm worker produced enough only for about four persons.

Shifting Agriculture

While technology is advancing in many parts of the world, some primitive cultures in sparsely populated tropical areas still practice a shifting system of agriculture. This system is a type of slash-and-burn agriculture, in which land is cleared of plant life, which is burned to add some nutrients to the soil. This is followed by planting. When the land is exhausted, it is abandoned and new clearings are slashed and burned. This process is wasteful of native vegetation and is abusive to the land. The milpa of tropical America and the ladang system of the Orient are examples of such farming practices.

Plantation Agriculture

A plantation is a large area of land that is usually privately or government owned and employs resident labor to cultivate a single commercial crop. Plantation agriculture is generally found in tropical and subtropical regions. This type of agriculture has achieved new degrees of efficiency in Central and South America and some other areas where such crops as cacao, sugarcane, coconut, banana, pineapple, breadfruit, and other tropical plants are raised under efficient agricultural methods.

Typically plantations develop as settlements grow and slash-and-burn farming exhausts the land. Villagers then turn to tending groves of coconut, breadfruit, banana, citrus, and avocado trees that can thrive permanently under tropical and subtropical soil and climate conditions. The rubber plantations of Sumatra and Malaya, cacao plantations of Africa and Central America, and the sugar and coffee plantations throughout the tropics are probably the best methods of using the land under existing conditions.

Forests have only recently became regarded as croplands to be managed for continuous production, like plantations, with specialized techniques and machines for planting, harvesting, and replanting. (See also Forest and Forestry.)

Orcharding

Orcharding is a more intensive method of fruit and nut tree cropping than plantation agriculture. In other words, it demands more skill and effort to be done successfully. The first orchards came into being in the Temperate Zones of Europe, Asia, and North America. Crops such as apples, pears, plums, apricots, and cherries are grown in orchards.

In the United States, many orchards are found concentrated in the coastal Northwest and the Great Lakes regions. There are extensive pear orchards in the Rhone Valley of Europe, and apple and pear orchards in northern Italy. Southern Australia, South Africa, and southern Argentina are also areas of fruit orcharding. China has about 12 million acres (4.9 million hectares) of orchards, yielding in excess of 5 million tons (4.5 million metric tons) of fruit each year.

In the United States and Europe, apple, citrus, pear, peach, plum, apricot, cherry, pecan, and walnut are the principal orchard-grown crops. Although grapes are sometimes grown in orchards, along with some other fruit, they are more usually grown in vineyards. (See also Fruitgrowing.)

Floodplain Farming

Farming in the tropics often includes floodplain cropping with periodic irrigation. A river's floodplain is the area on either side of the river over which it deposits soil when it floods. Farming is practiced along the floodplains of rivers such as the Nile in Egypt and large waterways in the Orient, where paddies are formed by terracing. Floodplain farming is most successfully used in Southeast Asia.

Burning-grazing

In many parts of the world grasses cover the land to the horizon. Livestock grazing is ideal in these areas, which include the prairies of the western United States, the pampas of South America, tropical savannas of Africa, and steppes of Asia. Periodic, controlled burning is practiced in such areas to keep woody brush from gaining a foothold and to stimulate continuing grass growth.

Desert Farming

Some of the richest plant areas are along stream borders in desert valleys. Desert land apparently lacks only water to be productive. Now, irrigation projects transport water for many miles to produce large crops in places like the interior desert valleys of California, Arizona, Colorado, and Texas in the United States. The deserts of the Middle East are in the beginning phases of large-scale agricultural production in such places as Egypt and Israel. A host of innovative irrigation techniques, such as drip irrigation, have originated in these areas.

Diversified General Farming

The farming traditional to Western cultures in temperate regions is diversified general farming. In this type of farming, a variety of crops is grown, including most of the Temperate Zone crops, and especially corn, small grains, and soybeans. In the south, tobacco, beans, peanuts, corn, small grains, hay and forage crops, and fruit trees are grown. Diversified general farming produces great self-sufficiency for the farmer, even more so if some livestock are also raised, as is often the case.

Prairie Farming

Much prairie land is used for the burning-grazing agriculture described earlier. Large acreages are usually devoted to a single crop or only a few. The prairie wheat fields of Canada and the cornfields of the United States are examples. Each year, with rare exceptions, this land yields larger and larger harvests because of more productive crop strains and improved farming techniques.

