<h2><SPAN name="c5"></SPAN><span>5</span> <br/><span>THE THUNDER GIANT</span></h2>
<p>A few years before his retirement, Franklin, on a visit to
Boston, attended a display of electrical tricks given by a Dr.
Adam Spencer of Scotland. There is no record of the nature
of these “electrical tricks.” Franklin commented later that Dr.
Spencer was no expert and that they were imperfectly performed.
Since he had never seen anything of the sort before,
he was “surpris’d and pleased.”</p>
<p>That sparks could be produced by friction had been known
since ancient times. Little more was known about electricity
until, in the first part of the eighteenth century, a young
Frenchman, Charles François du Fay, identified two different
types of electricity: <i>vitreous</i>, produced by rubbing glass with
silk; <i>resinous</i>, produced by rubbing resin with wool or fur.
Such frictional electricity was brief-lived. Sparks flashed and
were gone, and that was the end of it.</p>
<p>Was there any way in which electric charges could be
preserved from the rapid decay which they underwent in the
air? Around 1747 two scientists were working independently
on this problem—E. C. von Kleist of Pomerania and Pieter
van Musschenbroek of the University of Leyden. Within a
few months of each other, they had found a method of storing
electricity in a container. The Leyden jar, this container was
named. It was the first electrical condenser.</p>
<p>In one experiment Musschenbroek suspended a glass phial
of water from a gun barrel by a wire which went down
through a cork in the phial a few inches into the water. The
gun barrel, hanging on a silk rope, had a metallic fringe inserted
into the barrel which touched an electrically charged
glass globe. A friend who was watching him, a man named
Cunaeus, happened to grasp the phial with one hand and the
wire with another. Immediately he felt a strange and startling
sensation—reportedly the first manmade electric shock in
history.</p>
<p>Musschenbroek repeated what Cunaeus had done, this time
using a small glass bowl as his “Leyden jar.” “I would not
take a second shock for the King of France,” he said.</p>
<p>Van Kleist in Pomerania produced the same effect. He lined
the inside and outside of his Leyden jar with silver foil,
charged the inner coat heavily, connected it with the outer
foil by a wire which he held in his hand—and felt a violent
shock run into his arm and chest.</p>
<p>A Leyden jar could take any number of forms. Even a wine
bottle would serve. The type used most frequently during the
next few years was a glass tube, some two and a half feet long,
and just big enough around so that a man might grasp it easily
in his hand. The advantage of this size and shape was that it
could most conveniently be electrified, which was then done
by hand, by rubbing the glass with a cloth or buckskin. This
simple device gave impetus to research on electricity throughout
Europe. It also provided a new form of entertainment.</p>
<p>Performers went from town to town with their Leyden
jars, giving spectators the thrill of receiving electric shocks,
and extolling the marvels of “electrical fire.” Louis XV of
France invited his guests to watch a novel spectacle arranged
by his court philosopher, Abbé Jean-Antoine Nollet. The
King’s Guard in full uniform lined up before the throne,
holding hands. The first one was instructed to grasp the wire
or chain connected to the Leyden jar. They all jumped convulsively
into the air as an electric current passed through
them.</p>
<p>In Italy some scientists tried to cure paralysis by electric
shock, claiming moderate success. In May 1748, for instance,
Jean-François Calgagnia, thirty-five years old, was given an
electric shock from a simple cylinder-type Leyden jar. Since
the age of twelve, his left arm had been so paralyzed he could
not lift his hand to his head. After the first electrical treatment
he at once raised his arm and touched his face. There is no
record as to whether the cure was permanent.</p>
<p>After Franklin became aware of this phenomenon, he was
agog to try experiments on his own. He wrote of his interest
to a London friend, Peter Collinson, a Quaker merchant and
member of the Royal Society. Collinson promptly sent him a
glass tube, along with suggestions as to how it might be used
for electrical experiments. This was all Franklin needed to
get started.</p>
<p>He was not trained in scientific matters as were many of his
European contemporaries. He was unfamiliar with scientific
jargon, and could only write about what he was doing in
everyday language. But he had those qualities that are innate
in any scientist, with or without a university degree—an inquiring
mind, patience, and persistence.</p>
<p>His experiments, beginning with the winter of 1746, covered
a wide range. He melted brass and steel needles by
electricity, magnetized needles, fired dry gunpowder by an
electric spark. He stripped the gilding from a book, and he
electrified a small metallic crown above an engraving of the
King of England—so that whoever touched the crown received
a shock!</p>
<p>His home was soon so crowded with curious visitors trooping
up and down the stairs, he could hardly get any work
done. He solved the problem by having a glass blower make
tubes similar to his, passing them out to friends so they could
make their own experiments.</p>
<p>Several of the Junto members worked closely with him. At
first they electrified the tube, as was still done in Europe, by
vigorously rubbing one side of it with a piece of buckskin.
