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f measurements had been taken throughout the world。 rather than restate everyone; scientists decided to keep the inaccurate constant。 鈥渢hus;鈥潯im flannery notes; 鈥渆veryraw radiocarbon date you read today is given as too young by around 3 percent。鈥潯heproblems didn鈥檛 quite stop there。 it was also quickly discovered that carbon…14 samples can beeasily contaminated with carbon from other sources鈥攁 tiny scrap of vegetable matter; forinstance; that has been collected with the sample and not noticed。 for younger samples鈥攖hose under twenty thousand years or so鈥攕light contamination does not always matter somuch; but for older samples it can be a serious problem because so few remaining atoms arebeing counted。 in the first instance; to borrow from flannery; it is like miscounting by a dollarwhen counting to a thousand; in the second it is more like miscounting by a dollar when youhave only two dollars to count。
libby鈥檚 method was also based on the assumption that the amount of carbon…14 in theatmosphere; and the rate at which it has been absorbed by living things; has been consistentthroughout history。 in fact it hasn鈥檛 been。 we now know that the volume of atmosphericcarbon…14 varies depending on how well or not earth鈥檚 magnetism is deflecting cosmic rays;and that that can vary significantly over time。 this means that some carbon…14 dates are more1if you have ever wondered how the atoms determine which 50 percent will die and which 50 percent willsurvive for the next session; the answer is that the half…life is really just a statistical convenience…a kind ofactuarial table for elemental things。 imagine you had a sample of material with a half…life of 30 seconds。 it isntthat every atom in the sample will exist for exactly 30 seconds or 60 seconds or 90 seconds or some other tidilyordained period。 each atom will in fact survive for an entirely random length of time that has nothing to do withmultiples of 30; it might last until two seconds from now or it might oscillate away for years or decades orcenturies to e。 no one can say。 but what we can say is that for the sample as a whole the rate ofdisappearance will be such that half the atoms will disappear every 30 seconds。 its an average rate; in otherwords; and you can apply it to any large sampling。 someone once worked out; for instance; that dimes have ahalf…life of about 30 years。
dubious than others。 this is particularly so with dates just around the time that people firstcame to the americas; which is one of the reasons the matter is so perennially in dispute。
finally; and perhaps a little unexpectedly; readings can be thrown out by seeminglyunrelated external factors鈥攕uch as the diets of those whose bones are being tested。 onerecent case involved the long…running debate over whether syphilis originated in the newworld or the old。 archeologists in hull; in the north of england; found that monks in amonastery graveyard had suffered from syphilis; but the initial conclusion that the monks haddone so before columbus鈥檚 voyage was cast into doubt by the realization that they had eaten alot of fish; which could make their bones appear to be older than in fact they were。 the monksmay well have had syphilis; but how it got to them; and when; remain tantalizinglyunresolved。
because of the accumulated shortings of carbon…14; scientists devised other methods ofdating ancient materials; among them thermoluminesence; which measures electrons trappedin clays; and electron spin resonance; which involves bombarding a sample withelectromagnetic waves and measuring the vibrations of the electrons。 but even the best ofthese could not date anything older than about 200;000 years; and they couldn鈥檛 date inorganicmaterials like rocks at all; which is of course what you need if you wish to determine the ageof your planet。
the problems of dating rocks were such that at one point almost everyone in the world hadgiven up on them。 had it not been for a determined english professor named arthur holmes;the quest might well have fallen into abeyance altogether。
holmes was heroic as much for the obstacles he overcame as for the results he achieved。
by the 1920s; when holmes was in the prime of his career; geology had slipped out offashion鈥攑hysics was the new excitement of the age鈥攁nd had bee severely underfunded;particularly in britain; its spiritual birthplace。 at durham university; holmes was for manyyears the entire geology department。 often he had to borrow or patch together equipment inorder to pursue his radiometric dating of rocks。 at one point; his calculations were effectivelyheld up for a year while he waited for the university to provide him with a simple addingmachine。 occasionally; he had to drop out of academic life altogether to earn enough tosupport his family鈥攆or a time he ran a curio shop in newcastle upon tyne鈥攁nd sometimeshe could not even afford the 锟5 annual membership fee for the geological society。
