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CHAPTER 1

Enlightenment

'But these philosophers, whose hands seem only made to dabble in dirt, and their eyes to pore over the microscope or the crucible, have indeed performed miracles.'

Mary Shelley , Frankenstein

Mary Wollstonecraft Shelley (née Godwin) was born on 30 August 1797 and died on 1 February 1851. The 53 years of her life were packed with scandal, controversy and heartache. It has been said that she 'embodies the English Romantic movement'. She was survived by her son Percy Florence Shelley, named after his father, the poet Percy Bysshe Shelley. Mary Shelley lived at a time of political, social and scientific revolution, all of which she drew upon to create her masterpiece, Frankenstein.

How did a teenager create a work of fiction that has enthralled, inspired and terrified for two centuries? Like the infamous monster of her creation, stitched together from an assortment of fragments, Mary's novel took a collection of oddments from her own life and weaved them together to make a work much greater than the sum of its parts. Scenery from her travels, people she met and numerous influences from books she had read made it into the final work.

The novel, first published in 1818, was to dominate her literary legacy just as the monster dominated the life of his creator, Victor Frankenstein. Frankenstein gave Mary fame, if not fortune, and was recognised early on as a classic of English literature. In 1831 it was included in a series of standard English novels and this second publication gave Mary the opportunity to revise and edit her work. It is this later edition that is more widely read, but this book will examine both editions.

Frankenstein is often cited as the first science-fiction novel, but there is much scientific fact to be found within its pages. This book looks at many of the influences on the novel and particularly the science behind the story. Mary's characters were inventions – although they were heavily based on real people – but the science her characters studied was very real. Even the alchemists that fascinated the fictional Victor Frankenstein were real people. Mary's science fact veered off into science fiction when Victor made his sensational discovery of the secret of life.

To understand how Mary pieced together her creation it is worth spending a little time looking at the political, social and scientific world that she grew up in as well as the people and experiences that made their way into the novel. The ideas and concepts explored in Frankenstein – science, life, responsibility – were at the forefront of philosophical and public debate in the century preceding the book's publication. There were many other influences from Mary's childhood that will be explored in subsequent chapters before we look at the scientific aspects of the novel and the character of Victor Frankenstein in detail.

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The eighteenth century is known as the 'Age of Enlightenment'. A time when prominent thinkers began to examine and question not only political theory, but also religious authority and how radical principles might be used as a means of social improvement. One method of social improvement was education, increasing the knowledge – or 'Enlightenment' – of everyone, not just a privileged few. Immanuel Kant, a prominent German philosopher of the time, defined Enlightenment in 1784 as 'mankind's emancipation from self-imposed immaturity, and unwillingness to think freely for oneself'.

The century preceding Mary's birth was a time of political turmoil and political unrest was a feature of much of her early life. Over the course of the eighteenth century much of Europe moved away from a medieval system of government towards the modern system of statehood. The transformation was not simple or easy. Borders moved frequently, smaller estates were subsumed into larger nation states and wars were fought over land, and the control of that land. For example, when Mary was born and for the first 17 years of her life Britain was almost continuously at war with France.

Rulers sought to consolidate their power, many becoming the sole source of government over vast regions and peoples. Many rulers were influenced by the values of Enlightenment and sought to improve the lot of their subjects. Strange as it may seem to modern eyes, these individuals were welcomed by contemporary philosophes and became known as 'enlightened despots'.

At the turn of the eighteenth century, under the rule of Louis XIV, France became the artistic, cultural and political leader of Europe. Other rulers copied not only the system of government, but also the fashions and architectural styles of the Sun King's magnificent court. French became the common language of diplomatic and scientific discourse for the following century.

Louis XIV was succeeded to the throne by his grandson Louis XV. It became apparent that rule by one person was only as good as that person, and Louis XV failed to live up to the role. France stagnated politically under Louis XV's reign, but it generated a wealth of intellectual ideas.

Many French philosophes contributed and collected together their ideas in the French Encyclopédie, published between 1751 and 1772. It was the collective work of not only philosophers, but also contributions from experts from various fields, including science and engineering. The 28-volume work, complete with over 70,000 articles and more than 3,000 illustrations, aimed 'to change the way people think'. It was a grand compendium of knowledge as well as Enlightenment ideas and its influence spread not just through France but across Europe.

