4-manifold - Knowledge

1127: 39:. In dimension four, in marked contrast with lower dimensions, topological and smooth manifolds are quite different. There exist some topological 4-manifolds which admit no smooth structure, and even if there exists a smooth structure, it need not be unique (i.e. there are smooth 4-manifolds which are 552:-dimensional embeddings to embeddings of 2-disks. But this is not a reduction when the dimension is 4: the 2-disks themselves are middle-dimensional, so trying to embed them encounters exactly the same problems they are supposed to solve. This is the phenomenon that separates dimension 4 from others." 255:

to tell whether two finitely presented groups are isomorphic (even if one is known to be trivial), there can be no algorithm to tell if two 4-manifolds have the same fundamental group. This is one reason why much of the work on 4-manifolds just considers the simply connected case: the general case of

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it is easy to construct a (smooth) compact 4-manifold with it as its fundamental group. (More specifically, for any finitely presented group, one constructs a manifold with the given fundamental group, such that two manifolds in this family are homeomorphic if and only if the fundamental groups are

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to show that the smooth structures are different. Their results suggest that any classification of simply connected smooth 4-manifolds will be very complicated. There are currently no plausible conjectures about what this classification might look like. (Some early conjectures that all simply

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In contrast, very little is known about the second question of classifying the smooth structures on a smoothable 4-manifold; in fact, there is not a single smoothable 4-manifold where the answer is fully known. Donaldson showed that there are some simply connected compact 4-manifolds, such as

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There are several fundamental theorems about manifolds that can be proved by low-dimensional methods in dimensions at most 3, and by completely different high-dimensional methods in dimension at least 5, but which are false in dimension 4. Here are some examples:

188:, there are two manifolds depending on the Kirby–Siebenmann invariant: one is 2-dimensional complex projective space, and the other is a fake projective space, with the same homotopy type but not homeomorphic (and with no smooth structure). 456:

In any dimension other than 4, a compact topological manifold has only a finite number of essentially distinct PL or smooth structures. In dimension 4, compact manifolds can have a countably-infinite number of non-diffeomorphic smooth

453:) vanishes. In dimension 3 and lower, every topological manifold admits an essentially unique PL structure. In dimension 4 there are many examples with vanishing Kirby–Siebenmann invariant but no PL structure. 415:. Fintushel and Stern showed how to use surgery to construct large numbers of different smooth structures (indexed by arbitrary integral polynomials) on many different manifolds, using 195:

starts to increase extremely rapidly with the rank, so there are huge numbers of corresponding simply connected topological 4-manifolds (most of which seem to be of almost no interest).

127: 395:=7. See for recent (as of 2019) progress in this area.) The "11/8 conjecture" states that smooth structures do not exist if the dimension is less than 11/8 times the |signature|. 441:

provides the obstruction to the existence of a PL structure; in other words a compact topological manifold has a PL structure if and only if its Kirby–Siebenmann invariant in H(

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If the form is indefinite and even we may as well assume that it is of nonpositive signature by changing orientations if necessary, in which case it is isomorphic to a sum of

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A major open problem in the theory of smooth 4-manifolds is to classify the simply connected compact ones. As the topological ones are known, this breaks up into two parts:

243:. If the fundamental group is too large (for example, a free group on 2 generators), then Freedman's techniques seem to fail and very little is known about such manifolds. 241: 219: 186: 494:

has been proved for all dimensions other than 4. In 4 dimensions, the PL Poincaré conjecture is equivalent to the smooth Poincaré conjecture, and its truth is unknown.

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holds for cobordisms provided that neither the cobordism nor its boundary has dimension 4. It can fail if the boundary of the cobordism has dimension 4 (as shown by

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and Kirby–Siebenmann invariant can arise, except that if the form is even, then the Kirby–Siebenmann invariant must be the signature/8 (mod 2).

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There is an almost complete answer to the first problem asking which simply connected compact 4-manifolds have smooth structures. First, the

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showed that there are topological manifolds in each dimension greater than or equal to 5, that are not homeomorphic to a simplicial complex.

