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The sweeping true story of how the steam engine changed the world, from the acclaimed author of Miracle Cure

If all measures of human advancement in the last hundred centuries were plotted on a graph, they would show an almost perfectly flat line—until the eighteenth century, when the Industrial Revolution would cause the line to shoot straight up, beginning an almost uninterrupted march of progress.
   
In The Most Powerful Idea in the World, William Rosen tells the story of the men responsible for the Industrial Revolution and the machine that drove it—the steam engine. In the process he tackles the question that has obsessed historians ever since: What made eighteenth-century Britain such fertile soil for inventors? Rosen’s answer focuses on a simple notion that had become enshrined in British law the century before: that people had the right to own and profit from their ideas.
   
The result was a period of frantic innovation revolving particularly around the promise of steam power. Rosen traces the steam engine’s history from its early days as a clumsy but sturdy machine, to its coming-of-age driving the wheels of mills and factories, to its maturity as a transporter for people and freight by rail and by sea. Along the way we enter the minds of such inventors as Thomas Newcomen and James Watt, scientists including Robert Boyle and Joseph Black, and philosophers John Locke and Adam Smith—all of whose insights, tenacity, and ideas transformed first a nation and then the world.
 
William Rosen is a masterly storyteller with a keen eye for the “aha!” moments of invention and a gift for clear and entertaining explanations of science. The Most Powerful Idea in the World will appeal to readers fascinated with history, science, and the hows and whys of innovation itself.

ASIN ‏ : ‎ B0036S49WS
Publisher ‏ : ‎ Random House (May 27, 2010)
Publication date ‏ : ‎ May 27, 2010
Language ‏ : ‎ English
File size ‏ : ‎ 2960 KB
Text-to-Speech ‏ : ‎ Enabled
Screen Reader ‏ : ‎ Supported
Enhanced typesetting ‏ : ‎ Enabled
X-Ray ‏ : ‎ Not Enabled
Word Wise ‏ : ‎ Enabled
Print length ‏ : ‎ 448 pages
Reviewer: EDWARD W HILL
Rating: 5.0 out of 5 stars
Title: Read this book! It makes sense of an era that even today frames the context of our lives.
Review: Ties the threads of technology,science,politics,law & history together in a well written & structured way.It must have been difficult for the author not to digress into any of the many fascinating sub-stories.(How were boiler's soldered, how were technical papers distributed, how did the banking-credit system work.....)There's enough detail to engage each type of reader (I now know why steam locomotives chuff) while not breaking the narrative thread.I'm reading this book a second time after reading the bibliography & realizing what this E-book (& other E-media like it) needs (thru no fault of the author). It needs a LinkR so I can digress as I read into sub-stories (supporting content) that interest me but that if were included in the book would burden it's utility.A LinkR app would work differently for different users:1. It would post process the book & it's biblio, perhaps tweaked for my interests & insert links in the text.2. For authors, perhaps a Word plug-in that would permit them to efficiently fine, sort & link relevant content, perhaps tagged for user classes..3. Commercially a LinkR has value (cookies have crumbs...Google) to both sellers of content & to authors(think of a LinkR as your personal app-bot that parses your E-content for your interests)& Here I digress: Thank-you Mr. Rosen a thoroughly enjoyable book.

Reviewer: Ian Baines
Rating: 4.0 out of 5 stars
Title: For those who love the history of steam
Review: A densely written book with many detours from the original story of steam technology, most of which are relevant. Considerable economic theory and constant reference to the politics of the day and the great thinkers of that time. Makes a compelling argument for the patent system. If you can follow all the twists and turns as well as re-reading segments to understand the logic, you will arrive at a more fulsome understanding of the Industrial Revolution. Steam technology underpins this book, but it is actually about the system and people that produced it. A bit of work, but worth the read. This is a Big Picture story

