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What Do Steam, Science, and Digital Technology Have in Common?These are the first three industrial revolutions that transformed our modern society. With each of these three advancements—the steam engine, the age of science and mass production, and the rise of digital technology—the world around us fundamentally changed. And right now, it’s happening again, for a fourth time. And so here we are, all of us together, poised at the beginning of the Fourth Industrial Revolution. But this time, the revolution is powered by cloud, social, mobile, the Internet of things (IoT) and artificial intelligence (AI), along with increasing computing power and data. There’s a lot to unpack here. And that’s why we created this trail: to help you make sense of where we’ve been and where we’re headed next, and what it all means for you. Before we get to the details on the Fourth Industrial Revolution, let’s review some basics. We start by defining the term industrial revolution. Wait, I thought the Industrial Revolution Only Happened That One Time?So, perhaps you remember learning about the Industrial Revolution in history class, and talking about how steam engines and factories changed the landscape of European and American economics and society. But didn’t that only happen once? In his book The Fourth Industrial Revolution, Klaus Schwab, the founder and executive chairman of the World Economic Forum, the International Organization for Public-Private Cooperation, asserts that there are actually four distinct periods of industrial revolution throughout history, including the one we’re beginning right now. Schwab describes an industrial revolution as the appearance of “new technologies and novel ways of perceiving the world [that] trigger a profound change in economic and social structures.” So the first one—the one with steam power—that was the first industrial revolution. It was followed by the age of science and mass production, and then the digital revolution. We’re now at the beginning of the next phase of dramatic technological expansion and social change—the Fourth Industrial Revolution. Rest assured, we cover each of these in more detail next. The First Industrial Revolution: The Age of Mechanical ProductionAs it turns out, when you heat up water, you get steam. And beginning around 1760, through the advent of the steam engine, steam was powering everything from agriculture to textile manufacturing. Society used to be largely agrarian, which is a fancy way of saying that life used to be centered around farming. But with steam power, those agrarian societies gave way to urbanization. The world began to rely on steam power and machine tools, while steamships and railroads revolutionized how people got from A to B. And what emerged as the new center of community life? The factory.
 But factory life was difficult. Unskilled factory laborers were cheap and plentiful. They were made to work long hours, often in unsafe conditions. Even children worked in factories, putting in 14-hour shifts alongside adults. Such conditions endured into the 20th century. Ultimately, advancing industrialization created a middle class of skilled workers. Cities and industries grew more quickly than ever before, and economies grew along with them. The Second Industrial Revolution: The Age of Science and Mass ProductionThings started to speed up with a number of key inventions. Think gasoline engines, airplanes, chemical fertilizer. All inventions that helped us go faster and do more. That’s science, folks. It works. But advancements in science weren’t limited to the laboratory. Scientific principles were brought right into the factories. Most notably, the assembly line, which effectively powered mass production. By the early part of the 20th century, Henry Ford’s company was mass producing the groundbreaking Ford Model T, a car with a gasoline engine built on an assembly line in his factories.
People follow the jobs, and the early 1900s saw workers leaving their rural homes behind to move to urban areas and factory jobs. By 1900, 40% of the US population lived in cities, compared to just 6% in 1800. Along with increasing urbanization, inventions such as electric lighting, radio, and telephones transformed the way people lived and communicated. When you stop and think about it, it was this industrial revolution, the second one, that ushered in the modern world. The Third Industrial Revolution: The Digital RevolutionSo, if you’re reading this, you’re experiencing some of the wonders of the digital revolution right now. You’re enjoying the cloud, the Internet, and some kind of handy device that lets you access both. You can even be reading this on your phone. Hello there. Welcome to the digital revolution. Beginning in the 1950s, the third industrial revolution brought semiconductors, mainframe computing, personal computing, and the Internet—the digital revolution. Things that used to be analog moved to digital technologies, like an old television you used to tune in with an antenna (analog) being replaced by an Internet-connected tablet that lets you stream movies (digital). The move from analog electronic and mechanical devices to pervasive digital technology dramatically disrupted industries, especially global communications and energy. Electronics and information technology began to automate production and take supply chains global.