One of the club members, a Silversmith named Philip Synge,
devised a sort of grindstone, which revolved the tube as one
turned a handle. To charge the tube with electricity, all that
was needed was to hold the buckskin against the glass as it
revolved, a vast saving in physical labor.</p>
<p>Another invention of Franklin and his associates was the
first storage battery. For electrical plates they used eleven
window glass panes about six by eight inches in size, covered
with sheets of lead, and hung on silk cords by means of hooks
of lead wire. They found it as easy to charge this “battery”
with frictional electricity as to charge a single pane of glass.</p>
<p>Among his disciples was an unemployed Baptist minister
named Ebenezer Kinnersley. Franklin suggested he might
both serve science and earn his living if he held electrical
demonstrations. Kinnersley’s first announcement of a lecture,
held in Newport, described “electrical fire” as having “an
appearance like fishes swimming in the air,” claiming this fire
would “live in water, a river not being sufficient to quench
the smallest spark of it.” He promised his audience such wonders
as “electrified money, which scarce anybody will take
when offered ... a curious machine acting by means of
electric fire, and playing a variety of tunes on eight musical
bells ... the force of the electric spark, making a fair hole
through a quire of paper....”</p>
<p>Kinnersley lectured in the colonies and the West Indies and
was hugely successful. Neither he nor any of the other collaborators
could rival Franklin’s own achievements.</p>
<p>Early in 1747, he gave the names of positive and negative
(or plus and minus) to the two types of electricity, to replace
the unwieldy terms, resinous and vitreous. Positive and negative
electricity became part of the scientific vocabulary. He
was the first to refer to the <i>conductivity</i> of certain substances.
Electricity passed easily through metals and water; they were
<i>conductive</i>. Glass and wood were <i>nonconductive</i>, unless they
were wet. He also noted that pointed metal rods were wonderfully
effective “in drawing off and throwing off the electrical
fire.”</p>
<p>After he retired in 1748, he spent much more time on
electricity. To Peter Collinson in London he wrote, “I never
was before engaged in any study that so totally engrossed my
attention and my time as this has lately done.” He kept Collinson
informed in detail of his experiments, not because he
thought he had the final word but in the hope that his experiments
might possibly prove helpful to English scientists.</p>
<p>It was to Collinson he described an electrical party to be
held on the banks of the Schuylkill River in the spring of
1749: “A turkey is to be killed for our dinner by the electrical
shock, and roasted by the electrical jack, before a fire kindled
by the electrified bottle; when the healths of all the famous
electricians in England, Holland, France, and Germany are to
be drank in electrified bumpers, under the discharge of guns
from an electrical battery.”</p>
<p>For Christmas dinner that year, he started to electrocute
another turkey, but inadvertently gave himself the shock intended
for the fowl: “The company present ... say that the
flash was very great and the crack as loud as a pistol....