Mechanization

The full influence of mechanization began shortly after 1850, when a variety of machines came rapidly into use. The introduction of these machines frequently created rebellions by workers who were fearful that the machines would rob them of their work. Patrick Bell, in Scotland, and Cyrus McCormick, in the United States, produced threshing machines. Ingenious improvements were made in plows to compensate for different soil types. Steam power came into use in the 1860s on large farms. Hay rakes, hay-loaders, and various special harvesting machines were produced. Milking machines appeared. The internal-combustion engine—run by gasoline—became the chief power source for the farm.

In time, the number of certain farm machines that came into use skyrocketed and changed the nature of farming. Between 1940 and 1960, for example, 12 million horses and mules gave way to 5 million tractors. Tractors offer many features that are attractive to farmers. There are, for example, numerous attachments: cultivators that can penetrate the soil to varying depths, rotary hoes that chop weeds; spray devices that can spray pesticides in bands 100 feet (30 meters) across, and many others.

A piece of equipment has now been invented or adapted for virtually every laborious hand or animal operation on the farm. In the United States, for example, cotton, tobacco, hay, and grain are planted, treated for pests and diseases, fertilized, cultivated, and harvested by machine. Large devices shake fruit and nuts from trees, grind and blend feeds, and dry grain and hay. Equipment is now available to put just the right amount of fertilizer in just the right place, to spray an exact row width with herbicides, and to count out, space, and plant just the right number of seeds for a row.

Mechanization is not used in agriculture in many parts of Latin America, Africa, and heavily populated areas of the Orient, where human and animal labor is usually far less expensive than are machines. Agricultural innovation is accepted fastest where agriculture is already profitable and progressive. Some mechanization has reached the level of plantation agriculture in parts of the tropics, but even today much of that land is laboriously worked by people leading draft animals pulling primitive plows.

The problems of mechanizing some areas are not only cultural in nature. For example, tropical soils and crops differ markedly from those in temperate areas that the machines are designed for; so adaptations have to be made. But the greatest obstacle to mechanization is the fear in underdeveloped countries that the workers who are displaced by machines would not find work elsewhere. Introducing mechanization into such areas requires careful planning.

Tillage Systems

Deep tilling, in which the soil is plowed deeply, is being superseded in many areas by shallow plowing or no plowing at all. This is one of several techniques that are effective in controlling soil erosion. In the fallow system, which dates back to ancient times, land is plowed and tilled but not planted to a crop. This is to rest and rejuvenate the land. The disadvantage is that such fallow land is more vulnerable to wind and water erosion than is planted land. Plowing along the contours of the land is called contour tillage. This and building terraces on sloping land help to conserve moisture by preventing excessive water runoff on moderately sloping land.

Minimum tillage appears to be gaining acceptance in many areas of the world. With minimum tillage, soil is disturbed as little as possible. In fact, in some areas zero tillage, or no tillage at all, is a growing practice. Weeds can be killed chemically and left as a soil-improving mulch. Crops are planted in untilled land by special machines. Yields of potatoes, parsnips, carrots, gooseberries, broad beans, and brussels sprouts are close to, and sometimes slightly better than, yields under traditional cultivation practices, which consume more time and energy. Corn and soybeans under zero tillage often yield more than under standard cultivation.

Intensive Cropping

Another trend is toward growing more plants in any given space. Increased fertilization and irrigation are often required to do this. But the dense growth usually reduces soil erosion and chokes out weeds, making weeding unnecessary. Cotton, sorghum, sugar beets, soybeans, and corn are effectively grown in such dense plantings.

Field Processing

In some areas field processing of crops is becoming a standard practice. The farmers use machines that process crops as they are harvested. Corn is shelled, or removed from the cob, as it is picked. Hay is baled and tossed onto a wagon, ready to be stored or sold. The idea behind machine processing in the field is to avoid unnecessary handling and storage of unprocessed crops.

Crop and Livestock Improvement

Crop improvement is continuous. Professional plant breeders are constantly working, through genetics, on the improvement of plants to meet changing needs and standards. For example, with the introduction of mechanical pickers for tomatoes, a tomato resistant to bruising by the machine was needed. Such a variety was created by plant breeders.

Better, higher-yielding crop varieties have played an important part in the increase in crop production per acre in the United States and some other nations. Varieties of rice, cotton, vegetable-oil crops, and sugar crops have changed almost completely since 1950. By the late 1960s most crop acreage in the United States was producing varieties unknown in earlier decades. Best known of the improved crops are the many varieties of hybrid corn that are planted on more than 97 percent of the total corn acreage in the United States. Government experimental laboratories and commercial seed companies shared in the research and development of the high-yield plant varieties that provide such superior characteristics as resistance to cold, drought, diseases, and pests.