The Fourth Industrial Revolution: Starting Now!Each of these first three industrial revolutions represented profound change. We’re talking major societal transformation. Life went from being all about the farm to all about the factory, and people moved from the country into town with the introduction of mechanical production. How people lived and worked fundamentally changed with the discovery of electricity and mass production. And most recently, the digital revolution altered nearly every industry, once again transforming how people live, work, and communicate. So where are we now? Well, at this moment, many of the technologies people dreamed of in the 1950s and 60s have become a reality. Maybe we don’t have flying cars yet, but we’ve got robots! Plus there’s genetic sequencing and editing, artificial intelligence, miniaturized sensors, and 3D printing, to name a few. And when you put some of these technologies together, well, let’s just say the innovations are unexpected and surprising. This is the beginning of the next great industrial revolution: The Fourth Industrial Revolution. We head there next. Resources
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Scientific Revolution is the name given to a period of drastic change in scientific thought that took place during the 16th and 17th centuries. It replaced the Greek view of nature that had dominated science for almost 2,000 years. The Scientific Revolution was characterized by an emphasis on abstract reasoning, quantitative thought, an understanding of how nature works, the view of nature as a machine, and the development of an experimental scientific method. The sudden emergence of new information during the Scientific Revolution called into question religious beliefs, moral principles, and the traditional scheme of nature. It also strained old institutions and practices, necessitating new ways of communicating and disseminating information. Prominent innovations included scientific societies (which were created to discuss and validate new discoveries) and scientific papers (which were developed as tools to communicate new information comprehensibly and test the discoveries and hypotheses made by their authors). Scientific Revolution, drastic change in scientific thought that took place during the 16th and 17th centuries. A new view of nature emerged during the Scientific Revolution, replacing the Greek view that had dominated science for almost 2,000 years. Science became an autonomous discipline, distinct from both philosophy and technology, and it came to be regarded as having utilitarian goals. By the end of this period, it may not be too much to say that science had replaced Christianity as the focal point of European civilization. Out of the ferment of the Renaissance and Reformation there arose a new view of science, bringing about the following transformations: the reeducation of common sense in favour of abstract reasoning; the substitution of a quantitative for a qualitative view of nature; the view of nature as a machine rather than as an organism; the development of an experimental, scientific method that sought definite answers to certain limited questions couched in the framework of specific theories; and the acceptance of new criteria for explanation, stressing the “how” rather than the “why” that had characterized the Aristotelian search for final causes. The growing flood of information that resulted from the Scientific Revolution put heavy strains upon old institutions and practices. It was no longer sufficient to publish scientific results in an expensive book that few could buy; information had to be spread widely and rapidly. Natural philosophers had to be sure of their data, and to that end they required independent and critical confirmation of their discoveries. New means were created to accomplish these ends. Scientific societies sprang up, beginning in Italy in the early years of the 17th century and culminating in the two great national scientific societies that mark the zenith of the Scientific Revolution: the Royal Society of London for Improving Natural Knowledge, created by royal charter in 1662, and the Académie des Sciences of Paris, formed in 1666. In these societies and others like them all over the world, natural philosophers could gather to examine, discuss, and criticize new discoveries and old theories. To provide a firm basis for these discussions, societies began to publish scientific papers. The old practice of hiding new discoveries in private jargon, obscure language, or even anagrams gradually gave way to the ideal of universal comprehensibility. New canons of reporting were devised so that experiments and discoveries could be reproduced by others. This required new precision in language and a willingness to share experimental or observational methods. The failure of others to reproduce results cast serious doubts upon the original reports. Thus were created the tools for a massive assault on nature’s secrets.