I neither saw the one nor heard the other.... I then felt
... a universal blow throughout my whole body from head
to foot.... That part of my hand and fingers which held
the chain was left white, as though the blood had been driven
out, and remained so eight or ten minutes after, feeling like
dead flesh; and I had a numbness in my arms and the back of
my neck which continued till the next morning but wore off.”</p>
<p>He was apologetic rather than frightened by the near
catastrophe, comparing himself to the Irishman “who, being
about to steal powder, made a hole in the cask with a hot iron.”</p>
<p>This was soon after he had come to the conclusion that
what he now called “electrical fluid” had much in common
with lightning—that indeed they might be one and the same
thing. He was not the first to propose this theory but no one
before him had been able to suggest how it might be tested.</p>
<p>Thunder and lightning had mystified humanity since the
beginning of recorded history. The Greeks had held that
thunderbolts were launched by the god Jupiter. (One Greek
philosopher, Empedocles, thought that lightning was caused
by the rays of the sun striking the clouds.) Hunters of primitive
tribes prayed to the god of lightning, who was a killer, as
they wished to be. Certain medicine men were said to be
endowed with the gift of summoning lightning at will.</p>
<p>Since biblical days, lightning was assumed to be an act of
heavenly vengeance, but no one could explain the paradox
that it struck church steeples more frequently than other
buildings. In medieval times, people believed that ringing
church bells would keep lightning away, a belief that survived
the death of countless unfortunate bell ringers.</p>
<p>About 1718, an English scientist, Jonathan Edwards, suggested
that thunder and lightning might be produced by a
“mighty fermentation, that is some way promoted by the cool
moisture, and perhaps attraction of the clouds.” There had
been very few other attempts to give a scientific explanation of
the phenomenon, and even in Franklin’s time many preachers
considered lightning a manifestation of the Divine Will.</p>
<p>“Electrical fluid” and lightning had in common, Franklin
wrote in his notes on November 7, 1749, that they both gave
light, had a crooked direction and swift motion, and were
conducted by metals. Both melted metals and could destroy
animals. Since they were similar in so many respects, would
it not follow that lightning, like “electrical fluid” would be
attracted by pointed rods? “Let the experiment be made.”</p>
<p>By May 1750, he was sure enough of his hypothesis that he
elaborated to Peter Collinson the advantages to humanity of
what later were called lightning rods:</p>
<blockquote>
<p>I am of the opinion that houses, ships, and even towers and
churches may be effectually secured from the strokes of lightning
... if, instead of the round balls of wood or metal which
are commonly placed on tops of weathercocks, vanes, or masts,
there should be a rod of iron eight or ten feet in length,
sharpened gradually to a point like a needle ... the electric
fire would, I think, be drawn out of a cloud silently, before
it could come near enough to strike....</p>
</blockquote>
<p>Did he guess that he was on the verge of the most momentous
discovery of the century—one which would assure his
name a place among the immortals? It is fairly certain he was
more interested in solving a perplexing problem than in immortality.
Possibly he took it for granted that European
scientists were already three steps ahead of him.</p>
<p>By July he had prepared a manuscript describing all his
exciting experiments of the past two years, and including
specific instructions for setting up a lightning rod on a tower
or steeple, even to the necessary feature of a grounding wire.
“Let the experiment be made,” he had said. He did not make
it himself, not then. For one thing, he was waiting for a spire
to be erected on the top of Christ Church, from which he
wished to make his first try of drawing lightning from the
skies. Also, in spite of his alleged retirement, his days were
becoming increasingly filled with public duties.</p>
<p>He still had the Gazette and <i>Poor Richard’s Almanack</i> to
publish and edit. Beginning in 1748, he served on the City
Council. Since 1749 he was Grand Master of the Masons. In
1751 he was made an alderman and a member of the Pennsylvania
Assembly, where previously he had served as clerk.</p>
<p>In 1750, an American Philosophical Society member, Dr.
Thomas Bond, came to him for help in starting a hospital for
the sick and the insane. Hitherto those who could not pay for
medical care had no choice but the prison or the almshouse.
The need was urgent but Dr. Bond had failed to arouse interest
in his project.</p>
<p>“Those whom I ask to subscribe,” he confided to Franklin,
“often ask me whether I have consulted you and what you
think of it. When I tell them I have not, they don’t subscribe.”</p>
<p>Franklin knew promotion methods as Dr. Bond did not, and
began by calling a meeting of citizens. Under his impetus the
list of subscribers grew, though not until May 1755 was the
cornerstone of the Pennsylvania Hospital laid on Eighth Street
between Spruce and Pine. Nearly thirty years later, when
Dr. Benjamin Rush joined the staff, the “lunatics” at Pennsylvania
Hospital received the first intelligent care available
in America and, with few exceptions, in the world.</p>
<p>Franklin was also busy during this period in the formation
of America’s first insurance company (stemming from a meeting
of Philadelphia businessmen in 1752), and was taking the
lead in organizing an expedition in search of a Northwest
Passage, under Captain Charles Swaine, America’s first voyage
of Arctic exploration.</p>
<p>In the category of pleasure were the infrequent periods he