Improvements in livestock, such as more efficient use of feed, has added greatly to annual farm output. Such improvements are the result of breeding and improved husbandry and veterinary techniques. Special-purpose stock has been developed through selective breeding. It includes cattle that are able to thrive in subtropical regions, hogs that yield lean bacon instead of lard, and small and broad-breasted turkeys. (See also Cattle; Pig; Poultry; Turkey.)

Artificial insemination has become a major factor in cattle improvement. In this technique the sperm of genetically superior bulls is used to inseminate thousands of cows. In this way a herd can be upgraded significantly in a single generation. However, some people feel that producing plants and animals that conform to the needs of mechanization and increased production has resulted in less desirable farm products.

Pesticides, Herbicides, Growth Regulators

Better control of plant and animal diseases and pests has aided the increase in agricultural output. Inorganic chemical pesticides were generally used before 1945. Organic chemicals developed later include chlorinated hydrocarbons, such as toxaphene and benzene hexachloride. They also include organic phosphates, such as malathion and parathion.

The use of airplanes in spraying crops with these chemicals made the work more efficient. A plane can spray 1,000 acres (400 hectares) in a matter of minutes. Research in insecticides must go on continuously, since insects tend to develop immunity to sprays. Each new chemical is tested to be sure that no harmful residue will poison treated food plants. The combined use of minimal amounts of chemicals and of natural methods to control pests is called integrated pest management and is considered by many to be the most desirable control technique. Natural ways of controlling the spread of a pest population include disrupting the pest species's reproductive ability by releasing sterilized individuals into a population; releasing natural predators of a pest into a crop; and raising only pest-resistant crop varieties.

Insects, mites, and ticks that attack domestic animals can cost stock raisers millions of dollars annually. Methods worked out to free the animals from several types of pests have resulted, for example, in desirable weight gains and increased milk production. Antibiotics are given to animals in feed and as medicine. By checking and preventing disease, the antibiotics promote growth, weight gain, and efficient use of feed. To increase milk output, cows are sometimes given bovine growth hormone. (See also Dairy Industry; Insect; Scale Insect.)

The use of chemicals to kill weeds has saved much labor and has led to crop increases. The application of chemicals began on a large scale after the discovery in 1944 that 2,4-D (2,4-dichlorophenoxyacetic acid) kills broad-leaved weeds but not grasses. This kind of selective action is ideal if some plants (the crop) are to be saved, while others (the weeds) are killed. Since that time more than 100 weed killers have been developed. They may be applied by special machines before or after the crop plant emerges. (See also Weed.)

Research has shown ways to regulate or control the growth of the plants by means of chemicals, such as the gibberellins, fumaric acid, maleic hydrazide, and CCC (2-chloroethyl trimethyl ammonium chloride). Such regulators are used to increase the size of fruits or to influence the direction of growth or the plant structure. Hormones are used to retard the falling of fruit, thus extending the harvest period. Artificial control methods are usually considered controversial because of possible harmful effects to human health.

Fertilizers and Lime

Agricultural experts credit greater and more scientific use of fertilizers and lime with a major share of the increase in farm production since 1940. The liming of acid soils in humid areas is a general practice in advanced agricultural countries. The lime reduces the acidity of the soils, making them more productive when planted with most crops.

Farmers dig soil samples from their fields and send them to soil laboratories operated by the government or by private companies. After testing the samples, the technicians recommend a fertilizer mixture, in terms of pounds per acre, of nitrogen, phosphorus, and potassium—the chief elements used by plants. These fertilizers may also contain small amounts of minor elements, called micronutrients or trace elements. Many machines have been developed for applying fertilizers to various crops.

To return organic matter to the soil, thus keeping it in good physical condition as well as providing fertilizer, farmers plow under available manure and cornstalks, alfalfa, clover, and other so-called green manure plants. Residue from the processing of plants and animals is used as organic fertilizer. Waste from fish canneries and meatpacking plants is also widely used. (See also Fertilizer.)

Fertilizer and Pesticide Improvement

Farm manure is the major source of organic matter and plant nutrients in many parts of the world. Manure includes both animal excrement and animal bedding materials such as straw and wood chips.

The beneficial effects of organic matter and chemicals in the growth of crops have long been known. But only recently have sophisticated systems of chemical release and application been generated rapidly. The goal of most research is to determine precisely how much nutrient to add to a crop and when it is best to add it.