the technique holmes used in his work was theoretically straightforward and arose directlyfrom the process; first observed by ernest rutherford in 1904; in which some atoms decayfrom one element into another at a rate predictable enough that you can use them as clocks。 ifyou know how long it takes for potassium…40 to bee argon…40; and you measure theamounts of each in a sample; you can work out how old a material is。 holmes鈥檚 contributionwas to measure the decay rate of uranium into lead to calculate the age of rocks; and thus鈥攈ehoped鈥攐f the earth。
but there were many technical difficulties to overe。 holmes also needed鈥攐r at leastwould very much have appreciated鈥攕ophisticated gadgetry of a sort that could make veryfine measurements from tiny samples; and as we have seen it was all he could do to get asimple adding machine。 so it was quite an achievement when in 1946 he was able toannounce with some confidence that the earth was at least three billion years old and possiblyrather more。 unfortunately; he now met yet another formidable impediment to acceptance: theconservativeness of his fellow scientists。 although happy to praise his methodology; many maintained that he had found not the age of the earth but merely the age of the materials fromwhich the earth had been formed。
it was just at this time that harrison brown of the university of chicago developed a newmethod for counting lead isotopes in igneous rocks (which is to say those that were createdthrough heating; as opposed to the laying down of sediments)。 realizing that the work wouldbe exceedingly tedious; he assigned it to young clair patterson as his dissertation project。
famously he promised patterson that determining the age of the earth with his new methodwould be 鈥渄uck soup。鈥潯n fact; it would take years。
patterson began work on the project in 1948。 pared with thomas midgley鈥檚 colorfulcontributions to the march of progress; patterson鈥檚 discovery of the age of the earth feelsmore than a touch anticlimactic。 for seven years; first at the university of chicago and then atthe california institute of technology (where he moved in 1952); he worked in a sterile lab;making very precise measurements of the lead/uranium ratios in carefully selected samples ofold rock。
the problem with measuring the age of the earth was that you needed rocks that wereextremely ancient; containing lead… and uranium…bearing crystals that were about as old as theplanet itself鈥攁nything much younger would obviously give you misleadingly youthfuldates鈥攂ut really ancient rocks are only rarely found on earth。 in the late 1940s no onealtogether understood why this should be。 indeed; and rather extraordinarily; we would bewell into the space age before anyone could plausibly account for where all the earth鈥檚 oldrocks went。 (the answer was plate tectonics; which we shall of course get to。) patterson;meantime; was left to try to make sense of things with very limited materials。 eventually; andingeniously; it occurred to him that he could circumvent the rock shortage by using rocksfrom beyond earth。 he turned to meteorites。
the assumption he made鈥攔ather a large one; but correct as it turned out鈥攚as that manymeteorites are essentially leftover building materials from the early days of the solar system;and thus have managed to preserve a more or less pristine interior chemistry。 measure the ageof these wandering rocks and you would have the age also (near enough) of the earth。
as always; however; nothing was quite as straightforward as such a breezy descriptionmakes it sound。 meteorites are not abundant and meteoritic samples not especially easy to gethold of。 moreover; brown鈥檚 measurement technique proved finicky in the extreme andneeded much refinement。 above all; there was the problem that patterson鈥檚 samples werecontinuously and unaccountably contaminated with large doses of atmospheric lead wheneverthey were exposed to air。 it was this that eventually led him to create a sterile laboratory鈥攖heworld鈥檚 first; according to at least one account。
it took patterson seven years of patient work just to assemble suitable samples for finaltesting。 in the spring of 1953 he traveled to the argonne national laboratory in illinois;where he was granted time on a late…model mass