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Authors: Niall Ferguson

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Perhaps most remarkably, at a time when anti-Turkish pamphlets were almost as popular as anti-Popish tracts in Germany,
25
the Koran was translated into Latin and published in Basel by the printer Johannes Oporinus. When, in 1542, the Basel city council banned the translation and seized the available copies, Luther himself wrote in Oporinus’ defence:

It has struck me that one is able to do nothing more grievous to Muhammad or the Turks, nor more to bring them to harm (more than with all weaponry) than to bring their Koran to Christians in the light of day, that they may see therein, how entirely cursed, abominable, and desperate a book it is, full of lies, fables and abominations that the Turks conceal and gloss over … to honour Christ, to do good for Christians, to harm the Turks, to vex the devil, set this book free and don’t withhold it … One must open sores and wounds in order to heal them.
26

 

Three editions were duly published in 1543, followed by a further edition seven years later. Nothing could better illustrate the opening of the European mind that followed the Reformation.

Of course, not everything that is published adds to the sum of human knowledge. Much of what came off the printing presses in the sixteenth and seventeenth centuries was distinctly destructive, like the twenty-nine editions of
Malleus maleficarum
that appeared between 1487 and 1669, legitimizing the persecution of witches, a pan-European mania that killed between 12,000 and 45,000 people, mostly women.
27
To the audiences who watched Christopher Marlowe’s
Doctor Faustus
, first performed in 1592, the idea that a German scholar might sell his soul to Satan in return for twenty-four years of boundless power and pleasure was entirely credible:

By him I’ll be great emperor of the world,

And make a bridge through the moving air,

To pass the ocean with a band of men;

I’ll join the hills that bind the Afric shore,

And make that country continent to Spain,

And both contributory to my crown:

The Emperor shall not live but by my leave …

 

Yet, just seventy years later, Thomas Hooke could publish his
Micrographia
(1665), a triumphant celebration of scientific empiricism:

By the means of
Telescopes
, there is nothing so
far distant
but may be represented to our view; and by the help of
Microscopes
, there is nothing so
small
, as to escape our inquiry; hence there is a new visible World discovered to the understanding. By this means the Heavens are open’d, and a vast number of new Stars, and new Motions, and new Productions appear in them, to which all the ancient Astronomers were utterly Strangers. By this the Earth it self, which lyes so neer us, under our feet, shews quite a new thing to us … We may perhaps be inabled to discern all the secret workings of Nature. What may not be therefore expected from it if thoroughly prosecuted?
Talking
and
contention of Arguments
would soon be turn’d into
labours
; all the fine
dreams
of Opinions, and
universal metaphysical natures
, which the luxury of subtil Brains has devis’d, would quickly vanish, and give place to
solid Histories
,
Experiments
and
Works.
And as at first, mankind
fell
by
tasting
of the forbidden Tree of Knowledge, so we, their Posterity, may be in part
restor’d
by the same way, not only by
beholding
and
contemplating
, but by
tasting
too those fruits of Natural knowledge, that were never yet forbidden. From hence the World may be assisted with
variety
of Inventions,
new
matter for Sciences may be
collected
, the
old improv’d
, and their
rust
rubb’d away …

 

Hooke’s use of the term ‘cell’ for a microscopic unit of organic matter was one of a host of conceptual breakthroughs, crowded together astonishingly in both time and space, that fundamentally redefined humanity’s understanding of the natural world.

The Scientific Revolution may be said to have begun with almost simultaneous advances in the study of planetary motion and blood circulation. But Hooke’s microscope took science to a new frontier by revealing what had hitherto been invisible to the human eye.
Micrographia
was a manifesto for the new empiricism, a world away from Faustus’ sorcery. However, the new science was about more than just accurate observation. Beginning with Galileo, it was about systematic
experimentation and the identification of mathematical relationships. The possibilities of mathematics were in turn expanded when Isaac Newton and Gottfried Leibniz introduced, respectively, infinitesimal and differential calculus. Finally, the Scientific Revolution was also a revolution in philosophy as René Descartes and Baruch Spinoza overthrew traditional theories about both perception and reason. Without exaggeration, this cascade of intellectual innovation may be said to have given birth to modern anatomy, astronomy, biology, chemistry, geology, geometry, mathematics, mechanics and physics. Its character is best illustrated by a list of just the most important twenty-nine breakthroughs of the period from 1530 to 1789.
*

 

1530

Paracelsus pioneers the application of chemistry to physiology and pathology

1543

Nicolaus Copernicus’
De revolutionibus orbium coelestium
states the heliocentric theory of the solar system

Andreas Vesalius’
De humani corporis fabrica
supplants Galen’s anatomical textbook

1546

Agricola’s
De natura fossilium
classifies minerals and introduces the term ‘fossil’

1572

Tycho Brahe records the first European observation of a supernova

1589

Galileo’s tests of falling bodies (published in
De motu
) revolutionize the experimental method

1600

William Gilbert’s
De magnete
,
magnetisque corporibus
describes the magnetic properties of the earth and electricity

1604

Galileo discovers that a free-falling body increases its distance as the square of the time

