Mechanical engineering ingenuity found solutions for even more problematic crops—the worst of which was probably cotton. In the long history of cotton's cultivation, no one had come up with a better way to harvest this scraggly tenacious plant than the labor-intensive process of plucking it by hand. The cotton gin, invented in 1794 by Eli Whitney, mechanized the post-harvest process of extracting the cotton fibers from the seedpod, or boll, but no really successful efforts at mechanizing the picking of cotton occurred until the 1930s. In that decade, brothers John and Mack Rust of Texas demonstrated several different versions of a spindle picker, a device consisting of moistened rotating spindles that grabbed the cotton fibers from open bolls, leaving the rest of the plant intact; the fibers were then blown into hoppers. Spindle pickers produced cotton that was as clean as or cleaner than handpicked cotton; soon they replaced earlier stripper pickers, which stripped opened and unopened bolls alike, leaving a lot of trash in with the fibers. The Rust brothers' designs had one shortcoming: They couldn't be mass produced on an assembly line. Thus credit goes to International Harvester for developing the first commercially viable spindle picker in 1943, known affectionately as Old Red.

Mechanization has come to the aid of another critical aspect of agriculture—namely, soil conservation. An approach known as conservation tillage has greatly reduced, or even eliminated, traditional plowing, which can cause soil erosion and loss of nutrients and precious moisture. Conservation tillage includes the use of sweep plows, which undercut wheat stubble but leave it in place above ground to help restrict soil erosion by wind and to conserve moisture. The till plant system is another conservation-oriented approach. Corn stalks are left in place to reduce erosion and loss of moisture, and at planting time the next year the row is opened up, the seeds are planted, and the stalks are turned over beside the row, to be covered up by cultivation. This helps conserve farmland by feeding nutrients back into the soil.

• Mechanization has come to the aid of another critical aspect of agriculture—namely, soil conservation. An approach known as conservation tillage has greatly reduced, or even eliminated, traditional plowing, which can cause soil erosion and loss of nutrients and precious moisture. Conservation tillage includes the use of sweep plows, which undercut wheat stubble but leave it in place above ground to help restrict soil erosion by wind and to conserve moisture. The till plant system is another conservation-oriented approach. Corn stalks are left in place to reduce erosion and loss of moisture, and at planting time the next year the row is opened up, the seeds are planted, and the stalks are turned over beside the row, to be covered up by cultivation. This helps conserve farmland by feeding nutrients back into the soil.

• As the century unfolded, everything about farming was changing—not the least its fundamental demographics. In 1900 farmers made up 38 percent of the U.S. labor force; by the end of the century they represented less than 3 percent. With machines doing most of the work, millions of farmers and farm laborers had to look elsewhere for a living—a displacement that helped fuel booms in the manufacturing and service industries, especially after World War II. It also fueled a dramatic shift in the entire culture, as metropolitan and suburban America began to replace the rural way of life. Although some may lament the passing of the agrarian way of life, in much of the developing world these transformations represent hope. The many ways in which agriculture has been changed by engineering—from new methods for land and resource management to more efficient planting and harvesting to the development of better crop varieties—offer the potential solution to the endemic problems of food shortage and economic stagnation.

In 1900 farmers represented 38 percent of the U.S. labor force. By the end of the century that number had plunged to 3 percent—dramatic evidence of the revolution in agriculture brought about by mechanization. Beginning with the internal combustion engine and moving on to rubber tires that kept machinery from sinking in muddy soil, mechanization also improved the farm implements designed for planting, harvesting, and reaping. The advent of the combine, for example, introduced an economically efficient way to harvest and separate grain. As the century closed, "precision agriculture" became the practice, combining the farmer's down-to-earth know-how with space-based technology.

• In 1900 farmers represented 38 percent of the U.S. labor force. By the end of the century that number had plunged to 3 percent—dramatic evidence of the revolution in agriculture brought about by mechanization. Beginning with the internal combustion engine and moving on to rubber tires that kept machinery from sinking in muddy soil, mechanization also improved the farm implements designed for planting, harvesting, and reaping. The advent of the combine, for example, introduced an economically efficient way to harvest and separate grain. As the century closed, "precision agriculture" became the practice, combining the farmer's down-to-earth know-how with space-based technology.

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