History: Fact or Fiction? Get hooked on history as this quiz sorts out the past. Find out who really invented movable type, who Winston Churchill called "Mum," and when the first sonic boom was heard. The Scientific Revolution began in astronomy. Although there had been earlier discussions of the possibility of Earth’s motion, the Polish astronomer Nicolaus Copernicus was the first to propound a comprehensive heliocentric theory equal in scope and predictive capability to Ptolemy’s geocentric system. Motivated by the desire to satisfy Plato’s dictum, Copernicus was led to overthrow traditional astronomy because of its alleged violation of the principle of uniform circular motion and its lack of unity and harmony as a system of the world. Relying on virtually the same data as Ptolemy had possessed, Copernicus turned the world inside out, putting the Sun at the centre and setting Earth into motion around it. Copernicus’s theory, published in 1543, possessed a qualitative simplicity that Ptolemaic astronomy appeared to lack. To achieve comparable levels of quantitative precision, however, the new system became just as complex as the old. Perhaps the most revolutionary aspect of Copernican astronomy lay in Copernicus’s attitude toward the reality of his theory. In contrast to Platonic instrumentalism, Copernicus asserted that to be satisfactory astronomy must describe the real, physical system of the world. The reception of Copernican astronomy amounted to victory by infiltration. By the time large-scale opposition to the theory had developed in the church and elsewhere, most of the best professional astronomers had found some aspect or other of the new system indispensable. Copernicus’s book De revolutionibus orbium coelestium libri VI (“Six Books Concerning the Revolutions of the Heavenly Orbs”), published in 1543, became a standard reference for advanced problems in astronomical research, particularly for its mathematical techniques. Thus, it was widely read by mathematical astronomers, in spite of its central cosmological hypothesis, which was widely ignored. In 1551 the German astronomer Erasmus Reinhold published the Tabulae prutenicae (“Prutenic Tables”), computed by Copernican methods. The tables were more accurate and more up-to-date than their 13th-century predecessor and became indispensable to both astronomers and astrologers. Get a Britannica Premium subscription and gain access to exclusive content. Subscribe Now During the 16th century the Danish astronomer Tycho Brahe, rejecting both the Ptolemaic and Copernican systems, was responsible for major changes in observation, unwittingly providing the data that ultimately decided the argument in favour of the new astronomy. Using larger, stabler, and better calibrated instruments, he observed regularly over extended periods, thereby obtaining a continuity of observations that were accurate for planets to within about one minute of arc—several times better than any previous observation. Several of Tycho’s observations contradicted Aristotle’s system: a nova that appeared in 1572 exhibited no parallax (meaning that it lay at a very great distance) and was thus not of the sublunary sphere and therefore contrary to the Aristotelian assertion of the immutability of the heavens; similarly, a succession of comets appeared to be moving freely through a region that was supposed to be filled with solid, crystalline spheres. Tycho devised his own world system—a modification of Heracleides’—to avoid various undesirable implications of the Ptolemaic and Copernican systems. Johannes KeplerErich Lessing/Art Resource, New York At the beginning of the 17th century, the German astronomer Johannes Kepler placed the Copernican hypothesis on firm astronomical footing. Converted to the new astronomy as a student and deeply motivated by a neo-Pythagorean desire for finding the mathematical principles of order and harmony according to which God had constructed the world, Kepler spent his life looking for simple mathematical relationships that described planetary motions. His painstaking search for the real order of the universe forced him finally to abandon the Platonic ideal of uniform circular motion in his search for a physical basis for the motions of the heavens. In 1609 Kepler announced two new planetary laws derived from Tycho’s data: (1) the planets travel around the Sun in elliptical orbits, one focus of the ellipse being occupied by the Sun; and (2) a planet moves in its orbit in such a manner that a line drawn from the planet to the Sun always sweeps out equal areas in equal times. With these two laws, Kepler abandoned uniform circular motion of the planets on their spheres, thus raising the fundamental physical question of what holds the planets in their orbits. He attempted to provide a physical basis for the planetary motions by means of a force analogous to the magnetic force, the qualitative properties of which had been recently described in England by William Gilbert in his influential treatise, De Magnete, Magneticisque Corporibus et de Magno Magnete Tellure (1600; “On the Magnet, Magnetic Bodies, and the Great Magnet of the Earth”). The impending marriage of astronomy and physics had been announced. In 1618 Kepler stated his third law, which was one of many laws concerned with the harmonies of the planetary motions: (3) the square of the period in which a planet orbits the Sun is proportional to the cube of its mean distance from the Sun.
As revealed by DNA analysis, the closest living relative to the whale is the hippopotamus. See All Good FactsA powerful blow was dealt to traditional cosmology by Galileo Galilei, who early in the 17th century used the telescope, a recent invention of Dutch lens grinders, to look toward the heavens. In 1610 Galileo announced observations that contradicted many traditional cosmological assumptions. He observed that the Moon is not a smooth, polished surface, as Aristotle had claimed, but that it is jagged and mountainous. Earthshine on the Moon revealed that Earth, like the other planets, shines by reflected light. Like Earth, Jupiter was observed to have satellites; hence, Earth had been demoted from its unique position. The phases of Venus proved that that planet orbits the Sun, not Earth. |
Which statement best describes the relationship between the Industrial Revolution and Scientific Revolution?
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