Although there is continued use of standard chemical sources of nitrogen—the most needed and most expensive nutrient—such as anhydrous ammonia, ammonium nitrate, and urea, cheaper and better ways of providing nitrogen are available. Concentrated liquid fertilizers are often used, as is customized mixing of fertilizers based on soil and plant analysis.

Larger and more precise fertilizing machines are being developed. Biodegradable tapes, with seed, fertilizer, and pesticide already incorporated, have found acceptance in gardening and application in some commercial agriculture.

The pesticide industry continues to produce standard control products while actively engaging in the search for more effective and safer ones. Herbicides are of increasing importance, especially under zero tillage systems of farming. Fungicides and other protectants against disease are expensive and may not be as advantageous in the long run as the breeding of disease-resistant strains of crops.

The future of chemical pesticides—including insecticides, fungicides, and herbicides—is being reconsidered on several levels: by the manufacturers, the sellers, and the buyers. The concern for environmental quality demands that greater care be given to development and use of these valuable yet potentially hazardous substances. Integrated control—the use of biological agents along with chemicals when necessary—is perceived as more and more desirable.

Fish-farming and Other Aquaculture

Fish-farming involves raising small immature fishes as livestock, under the best conditions possible. The Chinese have raised carp for several thousands of years, and the Japanese and others have raised certain other species of fishes with varying degrees of success. Now some researchers claim that the time is near when the problem of feeding a growing world population could be solved by farming the edges of the sea, raising not only fishes, but also lobsters, shrimps, and other shellfishes under optimum conditions. Commercial culture of lobsters, shrimps, and clams is in its infancy, but continues to develop. Under ideal conditions, such as those found in parts of Spain, edible bivalves are raised in great numbers.

Commercial farming of algae as human or farm-animal food has yet to begin. However, seaweed and other algae are collected for food and other uses in several parts of the world. (See also Aquaculture.)

Hydroponics, or soilless culture of plants in liquids, is used on a small scale in greenhouses for production of off-season vegetables. Large-scale production would be economical only for certain kinds of farming, under special conditions, perhaps on some of the coral islands of the Pacific.

Soil and Water Management

Farmers have become more expert in soil and water management in the past half century. The science of agronomy includes land management. The huge yields today are partly due to intelligent use of the land. Farmers use areas with the least fertile soil, poor drainage, steep slopes, or other disadvantages as pasture and woods rather than for crops. They work and plant their land in ways that hold the rainfall and prevent or check erosion. The farmers of a district may join in soil conservation projects with federal aid. (See also Conservation.)

Irrigation has long played an important part in the agriculture of many countries. Individual farmers and groups of farmers may get water for their fields from streams and wells. Others may get water from large government irrigation systems. These systems dam the snow-fed mountain rivers of the area and send their water through canals to the fields. About two thirds of the increase in irrigated acreage in the United States after 1949 was in the West. (See also Irrigation.)

Until recently farmers in moister areas relied entirely upon rainfall for moisture. Since World War II many farmers in such areas have turned to irrigation to compensate for periods of poor rainfall during the growing season. This has insured more dependable crops and high yields even in times of drought. More than 400 million acres (162 million hectares) were being irrigated worldwide in the 1970s.

Livestock Production

As the need for grain as human food grows, the practice of feeding it to cattle and other livestock is increasingly questioned. New sources of livestock feed seem likely to emerge. Some research has focused on and appears to be headed toward increasing the yield of animal products just on the food that can be provided by rangeland and permanent pastures. Large-scale fertilization of this kind of land could, therefore, become justified in the future.

Genetic improvement through controlled breeding of dairy cows, better nutrition, and improved management have resulted in unparalleled gains in milk production in the past 40 years. Improvement is expected to continue. Research on climate control and increasing the number of multiple births is expected to result in improved production of beef cattle and pigs. Efficiency of poultry production, already high, could reach even higher levels through techniques that now seem fantastic.

For example, the potential efficiency limit for a laying hen is one egg each day for a year from three pounds (1.4 kilograms) of feed per dozen eggs. The average hen, however, lays about 230 eggs per year from four pounds (1.8 kilograms) of feed per dozen eggs. Much energy goes into producing the shell around an egg. Research may result in hens' laying eggs without shells, thereby increasing the total number that are laid. The question then becomes one of packaging and acceptance by the public.

The limits in most livestock productivity are still not within sight. Much remains to be done, but supplements in feed to fatten animals and keep them healthy may have reached its limit. There is growing concern over the appearance of such additives in the human food derived from treated animals.