Reviewer: T. Graczewski
Rating: 5.0 out of 5 stars
Title: Adding the fuel of interest to the fire of genius
Review: I’ve written several hundred non-fiction book reviews here on Amazon over the years and this is the first one that comes with a spoiler alert. William Rosen has written a fabulously thorough and consistently entertaining history of the steam engine in “The Most Powerful Idea in the World: A Story of Steam, Industry, and Invention” (2012). But it has a surprising twist ending. On literally the last page of the book Rosen reveals that the steam engine isn’t the most powerful idea in the world, it’s the patent system that protected and rewarded the eighteenth and nineteenth century inventors that built it.Some have argued that the Industrial Revolution was all about cotton. Rosen argues that it was steam power that made the phenomenal growth of the British cotton textile industry possible. “Cotton traveled to the British Isles on steamships,” he writes, “was spun into cloth by steam-powered mills, and was brought to market by steam locomotives.” But Rosen doesn’t stop there. If cotton made the Industrial Revolution possible, and steam made the cotton textile industry possible, what made steam power possible? According to the author, the answer is the patent system.The Republic Venice instituted a patent system as early as 1474. However, according to the author, it was the British who developed intellectual property rights into their modern form. The foundation of British patent law – “the lawsuit that marks the ideological transformation that would [eventually] create the Industrial Revolution,” Rosen says – is the Case of Monopolies (officially Darcy vs Allein). Argued by the celebrated lawyer Sir Edward Coke in 1602, this landmark case established that the grant of exclusive rights to produce a certain product was improper and therefore illegal. The case arose out of Darcy’s monopoly over the import and trade of playing cards granted to him by Queen Elizabeth. The judgment found that state-established monopolies are inherently harmful and therefore contrary to law. This decision was followed two decades later by the Statute of Monopolies (1624), which determined that patents (i.e. time restricted, state-established monopolies) could only be awarded to “the first and true inventor” of a technology or process. The patent had to be both novel and useful, not related to the improvement of an existing technology or manufacturing process, and unlikely to be “mischievous to the state” (i.e. raise commodity prices or hurt trade). Those that met all of these criteria would be granted a patent for the term of fourteen years, which amounted to two standard seven-year artisan apprenticeship cycles. (Later, in 1700, the British would pass the Calico Acts, which prohibited the import and ownership of Indian printed cottons, a key part of London’s industrial policy that led to the Industrial Revolution.)For most of the seventeenth century, less than ten patents were issued a year. But something else important was happening in Great Britain at this time, Rosen says, echoing the argument made famous by Northwestern University economic history professor Joel Mokyr: “a culture of observation, experimentation, and innovation was being cultivated in England at exactly the same moment that Coke was advocating for her artisans.” The final piece of the puzzle, according to Rosen, was the articulation of intellectual property rights by John Locke. “The recognition of a property right in ideas,” he writes, “was the critical ingredient in democratizing the act of invention.” The allocation of patents grew slowly in Great Britain during the eighteenth century, from just five a year from 1700 to 1740, to almost twenty a year from 1740 to 1780, before exploding to over fifty a year from 1780 to 1800. By comparison, between the years 1793 to 1800 Britain granted 533 patents to Revolutionary France’s 65.If intellectual property rights and the patent system are “the most powerful idea in the world,” how did those ideas translate into the steam power-driven Industrial Revolution? Rosen says it was a relatively slow and often anonymous process. He claims that the Industrial Revolution was not a function of impersonal forces, but neither was it “the work of a dozen brilliant geniuses.” It was not driven by strikingly original creations (i.e. invention) but rather by an innumerable string of small improvements made over decades by anonymous tinkerers (i.e. innovation). “Sustained innovation is incremental innovation,” he writes, “and those increments are usually very small,” such as Henry Maudlslay’s leadscrew, Matthew Murray’s D-valve, Richard Trevithick’s fusible plug, and thousands of other now forgotten micro-improvements that collectively added up to significant change.Rosen writes that there are general phases of steam power. The first phase used condensed steam to convert atmospheric pressure into reciprocating motion. The basic mechanics of a steam engine are simple: turning water into steam creates pressure (because water in its vapor form takes up 1,800 times more space than it does as a liquid), converting it back into a liquid creates a powerful vacuum. This simple equation, known since antiquity, held the secret of almost unimaginable power. The foundational principles at play were the vacuum and adiabatic pressure (the phenomenon that causes a gas to cool when it expands and heat when it is compressed). In 1698, Thomas Savery (1650-1715) patented a steam-powered water pump, the first commercially available steam-powered device. A decade later, in 1712, Thomas Newcomen (1664-1729) introduced a piston to Savery’s basic design, which greatly increased its efficiency and versatility. Rosen equates the Newcomen steam engine to the AK-47 for its legendary simplicity and ruggedness. Because of Savery’s patent, however, Newcomen could only take, after much negotiation, one-quarter of the sales from his revolutionary device. Within three years of developing his prototype, Newcomen had over one hundred of his steam engines pumping water out of mines all over Great Britain. However, because of its fuel inefficiency, that’s all the Newcomen steam engine could do. It was so big and so fuel inefficient that it was only cost effective if it could operate at the literal source of its fuel.The second phase of steam power came in the late eighteenth century by converting the expansive power of steam into rotary motion able to drive dozens, and then hundreds, of spinning and weaving machines. The transition to this phase was driven by James Watt (1736-1819), a man who, according to the author, combined “the hands of a master craftsman and a brain schooled in mathematical reasoning.” He recognized early on that fuel efficiency was the Newcomen engine’s achilles heel. He began to meticulously test the performance of a variety of changes as to how the steam was converted to power. By 1765 he had developed the separate condenser, a relatively modest innovation that would essentially change the world. With one chamber that stayed hot and another that stayed cool, Watt introduced a dramatic improvement in fuel efficiency. In January 1769, Watt was issued patent number 913 for “a method of lessening the consumption of steam and fuel in fire-engines.” Watt’s separate condenser alone increased the fuel efficiency of a Newcomen steam engine by one hundred percent while also increasing the power of the engine. In the process, Watt introduced a new unit of measurement to compare his steam engine with a separate condenser against the traditional Newcomen model: horsepower. The Newcomen engine averaged at most ten horsepower; the Watt engine upwards of fifty. Because of Watt’s innovations the steam engine was both more capable of power generation and fuel efficient enough to liberate it from the close tether of direct access to coal mine fuel supplies. Suddenly steam engines could go into factories.