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h more destructive。
introduce several million tons of air to this accelerator effect and the result can be exceedinglyenergetic。 a tropical hurricane can release in twenty…four hours as much energy as a rich;medium…sized nation like britain or france uses in a year。
the impulse of the atmosphere to seek equilibrium was first suspected by edmondhalley—the man who was everywhere—and elaborated upon in the eighteenth century by hisfellow briton george hadley; who saw that rising and falling columns of air tended toproduce “cells” (known ever since as “hadley cells”)。 though a lawyer by profession; hadleyhad a keen interest in the weather (he was; after all; english) and also suggested a linkbetween his cells; the earth’s spin; and the apparent deflections of air that give us our tradewinds。 however; it was an engineering professor at the école polytechnique in paris;gustave…gaspard de coriolis; who worked out the details of these interactions in 1835; andthus we call it the coriolis effect。 (coriolis’s other distinction at the school was to introducewatercoolers; which are still known there as corios; apparently。) the earth revolves at a brisk1;041 miles an hour at the equator; though as you move toward the poles the rate slopes offconsiderably; to about 600 miles an hour in london or paris; for instance。 the reason for thisis self…evident when you think about it。 if you are on the equator the spinning earth has tocarry you quite a distance—about 40;000 kilometers—to get you back to the same spot。 if youstand beside the north pole; however; you may need travel only a few feet to plete arevolution; yet in both cases it takes twenty…four hours to get you back to where you began。
therefore; it follows that the closer you get to the equator the faster you must be spinning。
the coriolis effect explains why anything moving through the air in a straight line laterallyto the earth’s spin will; given enough distance; seem to curve to the right in the northernhemisphere and to the left in the southern as the earth revolves beneath it。 the standard wayto envision this is to imagine yourself at the center of a large carousel and tossing a ball tosomeone positioned on the edge。 by the time the ball gets to the perimeter; the target personhas moved on and the ball passes behind him。 from his perspective; it looks as if it has curvedaway from him。 that is the coriolis effect; and it is what gives weather systems their curl andsends hurricanes spinning off like tops。 the coriolis effect is also why naval guns firingartillery shells have to adjust to left or right; a shell fired fifteen miles would otherwisedeviate by about a hundred yards and plop harmlessly into the sea。
considering the practical and psychological importance of the weather to nearly everyone;it’s surprising that meteorology didn’t really get going as a science until shortly before theturn of the nineteenth century (though the term meteorology itself had been around since1626; when it was coined by a t。 granger in a book of logic)。
part of the problem was that successful meteorology requires the precise measurement oftemperatures; and thermometers for a long time proved more difficult to make than you mightexpect。 an accurate reading was dependent on getting a very even bore in a glass tube; andthat wasn’t easy to do。 the first person to crack the problem was daniel gabriel fahrenheit; adutch maker of instruments; who produced an accurate thermometer in 1717。 however; forreasons unknown he calibrated the instrument in a way that put freezing at 32 degrees andboiling at 212 degrees。 from the outset this numeric eccentricity bothered some people; and in1742 anders celsius; a swedish astronomer; came up with a peting scale。 in proof of theproposition that inventors seldom get matters entirely right; celsius made boiling point zeroand freezing point 100 on his scale; but that was soon reversed。
the person most frequently identified as the father of modern meteorology was an englishpharmacist named luke howard; who came to prominence at the beginning of the nineteenthcentury。 howard is chiefly remembered now for giving cloud types their names in 1803。
although he was an active and respected member of the linnaean society and employedlinnaean principles in his new scheme; howard chose the rather more obscure askesiansociety as the forum to announce his new system of classification。 (the askesian society;you may just recall from an earlier chapter; was the body whose members were unusuallydevoted to the pleasures of nitrous oxide; so we can only hope they treated howard’spresentation with the sober attention it deserved。 it is a point on which howard scholars arecuriously silent。)howard divided clouds into three groups: stratus for the layered clouds; cumulus for thefluffy ones (the word means “heaped” in latin); and cirrus (meaning “curled”) for the high;thin feathery formations that generally presage colder weather。 to these he subsequentlyadded a fourth term; nimbus (from the latin for “cloud”); for a rain cloud。 the beauty ofhoward’s system was that the basic ponents could be freely rebined to describe everyshape and size of passing cloud—stratocumulus; cirrostratus; cumulocongestus; and so on。 itwas an immediate hit; and not just in england。 the poet johann von goethe in germany wasso taken with the system that he dedicated four poems to howard。
howard’s system has been much added to over the years; so much so that the encyclopedicif little read international cloud atlas runs to two volumes; but interestingly virtually all thepost…howard cloud types—mammatus; pileus; nebulosis; spissatus; floccus; and mediocris area sampling—have never caught on with anyone outside meteorology and not terribly muchthere; i’m told。 incidentally; the first; much thinner edition of that atlas; produced in 1896;divided clouds into ten basic types; of which the plumpest and most cushiony…looking wasnumber nine; cumulonimbus。
1that seems to have been the source of the expression “to be oncloud nine。”
for all the heft and fury of the occasional anvil…headed storm cloud; the average cloud isactually a benign and surprisingly insubstantial thi