Political and social upheavals were not confined to Europe. In America, war had erupted between the indigenous population and French and British colonisers. It was a successful campaign from the British point of view. Agreements were made with indigenous peoples for the division of land, but the French were militarily and financially ruined. The war had doubled Britain's national debt and to recoup some of their losses, new taxes were imposed on the colonies. Americans became increasingly hostile to these unfair taxes and began to challenge the authority of a distant foreign government. Incidents such as the Boston Tea Party in 1773 raised tensions and in 1775 revolution began. It resulted in the complete separation of this new nation from the British Empire in 1783.

Attention on America also threw a spotlight on the treatment of slaves brought from Africa to American, and British, colonies to work. The Shelleys were known to deplore the slave trade, and Frankenstein has been interpreted as a comment on slavery through examining the treatment of a race of humans visibly different to those around them.

The wars in America also had an impact in France. The defeat and financial cost had weakened both the monarchy and government. As a result of the spread of Enlightenment ideas and huge social upheavals, attention was increasingly drawn to examining how society treated its fellow citizens. In France, while these same ideas had taken hold, the aristocracy had effectively blocked social reform and shored up their own privileged positions. Poor crop yields, increasing disparity between rich and poor, and many other factors, eventually led to a violent and bloody revolution. In 1789 the French Revolution began and led to the Napoleonic Wars, which had repercussions throughout Europe.

The French Revolution transformed French society and moved it towards a more democratic and secular government. The authority of one group of people over the majority, and the majority's unquestioning acceptance of the situation, was no longer seen as a divine right. A set of principles were established in the Code Civil des Français, which remains the basis of civil law in France to this day and its influence on legal systems spread far beyond the French border to Italy, Germany, Belgium and the Netherlands. The Declaration of the Rights of Man and of the Citizen gave greater freedoms and protection to people of different faiths, black people, homosexuals and women. Though it was never implemented it has influenced liberal democracy globally.

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The eighteenth century brought about changes in geography and politics, as well as cultural and intellectual attitudes towards science. The medieval view of the world, explained by divine revelation, gave way to an increasingly secular way of understanding the universe in terms of universally applicable laws. Tremendous progress in science was made possible by three main changes in scientific method. Firstly, experimentation and experience came to be seen as valid methods of producing knowledge, as the limitations of the Greek tradition of advancing knowledge by well-constructed arguments became apparent.

Secondly, Isaac Newton, and others, had shown that processes such as movement could be explained in purely mathematical terms. There was no need for a god's direct and continued intervention to make the planets move through the heavens. The universe could be seen as a fantastic mechanical operation. However, God was not completely excluded from the universe; some 'prime mover' was often invoked as the initiator of everything.

Thirdly, the Enlightenment was an era of instrumentation. Devices, gadgets and gizmos of increasing complexity and accuracy were being designed, built and utilised. In Newton's mechanical universe, God was either a mathematician or an instrument maker.

While borders within Europe were something of a moveable feast during the eighteenth century, there was increased interest in the world beyond. Humans were no longer bound to the surface of the globe as hot-air balloons appeared in the skies above London and Paris. During the eighteenth century the known world had simultaneously expanded with the discovery of new continents, and shrunk as increasing travel and trade brought exotic goods and fantastic tales from far-flung places back to Europe.

Rulers realised that trade was the best way to bring much-needed money into their countries. The Dutch, the most mercantile and one of the wealthiest nations in Europe in the eighteenth century, had established the Dutch East India Company to trade exclusively with the East, as well as other operations in South Africa and the Americas. Spices, silks and slaves were packed into vessels that sailed across the globe. Other countries tried to mimic the success of the Dutch East India Company but their efforts paled in comparison.

Exploration of distant lands is a prominent theme in Frankenstein. The novel is framed within Walton's scientific expedition to the North Pole. The North Pole was a complete unknown and a source of fascination for eighteenth-century natural philosophers. No one knew if the top of the world was land, ice or open sea. Proposed expeditions to the Arctic hoped to increase scientific knowledge, for example, discovering the cause of a compass needle's attraction, as well as reaping the economic benefits from shorter trade routes to Asia.

As explorers pushed further and penetrated deeper into new continents, maps had fewer unknowns and cartographers had less recourse to populate their blank spaces with fantastical creatures. Man's dominance over the globe is perhaps exemplified by a series of scientific experiments conducted between 1797 and 98. The global met the provincial in Henry Cavendish, the reclusive scientific genius who weighed the world in a shed in his garden on Clapham Common.