“The Fire-Engines Act of 1775” was, according to at least one historian, “the most important single event in the Industrial Revolution.” It extended Watt’s 1769 patent on his steam engine with a separate condenser for twenty-five additional years. In 1774, John “Iron Mad” Wilkinson received patent number 1063 for his high precision boring system that enabled the manufacture of large, airtight cylinders capable of generating powerful and efficient engines. “If the most important invention of the Industrial Revolution was invention itself,” Rosen writes, “then automation of precision has to be one of the top three,” with Wilkinson’s boring device being perhaps the most important example. In 1786, Albion Mills, the largest and most efficient flour mill in the world, opened in London. It featured three large (34 inch cylinder) steam engines and thirty grinding wheels (the previous largest flour mill in London had four) and produced six thousand bushels of flour every week. “Behind the Albion Mills engine were hundreds of large and small innovations that had solved a dozen ancient problems in physics, metallurgy, and kinetics,” Rosen writes. It was in operation for just four years before burning down under mysterious circumstances.Steam engines were big business, but textiles would prove to be “the most valuable export industry in human history,” according to Rosen. The Industrial Revolution overturned “five centuries of traditional expertise controlled by militant and well-organized artisans.” Like steam engines, textile manufacturing developed over the course of the eighteenth century mainly because of patents. The leading inventors included John Lombe (silk throwing machine in 1718), John Kay (flying shuttle in 1733), James Hargreaves (spinning jenny in 1770), and Richard Arkwright (water frame in 1774). All of these inventions ultimately became public property, attracting competing and superior inventions. (Perhaps the most important innovation of all, Samuel Crompton’s spinning mule in 1779, which combined the work of Hargreaves and Arkwright, was never patented). In 1813, there were 2,400 steam driven power looms in England. Twenty years later there were 85,000. A century and a half after the Calico Acts, the productivity of the British cotton industry had grown by a factor of fourteen. “A great artisan can make a family prosperous,” Rosen writes, “a great inventor can enrich an entire nation.”The final stage was converting steam power into motion. It is best exemplified by the Rocket, the world’s first locomotive, introduced in 1829. In order for a steam engine to produce enough power to move itself, along with weighty cargo and passengers, it needed to be both powerful and lightweight. The only way to achieve that was to dramatically increase the pressure in the cylinder. American inventor Oliver Evans (1755-1819), who Rosen calls “a visionary and a pioneer,” made a significant contribution to the steam revolution in 1804 by placing his furnace inside a water-filled chamber, which significantly increased the heat transfer to the water. Doubling the heat of the water increases the potential power by one hundred times. Next, Richard Trevithick (1771-1833), the one man (along with Robert Stephenson) with a credible claim to the title of “father of railways,” developed a high pressure steam engine known as a “Cornish engine.” The thermal efficiency of the Cornish engine was astounding for its time, converting thirty percent of heat energy into work (steam turbines would eventually convert up to eighty percent). Using the standard benchmark of “duty” (the pounds of water raised one foot by a bushel of coal), Trevithick’s high pressure Cornish engine dominated the competition. A Newcomen-style engine possessed a duty of 5,000 pounds. A separate condenser Watt engine boasted a duty of almost 19,000 pounds. Trevithick’s engine could achieve 30,000 pounds by 1814 and 100,000 pounds by 1835. In 1829, the Manchester & Liverpool Railway offered a 500 pound prize for a locomotive that met several demanding requirements: the locomotive had to weigh less than six tons (including water), it had to operate at 45 to 60 psi, had to consume its own smoke, and pull a gross load of twenty tons at ten miles per hour for sixty miles. Only three applicants were serious contenders. The Rocket won in convincing fashion.Rosen notes that all of this was possible not only because the British patent system incentivized and protected would-be inventors, but also because the British slowly learned over time how to invent. No man was more important in teaching British artisans how to experiment productively and innovate successfully than John Smeaton (1724-1792), who was “by consensus the most brilliant engineer of his era – a bit like being the most talented painter in sixteenth century Florence.” Smeaton emphasized the importance of precise measurements and detailed records in experimentation. His work significantly advanced various fields, especially civil engineering and scientific methodology. “He bequeathed to his nation a process by which inventions could be experimentally tested,” Rosen says.In addition to improvements in the process of invention, Britain also took the relatively unusual and highly important step of lionizing her native inventive geniuses, men like Watt, Arkwright, and Trevithick, one time artisans who made fortunes by acquiring useful knowledge. Rosen contrasts this attitude with that of the French, who abolished the Academy of Sciences during the early years of the French Revolution, claiming, “The Republic does not need savants!”In closing, “There is no doubt that the thermodynamic gradient between liquid water and steam changed the world,” Rosen concludes, “and that its discovery marks one of the most important turning points in history.” Those are some pretty strong words, but I think Rosen successfully argued his case. From 1700 to 2000, the global population grew by a factor of twelve, but the production of goods and services expanded by one hundredfold. The patent-protected creative developments of the Industrial Revolution did much to spur and sustain this growth. No one benefited more than the Anglosphere (i.e. Great Britain and its majority caucasian former colonies). The Anglosphere created the Industrial Revolution and the Anglosphere profited most from it. The Anglosphere’s share of global GDP grew from perhaps three percent in 1700 to 28 percent in 2000 (down from an all-time high of 37 percent after World War II). At the foundation of this incredible success, according to the author, is the patent system and the notion of intellectual property rights. In the immortal words of Abraham Lincoln, the only US president to hold a patent, the patent system “added the fuel of interest to the fire of genius."

