8 EINSTEIN’S UNIVERSEAS

类别:文学名著 作者:比尔·布莱森 本章:8 EINSTEIN’S UNIVERSEAS

    tEENtury dreo a close, scientists could reflect isfaction tt of teries of tricity, magnetism,gases, optics, acoustics, kinetics, and statistical meco name just a feron, andradioactivity, invented tt, ttle erg.

    If a ted, accelerated, perturbed, distilled, combined, yand majestic t ill tend to e t in capitals: tromagnetic Field t, Ricions, C, tions, andoting. truments t ty  t for science to do.

    In 1875, eo matics or to p ily not to cury, ion and refinement, not revolution. Planck didn’t listen. udiedtical po ropy, a process at t of to ious young man.

    1In 1891 s and learned to  tant ropy been done already, in tance by a retiring sc Yale University namedJ. illard Gibbs.

    Gibbs is per brilliant person t most people  tot of near invisibility, ually t from t studying in Europe, icut. For  ten years at Yale  even botodrao tracted an average of sligudent asemester. ten  to folloe form of notationt many found incompre buried among ions  brilliance.

    In 1875–78, Gibbs produced a series of papers, collectively titledOn terogeneous Substances , t dazzlingly elucidated t is a measure of randomness or disorder in a system. Darrell Ebbing, in textbook GeneralCry, very usefully suggests t of tand in sequence from ace to king, can be said to be in its ordered state. S tate. Entropy is a   state is and of determining ticular outcomes o ionspublisable journal you o understand additional concepts sucies, lattice distances, and stoicric relations ts the general idea.

    nearly everytures, surfaces, solids, pions,electrocation, and osmosis,” to quote illiam  Gibbs did  apply simply to  and energy at t of large and noisy scale of team engine, but  and influential at tomic level of cions. Gibbs’s Equilibrium  for reasons t defy speculation Gibbs co publisions in transactions of ticut Academy of Arts and Sciences,a journal t managed to be obscure even in Connecticut, oo late.

    Undaunted—urned to otters.

    2e surnto t, but first  make a slig relevant!) detour toCleveland, Oitution t of early middle years named Albert Miced by  Eds t produced curious anddisturbing results t ions for muc followed.

    Mic actually intending to, anding belief in sometable, invisible, unately  to permeate tes, embraced by Need by nearly everyoneever since, tion of absolute centrality in nineteentury p traveled across tiness of space. It  and electromagnetism ypes of vibrations. Vibrations must occur in sometingdevotion to, an ete as 1909, t Britis J. J. ting:

    “t a fantastic creation of tive p is as essential to us aster it ty incontestably establis it didn’t exist. People, in s, taco ther.

    If you needed to illustrate teentury America as a land of opportunity,you could  Mico a family of poor Jeed States  and greo pay for college, raveled to ason, D.C.,and took to loitering by t door of te   Ulysses S. Grant utional. (It  age.) In tiated ot t Grant agreed to secure for  t Michelson learned his physics.

    ten years later, by no terested in trying to measure somet—a kind of s as tions ofNe as it pusen unlucky in life.   orld ar.  to look after ters er sy-five, an Allied bomb fell on everytime of accumulations. t in aconspiracy to assassinate ler and executed.

    respect to an observer depending on  or a, but no one  a o measure t occurred toMic for raveling to ismoving a, and  if you took careful enougs atopposite seasons and compared ligravel time betwo, you would have youranswer.

    Micalked Alexander Graor of telepoproviding to build an ingenious and sensitive instrument of Micerferometer, ed by t sidious measurements. te and exing, and o be suspended fora time to permit Mic compre by 1887 ts. t at all ists ed to find.

    As Caltecrop Kip S. tten: “t turned out to betions and at all seasons.” It   in t Neimeevery famous negative result in tory of p American so  not for tyyears. Meanysmell, in tific t.

    Remarkably, and despite ietury da an end,urrets and pinnacles to be added, a feo be carved,” in ter in Nature.

    In fact, of course, t to enter a century of science and anytand everytists  in a beicles and antiparticles, ence in spans of time t make nanoseconds look plodding and uneventful,ranspireness on scales far belos of imagining. e  toenter tum age, and t person to pusunateMax Planck.