1608

Hans Lippershey and Zacharias Jansen independently invent the telescope

1609

1609 Galileo conducts the first telescopic observations of the night sky

1610

Galileo discovers four of Jupiter’s moons and infers that the earth is not at the centre of the universe

1614

John Napier’s
Mirifici logarithmorum canonis descriptio
introduces logarithms

1628

William Harvey writes
Exercitatio anatomica de motu cordis et sanguinis in animalibus
, accurately describing the circulation of blood

1637

René Descartes’ ‘La Géométrie’, an appendix to his
Discours de la méthode
, founds analytic geometry

1638

Galileo’s
Discorsi e dimonstrazioni matematiche
founds modern mechanics

1640

Pierre de Fermat founds number theory

1654

Fermat and Blaise Pascal found probability theory

1661

Robert Boyle’s
Skeptical Chymist
defines elements and chemical analysis

1662

Boyle states Boyle’s Law that the volume occupied by a fixed mass of gas in a container is inversely proportional to the pressure it exerts

1669

Isaac Newton’s
De analysi per aequationes numero terminorum infinitas
presents the first systematic account of the calculus, independently developed by Gottfried Leibniz

1676

Antoni van Leeuwenhoek discovers micro-organisms

1687

Newton’s
Philosophiae naturalis principia mathematica
states the law of universal gravitation and the laws of motion

1735

Carolus Linnaeus’
Systema naturae
introduces systematic classification of genera and species of organisms

1738

Daniel Bernoulli’s
Hydrodynamica
states Bernoulli’s Principle and founds the mathematical study of fluid flow and the kinetic theory of gases

1746

Jean-Etienne Guettard prepares the first true geological maps

1755

Joseph Black identifies carbon dioxide

1775

Antoine Lavoisier accurately describes combustion

1785

James Hutton’s ‘Concerning the System of the Earth’ states the uniformitarian view of the earth’s development

1789

Lavoisier’s
Traité élémentaire de chimie
states the law of conservation of matter

 

By the mid-1600s this kind of scientific knowledge was spreading as rapidly as had the doctrine of the Protestant Reformers a century before. The printing press and increasingly reliable postal services combined to create an extraordinary network, small by modern standards, but more powerful than anything previously achieved by a community of scholars. There was of course a great deal of intellectual resistance, as is always the case when the paradigm – the conceptual framework itself – shifts.
28
Indeed, some of this resistance came from within. Newton himself dabbled in alchemy. Hooke all but killed himself with quack remedies for indigestion. It was by no means easy for such men to reconcile the new science with Christian doctrine, which few were ready to renounce.
29
But it remains undeniable that this was an intellectual revolution even more transformative than the religious revolution that preceded and unintentionally begat it. The ground rules of scientific research – including the dissemination of findings and the assigning of credit to the first into print – were laid. ‘Your first letter [paper] baptised me in the Newtonian religion,’ wrote the young French philosopher and wit François-Marie Arouet (better known by his pen-name Voltaire) to Pierre-Louis Moreau de Maupertuis following the publication of the latter’s
Discourse on the Different Figures of the Planets
in 1732, ‘and your second gave me confirmation. I thank you for your sacraments.’
30
This was irony; yet it also acknowledged the revelatory nature of the new science.

Those who decry ‘Eurocentrism’ as if it were some distasteful prejudice have a problem: the Scientific Revolution was, by any scientific measure, wholly Eurocentric. An astonishingly high proportion of the key figures – around 80 per cent – originated in a hexagon bounded by Glasgow, Copenhagen, Kraków, Naples, Marseille and Plymouth, and nearly all the rest were born within a hundred miles of that area.
31
In marked contrast, Ottoman scientific progress was non-existent in this same period. The best explanation for this divergence was the unlimited sovereignty of religion in the Muslim world. Towards the end of the eleventh century, influential Islamic clerics began to argue that the study of Greek philosophy was incompatible with the teachings of the Koran.
32
Indeed, it was blasphemous to suggest that man might be able to discern the divine mode of operation, which God
might in any case vary at will. In the words of Abu Hamid al-Ghazali, author of
The Incoherence of the Philosophers
, ‘It is rare that someone becomes absorbed in this [foreign] science without renouncing religion and letting go the reins of piety within him.’
33
Under clerical influence, the study of ancient philosophy was curtailed, books burned and so-called freethinkers persecuted; increasingly, the madrasas became focused exclusively on theology at a time when European universities were broadening the scope of their scholarship.
34
Printing, too, was resisted in the Muslim world. For the Ottomans, script was sacred: there was a religious reverence for the pen, a preference for the art of calligraphy over the business of printing. ‘Scholar’s ink’, it was said, ‘is holier than martyr’s blood.’
35
In 1515 a decree of Sultan Selim I had threatened with death anyone found using the printing press.
36
This failure to reconcile Islam with scientific progress was to prove disastrous. Having once provided European scholars with ideas and inspiration, Muslim scientists were now cut off from the latest research. If the Scientific Revolution was generated by a network, then the Ottoman Empire was effectively offline. The only Western book translated into a Middle Eastern language until the late eighteenth century was a medical book on the treatment of syphilis.
37

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