a history of science-2-第40部分

按键盘上方向键 ← 或 → 可快速上下翻页，按键盘上的 Enter 键可回到本书目录页，按键盘上方向键 ↑ 可回到本页顶部！
————未阅读完？加入书签已便下次继续阅读！


　Now；　subducting　the　diameter　of　the　hole　from　the　length　and　breadth　of　the　image；　there　remains　13　inches　the　length；　and　2　3/8　the　breadth；　comprehended　by　those　rays；　which；　passing　through　the　centre　of　the　said　hole；　which　that　breadth　subtended；　was　about　31'；　answerable　to　the　sun's　diameter；　but　the　angle　which　its　length　subtended　was　more　than　five　such　diameters；　namely　2　degrees　49'。　〃Having　made　these　observations；　I　first　computed　from　them　the　refractive　power　of　the　glass；　and　found　it　measured　by　the　ratio　of　the　sines　20　to　31。　And　then；　by　that　ratio；　I　computed　the　refractions　of　two　rays　flowing　from　opposite　parts　of　the　sun's　discus；　so　as　to　differ　31'　in　their　obliquity　of　incidence；　and　found　that　the　emergent　rays　should　have　comprehended　an　angle　of　31'；　as　they　did；　before　they　were　incident。　〃But　because　this　computation　was　founded　on　the　hypothesis　of　the　proportionality　of　the　sines　of　incidence　and　refraction；　which　though　by　my　own　experience　I　could　not　imagine　to　be　so　erroneous　as　to　make　that　angle　but　31'；　which　in　reality　was　2　degrees　49'；　yet　my　curiosity　caused　me　again　to　make　my　prism。　And　having　placed　it　at　my　window；　as　before；　I　observed　that　by　turning　it　a　little　about　its　axis　to　and　fro；　so　as　to　vary　its　obliquity　to　the　light　more　than　an　angle　of　4　degrees　or　5　degrees；　the　colors　were　not　thereby　sensibly　translated　from　their　place　on　the　wall；　and　consequently　by　that　variation　of　incidence　the　quantity　of　refraction　was　not　sensibly　varied。　By　this　experiment；　therefore；　as　well　as　by　the　former　computation；　it　was　evident　that　the　difference　of　the　incidence　of　rays　flowing　from　divers　parts　of　the　sun　could　not　make　them　after　decussation　diverge　at　a　sensibly　greater　angle　than　that　at　which　they　before　converged；　which　being；　at　most；　but　about　31'　or　32'；　there　still　remained　some　other　cause　to　be　found　out；　from　whence　it　could　be　2　degrees　49'。〃　All　this　caused　Newton　to　suspect　that　the　rays；　after　their　trajection　through　the　prism；　moved　in　curved　rather　than　in　straight　lines；　thus　tending　to　be　cast　upon　the　wall　at　different　places　according　to　the　amount　of　this　curve。　His　suspicions　were　increased；　also；　by　happening　to　recall　that　a　tennis…ball　sometimes　describes　such　a　curve　when　〃cut〃　by　a　tennis…racket　striking　the　ball　obliquely。　〃For　a　circular　as　well　as　a　progressive　motion　being　communicated　to　it　by　the　stroke；〃　he　says；　〃its　parts　on　that　side　where　the　motions　conspire　must　press　and　beat　the　contiguous　air　more　violently　than　on　the　other；　and　there　excite　a　reluctancy　and　reaction　of　the　air　proportionately　greater。　And　for　the　same　reason；　if　the　rays　of　light　should　possibly　be　globular　bodies；　and　by　their　oblique　passage　out　of　one　medium　into　another　acquire　a　circulating　motion；　they　ought　to　feel　the　greater　resistance　from　the　ambient　ether　on　that　side　where　the　motions　conspire；　and　thence　be　continually　bowed　to　the　other。　But　notwithstanding　this　plausible　ground　of　suspicion；　when　I　came　to　examine　it　I　could　observe　no　such　curvity　in　them。　And；　besides　（which　was　enough　for　my　purpose）；　I　observed　that　the　difference　'twixt　the　length　of　the　image　and　diameter　of　the　hole　through　which　the　light　was　transmitted　was　proportionable　to　their　distance。　〃The　gradual　removal　of　these　suspicions　at　length　led　me　to　the　experimentum　crucis；　which　was　this：　I　took　two　boards；　and；　placing　one　of　them　close　behind　the　prism　at　the　window；　so　that　the　light　must　pass　through　a　small　hole；　made　in　it　for　the　purpose；　and　fall　on　the　other　board；　which　I　placed　at　about　twelve　feet　distance；　having　first　made　a　small　hole　in　it　also；　for　some　of　the　incident　light　to　pass　through。　Then　I　placed　another　prism　behind　this　second　board；　so　that　the　light　trajected　through　both　the　boards　might　pass　through　that　also；　and　be　again　refracted　before　it　arrived　at　the　wall。　This　done；　I　took　the　first　prism　in　my　hands　and　turned　it　to　and　fro　slowly　about　its　axis；　so　much　as　to　make　the　several　parts　of　the　image；　cast　on　the　second　board；　successively　pass　through　the　hole　in　it；　that　I　might　observe　to　what　places　on　the　wall　the　second　prism　would　refract　them。　And　I　saw　by　the　variation　of　these　places　that　the　light；　tending　to　that　end　of　the　image　towards　which　the　refraction　of　the　first　prism　was　made；　did　in　the　second　prism　suffer　a　refraction　considerably　greater　than　the　light　tending　to　the　other　end。　And　so　the　true　cause　of　the　length　of　that　image　was　detected　to　be　no　other　than　that　LIGHT　consists　of　RAYS　DIFFERENTLY　REFRANGIBLE；　which；　without　any　respect　to　a　difference　in　their　incidence；　were；　according　to　their　degrees　of　refrangibility；　transmitted　towards　divers　parts　of　the　wall。〃＇1＇

