Science Set Free: 10 Paths to New Discovery - Couverture rigide

Sheldrake, Rupert

 
9780770436704: Science Set Free: 10 Paths to New Discovery
Couverture rigide
ISBN 10 : 0770436706 ISBN 13 : 9780770436704
Editeur : Crown Pub, 2012

Synopsis

Science Set Free The bestselling author of "Dogs That Know When Their Owners Are Coming Home" offers an intriguing new assessment of modern-day science that will radically change the way possibilities are viewed. Full description

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Extrait

Chapter 1

Is Nature Mechanical?

Many people who have not studied science are baffled by scientists’ insistence that animals and plants are machines, and that humans are robots too, controlled by computer-like brains with genetically programmed software. It seems more natural to assume that we are living organisms, and so are animals and plants. Organisms are self-organizing; they form and maintain themselves, and have their own ends or goals. Machines, by contrast, are designed by an external mind; their parts are put together by external machine-makers and they have no purposes or ends of their own.

The starting point for modern science was the rejection of the older, organic view of the universe. The machine metaphor became central to scientific thinking, with very far-reaching consequences. In one way it was immensely liberating. New ways of thinking became possible that encouraged the invention of machines and the evolution of technology. In this chapter, I trace the history of this idea, and show what happens when we question it.

Before the seventeenth century, almost everyone took for granted that the universe was like an organism, and so was the earth. In classical, medieval and Renaissance Europe, nature was alive. Leonardo da Vinci (1452–1519), for example, made this idea explicit: “We can say that the earth has a vegetative soul, and that its flesh is the land, its bones are the structure of the rocks . . . its breathing and its pulse are the ebb and flow of the sea.” William Gilbert (1540–1603), a pioneer of the science of magnetism, was explicit in his organic philosophy of nature: “We consider that the whole universe is animated, and that all the globes, all the stars, and also the noble earth have been governed since the beginning by their own appointed souls and have the motives of self-conservation.”

Even Nicholas Copernicus, whose revolutionary theory of the movement of the heavens, published in 1543, placed the sun at the center rather than the earth was no mechanist. His reasons for making this change were mystical as well as scientific. He thought a central position dignified the sun:

Not unfittingly do some call it the light of the world, others the soul, still others the governor. Tremigistus calls it the visible God: Sophocles’ Electra, the All-seer. And in fact does the sun, seated on his royal throne, guide his family of planets as they circle around him

Copernicus’s revolution in cosmology was a powerful stimulus for the subsequent development of physics. But the shift to the mechanical theory of nature that began after 1600 was much more radical.

For centuries, there had already been mechanical models of some aspects of nature. For example, in Wells Cathedral, in the west of England, there is a still-functioning astronomical clock installed more than six hundred years ago. The clock’s face shows the sun and moon revolving around the earth, against a background of stars. The movement of the sun indicates the time of day, and the inner circle of the clock depicts the moon, rotating once a month. To the delight of visitors, every quarter of an hour, models of jousting knights rush round chasing each other, while a model of a man bangs bells with his heels.

Astronomical clocks were first made in China and in the Arab world, and powered by water. Their construction began in Europe around 1300, but with a new kind of mechanism, operated by weights and escapements. All these early clocks took for granted that the earth was at the center of the universe. They were useful models for telling the time and for predicting the phases of the moon; but no one thought that the universe was really like a clockwork mechanism.

A change from the metaphor of the organism to the metaphor of the machine produced science as we know it: mechanical models of the universe were taken to represent the way the world actually worked. The movements of stars and planets were governed by impersonal mechanical principles, not by souls or spirits with their own lives and purposes.

In 1605, Johannes Kepler summarized his program as follows: “My aim is to show that the celestial machine is to be likened not to a divine organism but rather to clockwork . . . Moreover I show how this physical conception is to be presented through calculation and geometry.”4 Galileo Galilei (1564–1642) agreed that “inexorable, immutable” mathematical laws ruled everything.

The clock analogy was particularly persuasive because clocks work in a self-contained way. They are not pushing or pulling other objects. Likewise the universe performs its work by the regularity of its motions, and is the ultimate time-telling system. Mechanical clocks had a further metaphorical advantage: they were a good example of knowledge through construction, or knowing by doing. Someone who could construct a machine could reconstruct it. Mechanical knowledge was power.

The prestige of mechanistic science did not come primarily from its philosophical underpinnings but from its practical successes, especially in physics. Mathematical modelling typically involves extreme abstraction and simplification, which is easiest to realize with man-made machines or objects. Mathematical mechanics is impressively useful in dealing with relatively simple problems, such as the trajectories of cannonballs or rockets.

One paradigmatic example is billiard-ball physics, which gives a clear account of impacts and collisions of idealized billiard balls in a frictionless environment. Not only is the mathematics simplified, but billiard balls themselves are a very simplified system. The balls are made as round as possible and the table as flat as possible, and there are uniform rubber cushions at the sides of the table, unlike any natural environment. Think of a rock falling down a mountainside for comparison. Moreover, in the real world, billiard balls collide and bounce off each other in games, but the rules of the game and the skills and motives of the players are outside the scope of physics. The mathematical analysis of the balls’ behavior is an extreme abstraction.

From living organisms to biological machines

The vision of mechanical nature developed amid devastating religious wars in seventeenth-century Europe. Mathematical physics was attractive partly because it seemed to provide a way of transcending sectarian conflicts to reveal eternal truths. In their own eyes the pioneers of mechanistic science were finding a new way of understanding the relationship of nature to God, with humans adopting a God-like mathematical omniscience, rising above the limitations of human minds and bodies. As Galileo put it:

When God produces the world, he produces a thoroughly mathematical structure that obeys the laws of number, geometrical figure and quantitative function. Nature is an embodied mathematical system.