Agricultural Research

As competition for land increases and agricultural productivity peaks, agricultural research enters the area of bioengineering, through which plants can be redesigned by genetic manipulation. This offers the hope for crops that can take nitrogen out of the air, lessening the need for nitrogen fertilizer. Disease resistance increasingly will be built into crops. Plants will be able to grow on arid land or in salt marshes. Almost any desired genetic change is possible.

Agribusiness

In agriculturally progressive areas, such as Japan, the United States, Canada, and many parts of Europe, agriculture has become big business. The farmer is more and more a manager, running a business, which may be part of a huge corporation, based soundly on chemistry, biology, engineering, and economics. The goal is the same as for any businessman: to maximize profits. The agribusiness manager must be alert to government programs and regulations, must be aware of the newest varieties and growing techniques, and must be knowledgeable about pesticide hazards and hundreds of other details. Every segment of the operation is examined. The most select crop variety suited to soil conditions is chosen; special fertilizer is blended for maximum growth and yield. Chemical weed control is practiced. Irrigation may be used. Pesticides are applied at the best times. All of these have been done by farmers in the past, but now many of these activities are computerized.

Capital Outlay

The young person who selects farming as a career makes a large investment on entering it. Often there are years of expensive schooling. Then if the decision is to start one's own farm, there is the problem that the machines and equipment for scientific farming are expensive. The up-to-date farmer also must spend a great deal of money on such items as fertilizer, seed and livestock, special feeds, insect sprays, tractor fuel, and special buildings, such as milking parlors and poultry houses.

The price per acre of farm real estate (including land and buildings and other improvements) continues to rise. Net income, however, has changed little. A part of the rise in real estate has been caused by inflation. The demand for land for nonfarm uses also has boosted the average price.

Few farmers pay cash for their land. It may be months before money comes in from crops or animals. Like the city dweller buying a home, the average farmer must borrow. The farmer may also borrow to purchase seed, fertilizer, stock feed, and other supplies. The farm renter also needs money for the portion of machinery or livestock he or she must supply. Government and private agencies assist the farmers in securing this needed credit.

Records and Accounts

The modern farm family finds that it is necessary to keep numerous records. This task often falls to members of the farmer's family. The farmer needs data provided by the records for income tax returns and as a basis for making business decisions. Careful accounting is required to show whether the input—into a crop or into the farm as a whole—is warranted by the value of the output.

A dairy farmer may weigh and record the yield of every cow at each milking in order to find and then keep only the most productive animals. The poultry farmer may tally the number of eggs each hen lays and then cull the poor layers. The grain farmer must know the cost of seed, fertilizer, weed spray, labor, machinery depreciation, and other production items to calculate profit or loss on a crop.

After a careful study of investment, costs, and output, a farmer may make major changes in operations. The grain farmer, for example, may decide to rent more land to get greater use from machines. If yield is high and the price is low, the farmer may buy beef cattle to feed on the grain and hope to make a better profit on the beef. The farmer may decide to plant soybeans or another crop instead of grain the next year. A series of poor yearly results may reveal that the output of a small farm is not paying a fair wage for the labor. The farmer may then decide to take other work and run the farm only part-time.

Modern Marketing

Marketing has changed as much over the years as other aspects of farming. A century ago much of the farmer's output was sold and consumed at the nearest marketing town. The farmer might also deliver barrels of potatoes and apples directly to nearby homes. Grain was usually sold to a nearby mill, a steer or hog to the local slaughterhouse, and eggs and butter to a local store.

In some parts of the world farmers still carry their small surplus to a town market where they trade or sell it to their neighbors. In the United States, roadside vegetable stands and farmers' markets are the chief remnants of such direct trade between farmer and consumer. In general the modern farmer's output reaches the market through the hands of many businesses that buy, store, transport, process, package, and deliver it before it is sold to the consumer.

This system is necessary because people use few commodities in the form in which they come from the farm. People want cuts of meat or hamburger—not a steer; bread—not wheat; a dress or a coat—not cotton or wool. A farm's product may be used thousands of miles away, completely changed in form. More than a million commercial firms are engaged in agricultural marketing and processing. (See also Food Processing; Meat Industry.)

The people who handle farm produce en route to the consumer must be paid. In the United States, about 70 cents of every dollar people spend for farm commodities goes to the people who buy, handle, sell, package, and advertise it. This leaves about 30 cents for those who raise the produce.