    In 1900, noical p at ty of Berlin and at tadvanced age of forty-tum ted tenergy is not a continuous ter but comes in individualized packets,, and a good one. In t term it ion to ts in t itdemonstrated t lig be a er all. In term it ion for t  all events, t clue t t to change.

    But t—t ion, no access to a laboratory, and ter t of tional patent office in Bern, o be promoted to tecly been rejected.) Einstein, and in t one eventful year ted to Annalen derPo C. P. Snoest in tory of poelectric effect by means of Planck’s neum ticles in suspension (ion), and one outlining a special tivity.

    t s auture of ligomake television possible, among othings).

    3t atoms doindeed exist—a fact t e. the world.

    Einstein  grele ined tness to come. Famously  learn to speak until rical business failing, to Milan, butAlbert, by noeenager,  to Szerland to continue ion—trance exams on t try. In 1896 izensoavoid military conscription and entered tecitute on a four-year coursedesigned to c eac but not outstandingstudent.

    In 1900 ed and o contribute papers toAnnalen der P paper, on traum to 1904 atistical meco discover t tlyproductive J. illard Gibbs in Connecticut  atistical Mechanics of 1901.

    At time udent, a  of  up foradoption. Einstein never saer, s, in 1902, Einstein took a job ent office,  seven years.   so co distract  y in 1905.

    Called “On trodynamics of Moving Bodies,” it is one of t extraordinaryscientific papers ever publis ed as for  said. It notes or citations, contained almost no matics, made no mention of any  , and ackno one individual, a3Einstein ;for services to tical p; o  sixteen years, till1921, to receive te a long time, all t not all compared ected trino in 1957 but  il 1995, ty-eiger, ort Ruska, ron microscope in 1932 and received ury after t. Since Nobel Prizes are never ay can be asimportant a factor as ingenuity for prizewinners.

    colleague at tent office named Mic e C. P. Snoein“, unaided,  listening to to a surprisingly large extent, t is precisely w he had done.”

    ion, E =mc2, did not appear  came in a brief supplementt folloer. As you andsfor energy, m for mass, and c2for t squared.

    In simplest terms, ion says is t mass and energy have an equivalence.

    ted matter; matter is energy ing to times itself) is a truly enormous number, ion is saying is t t—a really —of energy bound upin every material thing.

    4You may not feel outstandingly robust, but if you are an average-sized adult you ain  frame no less tential energy—enougoexplode y very large oliberate it and really . Everytrapped. e’re just not very good at getting it out. Even a uranium bomb—tenergetic t—releases less t of t couldrelease if only we were more cunning.

    Among mucein’s tion ant streams of  melting a could do it by converting mass to energy extremely efficiently à laE =mc2.) Itexplained ars could burn for billions of years  racing tto.)At a stroke, in a simple formula, Einstein endos and astronomers  t ant and supreme. Notake it. It broug (no pun intended, exactly) tot of our understanding of ture of t incidentally, it alsosolved t clear t it didn’t exist. Einsteingave us a universe t didn’t need it.

    Ps as a rule are not overattentive to ts of Sent officeclerks, and so, despite tidings, Einstein’s papers attracted little notice.

    solved several of t mysteries of tein applied for a jobas a university lecturer and ed, and teacedt back to  of course t even come close to finis.

    Paul Valéry once asked Einstein if  a notebook to record ein looked at  genuine surprise. “O’s not necessary,” he replied.

    “It’s so seldom I  out t  tended to begood. Einstein’s next idea est t anyone est, according to Boorse, Motz, and eaver in tful ory of atomic science.

    4o be t is sometery, but David Bodanis suggests itprobably came from tin celeritas, meaning sness. t volume of tionary, compiled a decade before Einsteins to cricket, but makes no mention of it as a symbol for ligness.

    “As tion of a single mind,” te, “it is undoubtedly t intellectualac of y,” .

    In 1907, or so it imes been ten, Albert Einstein sao t gravity. Alas, like many good stories to beapocrypo Einstein ting in a cy occurred to him.

    Actually, o Einstein ion toty, since it  to set t one ty.   t itdealt ially unimpeded state. But acle sucy? It ion t of t decade and lead to tion in early1917 of a paper entitled “Cosmological Considerations on tivity.”

    tivity of 1905 ant piece of  as C. P. Snoein  t of it ing to  toget it,” e Sno is likely t ing for today.”

    itrified ein oo splendida figure to remain permanently obscure, and in 1919, t at once ivity developed a reputation for beingimpossible for an ordinary person to grasp. Matters  sout in imes decided to do a story, and—forreasons t can never fail to excite  t, oneo conduct terview.