Reviewer: Philip Lyon
Rating: 5.0 out of 5 stars
Title: Highly reccomended if humorously irreverant to those who need it; generally not the people in the book
Review: Howdy all,This is some excellent history with a personal approach to explaining how the-"Rocket", the first successful RR locomotive came to be, by starting with Hero's crude steam turbine, NTM asking questions about how inventors invent, including the whole process and culture of invention was created in England, and answering using current research on the brain, besides the culture and development of the idea as property by Thomas Coke and John Locke among other threads of development ("each little improvement") the author seeks to answer.Other questions such as if more people gets you more inventors as some attempting to explain the industrial revolution claim, why England and not China, or even France since it had three times as many people?The author ends with a brief summary of the locomotive contest, provides a fitting conclusion by quoting from an 1858-59 lecture or speech of Abraham Lincoln's on "Discoveries and Inventions" (which he agrees with most reviewers as not one of his best) but emphasizes Lincoln's closing remark that patent laws added "the fuel of interest to the fire of genius" that has been etched in stone now at the US Patent Office, is quite an appropriate end to the author's description of that very important creationOn the negative side, the reference to the earth being 33 trillion cubic kilometers (in a somewhat facetious side note) is a bit off being much closer to 1.083 trillion cubic kilometers, and some data could not be found on the index pages mentioned, though its in the book somewhere, and a problem common with many books.