The availability of increasingly sophisticated instruments particularly aided both explorers and natural philosophers. Telescopes, microscopes and numerous other devices were designed and developed. Astronomers looked beyond the earth, and the boundaries of space were pushed back further than ever before with the addition of a new planet – Uranus – and comets to the solar system. Distant stars and nebula were observed and catalogued. What had once been the domain of the heavens was now mapped and mathematically defined.

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At the start of the eighteenth century, science, or natural philosophy as it was known, was still ill-defined and almost all-encompassing in the variety of its interests. As the century progressed, one discovery seemed to lead to another. Fantastic experiments and staggering scientific achievements proliferated. Science began to advance from an ad-hoc process, often carried out by wealthy individuals who had time and money to indulge their interests, to a professional activity. The aims of science changed as well. It was no longer seen as a purely intellectual exercise. Practical applications of this knowledge became increasingly obvious. The enlightened aims of science became not only to expand human knowledge, but to apply this newly acquired knowledge to real life. Engineering came to the fore with the direct aims of industrial, medical and social improvement.

Science became the fashionable philosophy of the day, the talk of every well-to-do drawing room and social gathering. Societies were formed, not just in the capitals of Europe but in the provinces as well, where science was discussed and experiments performed. Coffee houses in London buzzed with the talk of recent discoveries in far-flung parts of the world. A new intellectual rigour was brought to scientific investigations and, importantly, new discoveries were disseminated to a wide audience through lectures and printed works. Scientific ideas were published, not just as papers for the benefit of learned societies, but as books that were purchased, borrowed and shared by a wide readership.

In London in 1801, the Royal Institution opened its doors to allow the general public to attend lectures on the latest scientific discoveries. Audiences and readers were in turn encouraged to not only learn about science but to do scientific experiments themselves. The philosophy of the English Enlightenment encouraged everyone and anyone to participate in further discoveries. Pamphlets and books were sold at low prices and contained clear, practical advice on carrying out experiments for relatively little cost. Scientific equipment, microscopes, chemistry sets and electrical devices were on sale in London shops.

The boundaries between different scientific disciplines at this time were very blurred. Geology, anthropology, engineering, medicine and astronomy were all areas of interest, but individual disciplines and specialisms began to distinguish themselves. At the beginning of the nineteenth century chemistry was to emerge as the most prominent science of its day.

Chemistry had long been associated with alchemists and quacks but in the late eighteenth and early nineteenth century a phenomenal series of discoveries allowed it to move from a collection of facts and experimental results to the beginnings of a coherent scientific philosophy. Chemists were beginning to search for deeper truths that could connect all the known facts. Newton had led the way when he connected the motions of planets with the simple observation of an apple falling to the ground – gravity linked them all. Could there be greater underlying principles that connected different chemical reactions and properties of compounds and elements?

Phlogiston, a mysterious fluid thought to be in all substances to a greater or lesser extent, was proposed as the cause of burning. The eminent French chemist Antoine Lavoisier, who we will meet again in later chapters, thought it was the presence of oxygen that gave some compounds their acidic properties. The increased rigour that had developed exposed these theories as seriously flawed, but progress was being made. Tables of chemical affinities were constructed that began to reveal similarities or groupings for different elements. Lavoisier, with Pierre-Simon Laplace (known as the French Newton), developed a new system of chemical naming that brought order and showed connections, where before there had been chaos and apparently isolated facts.

As new discoveries were made a whole host of new things – lands, plants, peoples, elements, manufacturing techniques and scientific processes – all demanded new names. The naming of things took on huge significance. For example, Lavoisier's naming of oxygen, meaning 'producer of acids', encapsulated his theory behind the element and how he believed it combined with other substances. When new branches of science emerged the practitioners of those experiments defined themselves by their work. Benjamin Franklin and Joseph Priestley referred to themselves as electricians. Sir Humphry Davy and Antoine Lavoisier were both identified as chemists. However, these identities were fluid. In the eighteenth century Franklin could simultaneously be a statesman, printer and natural philosopher. Priestley was also known for his writing on political, religious and educational themes.

(Continues…)

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Excerpted from "Making The Monster"
by .
Copyright © 2018 Kathryn Harkup.
Excerpted by permission of Bloomsbury Publishing Plc.
All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher.
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