spent on his Burlington farm, where he raised corn, red clover,
herd grass and oats, recording with scientific precision the
effects of frost and the results obtained from different types
of soil. He was one of the earliest Americans to think of agriculture
as a science. He never could persuade his farmer
neighbors to follow his example. They held that the ways of
their forefathers were inevitably the best.</p>
<p>It may have been at his farm that he made his experiment on
ants. Some ants had found their way into an earthen pot of
molasses. He shook out all but one and hung the pot by a
string to a nail in the ceiling. When the ant had dined to its
satisfaction, it climbed up the string and down the wall to the
floor. Half an hour later, he noted a swarm of ants retracing
its course back to the pot—exactly as though their comrade
had verbally informed them where to go for a good meal.</p>
<p>There were few mysteries of nature on which at one time
or another Franklin did not direct his attention. More often
than not, he wrote his speculations in long and entertaining
and gracefully phrased letters to his friends, men and women
alike.</p>
<p>If he was not impatient to learn what Peter Collinson
thought of his proposed lightning rods, it was simply that he
had no time for impatience. The truth was that Collinson had
found his paper fascinating and had even read it to the Royal
Society. As the Society members remained skeptical and unimpressed,
in 1751 he arranged for it to be printed in a pamphlet—“Experiments
and Observations on Electricity, Made
at Philadelphia, in America.” Dr. John Fothergill, a London
physician, wrote the preface. The pamphlet was translated
into French the next year, creating immediate excitement.</p>
<p>Three French scientists, the naturalist Count Georges Louis
Buffon, Thomas François d’Alibard, and another named de
Lor, resolved to carry out the experiment on drawing lightning
from the skies, which Franklin had outlined.</p>
<p>It was d’Alibard who succeeded first. At Marly, outside of
Paris, he set up a pointed iron rod forty feet long, not on a
church steeple as Franklin had recommended, but simply on
a square plank with legs made of three wine bottles to insulate
it from the ground. During a thunderstorm, on May 10, 1752,
a crash of thunder was followed by a crackling sound—and
sparks flew out from the rod. Here then was absolute proof
that Franklin was right. Lightning and electricity were
identical.</p>
<p>De Lor repeated the experiment in Paris eight days later.
Louis XV, King of France, was so moved that he sent congratulations
to the Royal Society, to be relayed to Messieurs
Franklin and Peter Collinson. The first successful experiment
in London was made by John Canton. Soon it was being repeated
throughout Europe. The name of Benjamin Franklin
was on everyone’s tongue.</p>
<p>No news of all this had yet been brought on the slow sailing
ships when, in June 1752, Franklin decided not to wait for
the completion of the Christ Church spire for his experiment.
He had another scheme. Why not try to draw electricity
from the skies with a kite?</p>
<p>“Make a small cross of two light strips of cedar, the arms so
long as to reach to the four corners of a large thin silk handkerchief
when extended; tie the corners of the handkerchief
to the extremities of the cross.” Thus he later described the
body of this world famous kite. Like ordinary kites, it had a
tail, loop, and string. At the top of the vertical cedar strip,
he fastened a sharp pointed wire about a foot long. At the end
of the string he tied a silk ribbon. He fastened a small key at
the juncture of silk and twine.</p>
<p>With this child’s plaything, he and his tall full-grown son,
William, took off across the fields one threatening summer
day. They let the wind raise the kite into the air and they
waited. Even before it began raining, Franklin observed some
loose threads from the hempen string standing erect. He
pressed his knuckle to the key—and an electric spark shot out.
There were more sparks when the thunderstorm began. After
the string was wet, the “electric fire” was “copious.”</p>
<p>He must have grinned triumphantly at William, and perhaps
said casually, “Well, Billy, we’ve done it.”</p>
<p>There is no evidence that he realized his experiment might
be dangerous, even deadly.</p>
<p>The first account of the “Electrical Kite” appeared five
months later in the October 19, 1752, issue of the <i>Gazette</i>.
<i>Poor Richard’s Almanack</i> for 1753 contained complete instructions
on how to build a lightning rod. He had already
put one up on his own chimney. It had small bells which
chimed when clouds containing electricity passed by. The
bells rang in his house for years.</p>
<p>News of his triumphs abroad were now flooding in. The
praise of the French king, he wrote a friend, made him feel
like the girl “who was observed to grow suddenly proud, and
none could guess the reason, till it came to be known that she
had got on a new pair of garters.” The Royal Society, making
up for lost time, published an account of his kite in <i>Transactions</i>,
their official paper, and in November 1753, gave him
the Copley gold medal for “his curious experiments and observations
on electricity.” They conservatively held off making
him a member of the Society until May 29, 1756. At
home, Harvard, Yale, and William and Mary College in turn
gave him honorary degrees of master of arts.</p>
<p>While these and other tributes were being heaped on him,
he was launching into a new profession—that of military expert
and officer.</p>
<div style="break-after:column;"></div><br />
1 of 2
2 of 2
Previous
Next
Update Required
To play the media you will need to either update your browser to a recent version or update your Flash plugin.