Reviewer: OTO CESAR MAGALHAES
Rating: 5.0 out of 5 stars
Title:
Review: William Rosen has managed, in this book, to gather several historical facts like experimental education, law of patents, British revolution, iron works, wool development, coal mining and steam engines and show how it all were assembled in the recent most significant change in human history 300 years ago and continues to this day.

Reviewer: Cliente Amazon
Rating: 5.0 out of 5 stars
Title:
Review: From an historian a beautiful book on why the industrial revolution happened in Britain and on the 18th century. An involving story (chronicled ) of the series of innovative ideas ( about heat, pressure, steam, patent law, etc) that starting from the first century Alexandria till the Rocket ( the first locomotive Rail )on the 1829.Written with the details of the historian mixed with the hindsight of contemporary wisdom. The key point is that innovative ideas are no not an individual affaire but a “ network effect”.Main takeaway: the way to create wealth for nations!

Reviewer: CD5968
Rating: 5.0 out of 5 stars
Title:
Review: J'avais fait l'acquisition de ce livre autant pour l'histoire de la révolution industrielle en général que pour celle du transport ferroviaire en particulier. Je n'ai pas été déçu. Il est très instructif de voir ce que les anglo-saxons ont comme recul sur le fonctionnement de l'économie, l'impact des inventions, leur interprétation des faits, leur manière d'analyser le lien entre économie et technologie. C'est un livre dans lequel l'amateur de développement personnel et de sociologie y trouvera aussi matière à réfléchir. Que du plaisir.

Reviewer: beau loots
Rating: 5.0 out of 5 stars
Title:
Review: Mr Rosen is the thinking man’s historian. His knowledge of his subject is encyclopedic, the story line is illuminating, and the insight into the interplay of complex factors is background knowledge that makes history lucid.I recommend this book to anyone who has interest in intellectual and cultural evolution.

Reviewer: TeamManley
Rating: 5.0 out of 5 stars
Title:
Review: I found this a fascinating book, about a fascinating subject. William has taken Stephenson's steam engine as focal point of an exploration of history, technology and ideas. This is far more than a history of one steam engine, it is a book that uses the advance of technology to reflect on social, economic, legal, political, economic and philosophical issues.Chapter 12- 'Strong steam' is the chapter that grabbed my attention the most; giving the best summary of the birth of the 'Cornish' engine I have found so far. The story told within that chapter is intertwined with the one told in 'The Last Great Cornish Engineer', a book that explains how William West took the high pressure beam engine to the peak of its development.navsbooks.wordpress.comThe Last Great Cornish Engineer: William West of TredenhamThe Last Great Cornish Engineer: William West of TredenhamSketch of the life of William West C.E. of Tredenham-The last of the great Cornish Engineers