World War I was less than one year old when British writer H. G. Wells lamented the fate of humanity at the hands of "man's increasing power of destruction" (H. G. Wells, "Civilization at the Breaking Point," New York Times, May 27, 1915, 2). Although considered a father of science fiction, Wells was observing something all too real—technology had changed the face of combat in World War I and ultimately accounted for an unprecedented loss of human life.  Infantry warfare had depended upon hand-to-hand combat. World War I popularized the use of the machine gun—capable of bringing down row after row of soldiers from a distance on the battlefield. This weapon, along with barbed wire and mines, made movement across open land both difficult and dangerous. Thus trench warfare was born. The British introduced tanks in 1916; they were used with airplanes and artillery to advance the front. The advent of chemical warfare added to the soldier's perils. Sea and airborne weapons made killing from a distance more effective as well. Guns mounted on ships were able to strike targets up to twenty miles inland. The stealth and speed of German submarines gave Germany a considerable advantage in its dominance of the North Sea. Although airplanes were technologically crude, they offered a psychological advantage. Fighter pilot aces such as Manfred von Richthofen, Germany's "Red Baron," became celebrities and heroes, capturing the world's imagination with their daring and thrilling mid-air maneuvers. Newspapers charted the public's reaction—horror and vengeance—to these technological advancements. A few weeks after the Germans first used poison gas in Ypres, Belgium, on April 22, 1915, a London newswire to the New York Times described the brutal details of the attack and the immediate effects on the soldiers, concluding: "It is without doubt the most awful form of scientific torture." Yet a Daily Chronicle [London] editorial urged Britain to retaliate with poison gas use of its own (quoted in New York Times, May 7, 1915, 2). In fact, Germany claimed that the Allies were already using mines charged with poison gas. So horrified were people by chemical warfare that the use of poison gases was banned for future wars, although not until 1925. When Germany's plan for a swift military victory went unrealized, the pace of war bogged down. Both sides tried to break this stalemate through the use of force. In previous wars, victory was achieved through territorial supremacy; in World War I it was accomplished by simply outlasting the opponent—a "war of attrition." When fighting first broke out in August 1914, many hoped the war would be short-lived; few predicted a conflict that would last for more than four years and scar an entire generation with its unprecedented brutality. Below is an excerpt from the Declaration of Independence. Which popular Enlightenment idea is reflected in this writing? We hold these truths to be self-evident, that all men are created equal, that they are endowed by their Creator with certain unalienable Rights, that among these are Life, Liberty and the pursuit of Happiness. — That to secure these rights, Governments are instituted among Men, deriving their just powers from the consent of the governed, — That whenever any Form of Government becomes destructive of these ends, it is the Right of the People to alter or to abolish it, and to institute new Government, laying its foundation on such principles and organizing its powers in such form, as to them shall seem most likely to effect their Safety and Happiness.2 Sets with similar terms
It has been said that the Industrial Revolution was the most profound revolution in human history, because of its sweeping impact on people’s daily lives. The term “industrial revolution” is a succinct catchphrase to describe a historical period, starting in 18th-century Great Britain, where the pace of change appeared to speed up. This acceleration in the processes of technical innovation brought about an array of new tools and machines. It also involved more subtle practical improvements in various fields affecting labor, production, and resource use. The word “technology” (which derives from the Greek word techne, meaning art or craft) encompasses both of these dimensions of innovation. The technological revolution, and that sense of ever-quickening change, began much earlier than the 18th century and has continued all the way to the present day. Perhaps what was most unique about the Industrial Revolution was its merger of technology with industry. Key inventions and innovations served to shape virtually every existing sector of human activity along industrial lines, while also creating many new industries. The following are some key examples of the forces driving change. Agriculture Western European farming methods had been improving gradually over the centuries. Several factors came together in 18th-century Britain to bring about a substantial increase in agricultural productivity. These included new types of equipment, such as the seed drill developed by Jethro Tull around 1701. Progress was also made in crop