    Crouc of  nearly everyting errors in  ion t Einstein o publis only t tion stuck anyway.

    Soon tivity ion—and tific establis, it must be said, did little to disturb th.

    asked tisronomer Sir Arton if it rue t and Einstein’s relativity ton considered deeply for a moment and replied: “I am trying to t, tivity  t it involved a lot of differentialequations, Lorentz transformations, and oted matics (t did—evenEinstein needed ), but t it  so tuitive.

    In essence ivity says is t space and time are not absolute, but relative to boto ter one moves ts become. e can never accelerate ourselves to t, and try (and faster orted ive to an outside observer.

    Almost at once popularizers of science tried to come up o make tsaccessible to a general audience. One of ttempts—commercially atleast—ivity by tician and prand Russell. Init, Russell employed an image t imes since. oenvision a train one  60 percent of t. tosomeone standing on a platform c pass, train o be only eig  too slos rain o be running at only four-fiftheir normal speed.

    rain ions. to train e normal. It form o do, you see, ion relative to t.

    t actually ime you move. Fly across ted States, and youep from tbely alter your oime and space. It ed t a baseball t a s o e. So ts of relativityare real and  sucoo small tomake tiniest detectable difference to us. But for ot,gravity, tself—tters of consequence.

    So if tivity seem  is only because  experience ts ofinteractions in normal life. o turn to Bodanis again, erotivity—for instance o sound. If you are in a park and someoneis playing annoying music, you kno if you move to a more distant spot ter. t’s not because ter, of course, but simply t your positionrelative to it o sometoo small or sluggiso duplicate t a boom box could seem to to produce tvolumes of music simultaneously might seem incredible.

    t cuitive of all ts in tivityis t time is part of space. Our instinct is to regard time as eternal, absolute,immutable—noturb its steady tick. In fact, according to Einstein, time is variableand ever c even  is bound up—“inextricably interconnected,” inStepime.

    Spacetime is usually explained by asking you to imagine somet but pliant—amattress, say, or a s of stretcing a , suc of terial on ting to stretcly. to t t a massive object sucime (terial): it stretc. No, it tries to go in a straigon’slaion, but as it nears t and t rollsdoably drao t. ty—a product of time.

    Every object t es a little depression in t it, is “timate sagging mattress.” Gravity on tcome—“not a ‘force’ but a byproduct of time,” in t Micy does not exist; s and stars is tortion of space andtime.”

    Of course ttress analogy can take us only so far because it doesn’tincorporate t of time. But take us only so far because it is sonearly impossible to envision a dimension comprising ts space to one part time, allinter all events, I t t for a young man staring out tent office in tal of Szerland.

    Among mucein’s general tivity suggested t tbe eitracting. But Einstein  a cosmologist, and ed t ternal. More or less reflexively, o ions sometant, erbalanced ts of gravity, serving as a kind of matical pause button. Bookson tory of science alein t it ually a fairlyappalling piece of science and .  “t blunder of my life.”

    Coincidentally, at about time t Einstein ant to  tory in Arizona, an astronomer ergalacticname of Vesto Slip from Indiana) aking spectrograpant stars and discovering t to be moving a static. tars Slip sakable signs of a Doppler s5—t distinctive stretc yee-yummm sound cars make as t on a racetrack. to lig is knoorum; approac ss to blue).

    Slip to notice t  and to realize its potential importancefor understanding tions of tunately no one muciced ory, as you  of an oddity to Percival Loian canals, post ofastronomical endeavor. Slipein’s tivity, and t.

    Glory instead o a large mass of ego named Eder Einstein, in a small Missouri toon, Illinois, a suburb of Cive, so life able, and Eds, too. rong and gifted ate, c, and immensely good-looking—“ to a fault,” in tion of illiam ian Doppler, an Austrian p, iced t in 1842. Briefly,  approacationary one its sound  as you  of anyt is beingpuso. tener as a kind of pinced sound (t and lengtco drop abruptly (the yummm).

    Adonis” in to s, ofit into ant acts of valor—rescuing droy across ttlefields of France, embarrassing s. It all seemed too good to be true. It was.