THE　NATURE　OF　COLOR　Having　thus　proved　the　composition　of　light；　Newton　took　up　an　exhaustive　discussion　as　to　colors；　which　cannot　be　entered　into　at　length　here。　Some　of　his　remarks　on　the　subject　of　compound　colors；　however；　may　be　stated　in　part。　Newton's　views　are　of　particular　interest　in　this　connection；　since；　as　we　have　already　pointed　out；　the　question　as　to　what　constituted　color　could　not　be　agreed　upon　by　the　philosophers。　Some　held　that　color　was　an　integral　part　of　the　substance；　others　maintained　that　it　was　simply　a　reflection　from　the　surface；　and　no　scientific　explanation　had　been　generally　accepted。　Newton　concludes　his　paper　as　follows：　〃I　might　add　more　instances　of　this　nature；　but　I　shall　conclude　with　the　general　one　that　the　colors　of　all　natural　bodies　have　no　other　origin　than　this；　that　they　are　variously　qualified　to　reflect　one　sort　of　light　in　greater　plenty　than　another。　And　this　I　have　experimented　in　a　dark　room　by　illuminating　those　bodies　with　uncompounded　light　of　divers　colors。　For　by　that　means　any　body　may　be　made　to　appear　of　any　color。　They　have　there　no　appropriate　color；　but　ever　appear　of　the　color　of　the　light　cast　upon　them；　but　yet　with　this　difference；　that　they　are　most　brisk　and　vivid　in　the　light　of　their　own　daylight　color。　Minium　appeareth　there　of　any　color　indifferently　with　which　'tis　illustrated；　but　yet　most　luminous　in　red；　and　so　Bise　appeareth　indifferently　of　any　color　with　which　'tis　illustrated；　but　yet　most　luminous　in　blue。　And　therefore　Minium　reflecteth　rays　of　any　color；　but　most　copiously　those　indued　with　red；　and　consequently；　when　illustrated　with　daylightthat　is；　with　all　sorts　of　rays　promiscuously　blendedthose　qualified　with　red　shall　abound　most　in　the　reflected　light；　and　by　their　prevalence　cause　it　to　appear　of　that　color。　And　for　the　same　reason；　Bise；　reflecting　blue　most　copiously；　shall　appear　blue　by　the　excess　of　those　rays　in　its　reflected　light；　and　the　like　of　other　bodies。　And　that　this　is　the　entire　and　adequate　cause　of　their　colors　is　manifest；　because　they　have　no　power　to　change　or　alter　the　colors　of　any　sort　of　rays　incident　apart；　but　put　on　all　colors　indifferently　with　which　they　are　enlightened。〃＇2＇　This　epoch…making　paper　aroused　a　storm　of　opposition。　Some　of　Newton's　opponents　criticised　his　methods；　others　even　doubted　the　truth　of　his　experiments。　There　was　one　slight　mistake　in　Newton's　belief　that　all　prisms　would　give　a　spectrum　of　exactly　the　same　length；　and　it　was　some　time　before　he　corrected　this　error。　Meanwhile　he　patiently　met　and　answered　the　arguments　of　his　opponents　until　he　began　to　feel　that　patience　was　no　longer　a　virtue。　At　one　time　he　even　went　so　far　as　to　declare　that；　once　he　was　〃free　of　this　business；〃　he　would　renounce　scientific　research　forever；　at　least　in　a　public　way。　Fortunately　for　the　world；　however；　he　did　not　adhere　to　this　determination；　but　went　on　to　even　greater　discoverieswhich；　it　may　be　added；　involved　still　greater　controversies。　In　commenting　on　Newton's　discovery　of　the　composition　of　light；　Voltaire　said：　〃Sir　Isaac　Newton　has　demonstrated　to　the　eye；　by　the　bare　assistance　of　a　prism；　that　light　is　a　composition　of　colored　rays；　which；　being　united；　form　white　color。　A　single　ray　is　by　him　divided　into　seven；　which　all　fall　upon　a　piece　of　linen　or　a　sheet　of　white　paper；　in　their　order　one　above　the　other；　and　at　equal　distances。　The　first　is　red；　the　second　orange；　the　third　yellow；　the　fourth　green；　the　fifth　blue；　the　sixth　indigo；　the　seventh　a　violet　purple。　Each　of　these　rays　transmitted　afterwards　by　a　hundred　other　prisms　will　never　change　the　color　it　bears；　in　like　manner　as　gold；　when　completely　purged　from　its　dross；　will　never　change　afterwards　in　the　crucible。〃＇3＇

XII。　NEWTON　AND　THE　LAW　OF　GRAVITATION　We　come　now　to　the　story　of　what　is　by　common　consent　the　greatest　of　scientific　achievements。　The　law　of　universal　gravitation　is　the　most　far…reaching　principle　as　yet　discovered。　It　has　application　equally　to　the　minutest　particle　of　matter　and　to　the　most　distant　suns　in　the　universe；　yet　it　is　amazing　in　its　very　simplicity。　As　usually　phrased；　the　law　is　this：　That　every　particle　of　matter　in　the　universe　attracts　every　other　particle　with　a　force　that　varies　directly　with　the　mass　of　the　particles　and　inversely　as　the　squares　of　their　mutual　distance。　Newton　did　not　vault　at　once　to　the　full　expression　of　this　law；　though　he　had　formulated　it　fully　before　he　gave　t