rotation and land use, soil health, development of new crop varieties, and animal husbandry. The result was a sustained increase in yields, capable of feeding a rapidly growing population with improved nutrition. The combination of factors also brought about a shift toward large-scale commercial farming, a trend that continued into the 19th century and later. Poorer peasants had a harder time making ends meet through traditional subsistence farming. The enclosure movement, which converted common-use pasture land into private property, contributed to this trend toward market-oriented agriculture. A great many rural workers and families were forced by circumstance to migrate to the cities to become industrial laborers. Energy Deforestation in England had led to a shortage of wood for lumber and fuel starting in the 16th century. The country’s transition to coal as a principal energy source was more or less complete by the end of the 17th century. The mining and distribution of coal set in motion some of the dynamics that led to Britain’s industrialization. The coal-fired steam engine was in many respects the decisive technology of the Industrial Revolution. Steam power was first applied to pump water out of coal mines. For centuries, windmills had been employed in the Netherlands for the roughly similar operation of draining low-lying flood plains. Wind was, and is, a readily available and renewable energy source, but its irregularity was considered a drawback. Water power was a more popular energy source for grinding grain and other types of mill work in most of preindustrial Europe. By the last quarter of the 18th century, however, thanks to the work of the Scottish engineer James Watt and his business partner Matthew Boulton, steam engines achieved a high level of efficiency and versatility in their design. They swiftly became the standard power supply for British, and, later, European industry. The steam engine turned the wheels of mechanized factory production. Its emergence freed manufacturers from the need to locate their factories on or near sources of water power. Large enterprises began to concentrate in rapidly growing industrial cities. Metallurgy In this time-honored craft, Britain’s wood shortage necessitated a switch from wood charcoal to coke, a coal product, in the smelting process. The substitute fuel eventually proved highly beneficial for iron production. Experimentation led to some other advances in metallurgical methods during the 18th century. For example, a certain type of furnace that separated the coal and kept it from contaminating the metal, and a process of “puddling” or stirring the molten iron, both made it possible to produce larger amounts of wrought iron. Wrought iron is more malleable than cast iron and therefore more suitable for fabricating machinery and other heavy industrial applications. Textiles The production of fabrics, especially cotton, was fundamental to Britain’s economic development between 1750 and 1850. Those are the years historians commonly use to bracket the Industrial Revolution. In this period, the organization of cotton production shifted from a small-scale cottage industry, in which rural families performed spinning and weaving tasks in their homes, to a large, mechanized, factory-based industry. The boom in productivity began with a few technical devices, including the spinning jenny, spinning mule, and power loom. First human, then water, and finally steam power were applied to operate power looms, carding machines, and other specialized equipment. Another well-known innovation was the cotton gin, invented in the United States in 1793. This device spurred an increase in cotton cultivation and export from U.S. slave states, a key British supplier. Chemicals This industry arose partly in response to the demand for improved bleaching solutions for cotton and other manufactured textiles. Other chemical research was motivated by the quest for artificial dyes, explosives, solvents, fertilizers, and medicines, including pharmaceuticals. In the second half of the 19th century, Germany became the world’s leader in industrial chemistry. Transportation Concurrent with the increased output of agricultural produce and manufactured goods arose the need for more efficient means of delivering these products to market. The first efforts toward this end in Europe involved constructing improved overland roads. Canals were dug in both Europe and North America to create maritime corridors between existing waterways. Steam engines were recognized as useful in locomotion, resulting in the emergence of the steamboat in the early 19th century. High-pressure steam engines also powered railroad locomotives, which operated in Britain after 1825. Railways spread rapidly across Europe and North America, extending to Asia in the latter half of the 19th century. Railroads became one of the world’s leading industries as they expanded the frontiers of industrial society. |
How did advances in military technology after the industrial revolution affect European empires apex?
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