But there was a major problem. Most of our experience is not mathematical. We taste food, feel angry, enjoy the beauty of flowers, laugh at jokes. In order to assert the primacy of mathematics, Galileo and his successors had to distinguish between what they called “primary qualities,” which could be described mathematically, such as motion, size and weight, and “secondary qualities,” like color and smell, which were subjective. They took the real world to be objective, quantitative and mathematical. Personal experience in the lived world was subjective, the realm of opinion and illusion, outside the realm of science.

René Descartes (1596–1650) was the principal proponent of the mechanical or mechanistic philosophy of nature. It first came to him in a vision on November 10, 1619, when he was “filled with enthusiasm and discovered the foundations of a marvellous science.” He saw the entire universe as a mathematical system, and later envisaged vast vortices of swirling subtle matter, the ether, carrying around the planets in their orbits.

Descartes took the mechanical metaphor much further than Kepler or Galileo by extending it into the realm of life. He was fascinated by the sophisticated machinery of his age, such as clocks, looms and pumps. As a youth he designed mechanical models to simulate animal activity, such as a pheasant pursued by a spaniel. Just as Kepler projected the image of man-made machinery onto the cosmos, Descartes projected it onto animals. They, too, were like clockwork.8 Activities like the beating of a dog’s heart, its digestion and breathing were programmed mechanisms. The same principles applied to human bodies.

Descartes cut up living dogs in order to study their hearts, and reported his observations as if his readers might want to replicate them: “If you slice off the pointed end of the heart of a live dog, and insert a finger into one of the cavities, you will feel unmistakably that every time the heart gets shorter it presses the finger, and every time it gets longer it stops pressing it.”

He backed up his arguments with a thought experiment: first he imagined man-made automata that imitated the movements of animals, and then argued that if they were made well enough they would be indistinguishable from real animals:

If any such machines had the organs and outward shapes of a monkey or of some other animal that lacks reason, we should have no way of knowing that they did not possess entirely the same nature as those animals.

With arguments like these, Descartes laid the foundations of mechanistic biology and medicine that are still orthodox today. However, the machine theory of life was less readily accepted in the seventeenth and eighteenth centuries than the machine theory of the universe. Especially in England, the idea of animal-machines was considered eccentric. Descartes’ doctrine seemed to justify cruelty to animals, including vivisection, and it was said that the test of his followers was whether they...

Revue de presse

 
"Science is ready to evolve beyond materialism and dogma. Rupert Sheldrake is a pioneer who is paving the way for the future of the sciences."  
—Deepak Chopra, M.D., author of War of the Worldviews
 
“This provocative and engaging book will make you question basic assumptions of Western science.  I agree with Rupert Sheldrake that, among other problems, those assumptions hinder medical progress because they severely limit our understanding of health and illness. I will recommend Science Set Free to my colleagues, students, patients, and friends.”
—Andrew Weil, M.D., author of Spontaneous Happiness

“Rupert Sheldrake may be to the 21st century what Charles Darwin was to the 19th:  someone who sent science spinning in wonderfully new and fertile directions.  The only thing that is certain in science is that it will change.  In SCIENCE SET FREE, Sheldrake gives us an inspiring picture of what these changes are likely to be."
—Larry Dossey, M.D. author of Reinventing Medicine
 
 “Science is often portrayed as a paragon of intellectual freedom. It's a quaint idea, but it's not true. Some key concepts in science have hardened into unshakeable, unquestioned dogma. Science Set Free exposes ten of the key dogmas of modern times. If even one is slightly off, then the scientific world is in for a shock, and the aftershocks will have huge impacts on technology, medicine, and religion. Rupert Sheldrake skillfully examines each dogma and argues, with evidence, that all ten dogmas are wrong. After reading this book I am persuaded that he's right. If you agree that science must be freed from the shackles of antiquated beliefs, then read this book. If you don't agree, then read it twice.”
—Dean Radin, Ph.D., author of The Conscious Universe
 
“This is a terrific, engrossing book that throws open the shutters to reveal our world to be so much more intriguing and profound than could ever have been supposed.”
—James Le Fanu, author of The Rise and Fall of Modern Medicine
 
“Certainly we need to accept the limitations of much current dogma and keep our minds as open as we reasonably can. Sheldrake may help us do so through this well-written, challenging, and always interesting book.”
—Sir Crispin Tickell, Financial Times
 
“Rupert Sheldrake does science, humanity and the world at large a considerable favor.”
—Colin Tudge, Ph.D., Independent
 
“A fascinating, humane, and refreshing book that any layman can enjoy. . . . Dr. Sheldrake wants to bring energy and excitement back into science . . . He has already done more than any other scientist alive to broaden the appeal of the discipline, and readers should get their teeth into the important and astounding book.”
—Jason Goodwin, Country Life

Les informations fournies dans la section « A propos du livre » peuvent faire référence à une autre édition de ce titre.

Éditeur
Crown Pub
Date d'édition
2012
Langue
anglais
ISBN 10 
0770436706
ISBN 13 
9780770436704
Reliure
Relié
Nombre de pages
390
Coordonnées du fabricant
non disponible
Personne responsable
Purmerul LTD
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Autres éditions populaires du même titre

9780770436728: Science Set Free: 10 Paths to New Discovery

Edition présentée

ISBN 10 :  0770436722 ISBN 13 :  9780770436728
Editeur : Harmony/Rodale/Convergent, 2013
Couverture souple