To avoid dealing with commercial buyers and processors, farm groups often organize cooperatives for the processing and selling of their produce. The extra profits are shared among the cooperative members. Farm cooperatives may also buy such items as fertilizer, seed, and gasoline in large, money-saving quantities, then sell them to members, passing along the savings. (See also Cooperatives.)

Understanding the Market

To sell produce most advantageously, the farmer needs to understand the market for particular commodities. He or she must keep in touch with price trends to determine the most favorable time to sell. Various services in different countries issue reports on the production and prices of crops and livestock. They also forecast future output and furnish market news to newspapers and radio broadcasters. Boards of trade, or commodity exchanges, issue reports of prices for current sales and futures on grains, cotton, soybeans, and other commodities. The farmer can increase profits by producing commodities that meet high standards. The Agricultural Marketing Service in the United States has played an important role in setting standards and grades for agricultural products. The service also inspects many foods for wholesomeness.

Farming in Communist Countries

Communist governments have worked to increase the supply of food and fiber in their countries. They have set up large cooperative and state farms, which use the labor and land of former private owners. In many cases they have met resistance. Also, crop results often have not come up to the expectations of leaders. In the late 1980s the Soviet Union's output of grain per acre, for example, was one third less than that of Western Europe, where intensive farming was practiced. Seeking to improve production, the Soviet government made several changes. For instance, they ended the system whereby collective farms had to sell grain to the state at low prices.

Communist China set up a commune system. Under this system, peasant families gave up their property and were housed in dormitories. Then they worked in the fields or on state projects under government-appointed supervisors. China also experimented with Western methods. (See also China; Union of Soviet Socialist Republics.)

Cooperative International Research

Progress in cooperative research is slow. Billions of dollars have been offered in agricultural aid through the AID, funded by the United States. Billions are also channeled through the FAO.

Grants from private foundations and various nations help to fund regional and international agricultural research centers in the tropics and subtropics. The centers provide educational opportunities as well as research services. At least half of the board members of these centers are distinguished authorities from the nations served.

The World Food Conference, sponsored by the United Nations, was held in Rome in November 1974. Important resolutions dealing with the food crisis were passed, but progress remains unsteady.

United States Department of Agriculture

The activities of the United States Department of Agriculture are an outstanding example of how a government can aid and influence a nation's agriculture. Within the United States Department of Agriculture are numerous divisions, generally called bureaus, services, or administrations. Most divisions assist in problems with farm methods. Several divisions, however, have programs to aid the farmers financially. Each of the 50 states also has an agricultural department. Federal and state departments work in cooperation with each other and with local committees, farmers' organizations, and individual farm families. (For information on these bureaus, services, and administrations and their activities and responsibilities, see United States Government, “The Department of Agriculture.”)

Agricultural Education in the United States

In the United States young people may study agriculture in high school and in college. Under the Smith-Hughes Act of 1917, the federal government grants funds to high schools for teaching vocational agriculture. High school students usually learn by doing. Their courses are coordinated with farming programs supervised by their teachers. Students carry on long-term productive projects, such as raising livestock as a business venture. They grade, process, and market their produce. They also undertake improvement projects to increase the value and efficiency of the farm. Examples include building a poultry house or repairing farm machinery using skills learned in shop class. In addition they are taught supplementary farm practices. For example, they learn to keep records and figure profits and losses.

High school vocational agriculture departments also offer evening classes to young farmers and adult farmers. These classes help keep those who are already farming up-to-date on new agricultural information, methods, skills, and practices.

In each state at least one college or university offers professional agricultural training. These institutions resulted from the Morrill Act of 1862 in which Congress provided public land grants to state colleges that would teach agriculture and mechanical arts. Later legislation provided more federal aid.

The state experiment stations are connected with the agricultural colleges. They carry on research in laboratories and on experimental farms.

Farm Organizations

Farm boys and girls learn some farming methods and may develop as rural leaders through their young people's clubs. Students in vocational agriculture courses are eligible to join the Future Farmers of America and similar organizations. The 4-H Clubs, sponsored by the United States Department of Agriculture and state agricultural colleges, and the Juvenile Grange, sponsored by the National Grange, carry on extensive programs in farming and homemaking.

Adult farmers have independent dues-supported organizations for advancing their welfare—for example, to provide specialist speakers, or exchange ideas, and other educational functions. Three major groups in the United States are the National Grange, organized in 1867; the American Farm Bureau Federation, begun in 1919; and the Farmers' Educational and Cooperative Union of America, founded in 1902.