    For all s, erate liar.

    ttle odd, for inction t  times almost ludicrously golden. At a single rack meetin 1906, , s put, discus, anding eam—t is seven first places in onemeet—and came in t a state record for the highjump in Illinois.

    As a sc, and rouble gaining admission to studypronomy at ty of Cally, tment  Miced to be one of t R Oxford. tly turned urned toon in 1913 alking und accent—not quite Britis not quite not—t h him for life.

    ter claimed to  of tury practicinglaucky, in fact eacball coacedly attaining orate and passing briefly tice and almost certainly never  fired in anger.)In 1919, noy, o California and took up a position at tilson Observatory near Los Angeles. Sly, and more ttle unexpectedly,  outstanding astronomer of tietury.

    It is  to consider just tle  time. Astronomers today believe the visible universe.

    t’s a  o suppose. Ifgalaxies  orium—tonGarden, say, or t rop named Bruce Gregory uallycomputed t put o t o us ly one: tto be eit of tself or one of many distant, peripheral puffs of gas.

    rated  belief was.

    Over t decade, ackled t fundamental questions of t, and o ans is necessary to knoain galaxies are and  t is knoy). t gives t doesn’t tell us o begin  you need andard candles”—stars ed and used asbenco measure tness (and ive distance) of otars.

    o come along soon after an ingenious a St  a o do so. Leavitt  tory asa computer, as ters spent tudying pograpes ofstars and making computations— tle more t it  to real astronomy at tymucem, ain unexpectedbenefits: it meant t  minds available ed to  tracted little reflective attention, and it ensured t ion of tructure of t often eluded terparts.

    One er, Annie Jump Cannon, used itive acquaintance ars to devise a system of stellar classifications so practical t it is still in use today.

    Leavitt’s contribution  a type of star knoellation Cep first ified) pulsated ellar beat. Cepe rare, but at least one of to most of us. Polaris, tar, is a Cepheid.

    e no Cepars t  tronomers, and become redgiants. try of red giants is a little ion for ties of singly ionized oms, among quite a lot else), but putsimply it means t t produces a very rening and dimming. Leavitt’s genius o realize t by comparing tive magnitudes of Cep different points in t o eacandard candles”—a term sill in universal use. tive distances, not absolute distances,but even so it  time t anyone o measure thelarge-scale universe.

    (Just to put ts into perspective, it is pering t at time Leavittand Cannon al properties of tograpes, tronomer illiam o a first-class telescope as often as ed, cing insects.)Combining Leavitt’s cosmic yardstick o Slips, Eded points in space  a puffof distant gossamer in tellation kno a gas cloud at allbut a blaze of stars, a galaxy in its oleast nine -years aer—vastly vaster—tin for “clouds,” ed not just of t of lots of independent galaxies—“islanduniverses”—many of tant.

    tation, but urned to tion of  just er triking discovery. o measure tra of distant galaxies—tSlip ilson’s ne all t for our oer) are moving aance lyproportional: ter it was moving.

    truly startling. tly and evenly in all directions. Itdidn’t take a  of imagination to read back it musttarted from some central point. Far from being table, fixed, eternal voidt everyone   migherefore also have an end.

    teped, is t no one  on tatic universe, as so Neronomer since, self. t if stars ely in a static universe tolerably —certainly mucoo  for t a stroke.

    ter observer t immediately appreciate tions of  ofEinstein’s General tivity. te remarkable because, for one tein and  Micill one of t alert and esteemed scientists—accepted a position at Mount ilson to measure ty of ligrustyinterferometer, and must surely  least mentioned to y of Einstein’sto his own findings.

    At all events, o make tical ead, it to a Belgian priest-sc) named Georges Lema?tre tobring togetrands in ed t trical point, a “primeval atom,” o glory and  ever since. It  very neatly anticipated tion of t ime t Lema?tre seldom gets moretence or t ent discovery of cosmic background radiation by Penzias and ilsonat tenna in Neo move frominteresting idea to establisheory.

    Neitein  big story. t at time, bot as muco do.

    In 1936 tering style s.  last ed ein’s to a point any of about two hundred.

    attack in 1953. One last small oddity aed ery, o  sury later ts of tury’s greatest astronomer remainunkno look to telescope,launched in 1990 and named in his honor.


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