720: 623: 653:; Lin, Jianfeng; Shi, XiaoLin; Xu, Zhouli (2019), "Intersection Forms of Spin 4-Manifolds and the Pin(2)-Equivariant Mahowald Invariant", 404:, with a countably infinite number of different smooth structures. There are an uncountable number of different smooth structures on 340:(so that the dimension is at least 11/8 times the |signature|) then there is a smooth structure, given by taking a connected sum of 199:

Freedman's classification can be extended to some cases when the fundamental group is not too complicated; for example, when it is

545: 375:). This leaves a small gap between 10/8 and 11/8 where the answer is mostly unknown. (The smallest case not covered above has 1002: 383:=5, but this has also been ruled out, so the smallest lattice for which the answer is not currently known is the lattice II 581: 548:

uses an isotopy across an embedded 2-disk to simplify these intersections. Roughly speaking this reduces the study of

1152: 1110: 939: 859: 826: 885: 788: 1084: 97: 438: 130: 79: 1094: 1027: 371:(so the dimension is at most 10/8 times the |signature|) then Furuta proved that no smooth structure exists ( 1131: 512:

decomposition. Manifolds of dimension 4 have a handlebody decomposition if and only if they are smoothable.

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Surgery and Geometric Topology: Proceedings of a conference held at Josai University, Sakado, Sept. 1996

931: 287: 265: 192: 247: 224: 221:, there is a classification similar to the one above using Hermitian forms over the group ring of 202: 169: 846:, Mathematical Sciences Research Institute Publications, vol. 1, Springer-Verlag, New York, 302:) gives a complete answer: there is a smooth structure if and only if the form is diagonalizable. 764:

Quinn, F. (1996). "Problems in low-dimensional topology". In Ranicki, A.; Yamasaki, M. (eds.).

505:). If the cobordism has dimension 4, then it is unknown whether the h-cobordism theorem holds. 295: 483: 145: 718:(2016). "Pin(2)-equivariant Seiberg–Witten Floer homology and the Triangulation Conjecture". 1157: 1042:

Kirby, R. C.; Taylor, L. R. (1998). "A survey of 4-manifolds through the eyes of surgery".

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is known in all dimensions other than 4 (it is usually false in dimensions at least 7; see

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can be smoothed in an essentially unique way, so in particular the theory of 4 dimensional

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There are compact 4-dimensional topological manifolds that are not homeomorphic to any

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In the special case when the form is 0, this implies the 4-dimensional topological

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connected smooth 4-manifolds might be connected sums of algebraic surfaces, or

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will usually intersect themselves and each other in isolated points. The

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type of the manifold only depends on this intersection form, and on a

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Furuta, Mikio (2001), "Monopole Equation and the 11/8-Conjecture",

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Classify the different smooth structures on a smoothable manifold.

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is much the same as the theory of 4 dimensional smooth manifolds.

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If the form is indefinite and odd there is a smooth structure.

424:, possibly with orientations reversed, have been disproved.) 821:, Oxford Mathematical Monographs, Oxford: Clarendon Press, 472:

has an uncountable number of exotic smooth structures; see

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A topological manifold of dimension not equal to 4 has a

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on the middle dimensional homology. A famous theorem of

540:-dimensional submanifolds of a manifold of dimension 2 227: 205: 172: 100: 427: 191:

When the rank of the form is greater than about 28,

1105:, Providence, R.I.: American Mathematical Society, 809: 923: 256:many problems is already known to be intractable. 235: 213: 180: 121: 1139: 193:the number of positive definite unimodular forms 50:4-manifolds are important in physics because in 649: 834: 676:"Irrationality and the h-cobordism conjecture" 1018: 914: 616:"Differential topology forty-six years later" 1059:"Four-dimensional topology: an introduction" 881:"The topology of four-dimensional manifolds" 624:Notices of the American Mathematical Society 1041: 528:Failure of the Whitney trick in dimension 4 279:Which topological manifolds are smoothable? 1056: 264:For manifolds of dimension at most 6, any 122:{\displaystyle \mathbb {Z} /2\mathbb {Z} } 65: 1074: 1047: 961: 898: 801: 782: 763: 732: 714: 691: 673: 658: 299: 229: 207: 174: 133:, and moreover that every combination of 115: 102: 1026:, Grad. Studies in Math., vol. 20, 875: 87: 1100: 1082: 78:compact 4-manifold only depends on the 1140: 947: 610: 372: 977: 468:can have an exotic smooth structure. 294:If the intersection form is definite 259: 159:, a manifold not homeomorphic to any 155:, this gives a manifold called the 13: 14: 1169: 1119: 428:Special phenomena in 4 dimensions 1125: 886:Journal of Differential Geometry 789:Journal of Differential Geometry 437:In dimensions other than 4, the 1076:10.1090/S0273-0979-1980-14687-X 582:Enriques–Kodaira classification 490:). The Poincaré conjecture for 266:piecewise linear (PL) structure 1024:4-Manifolds and Kirby Calculus 1022:; Stipsicz, András I. (1999), 819:The Geometry of Four-Manifolds 757: 708: 667: 643: 604: 1: 1103:The wild world of 4-manifolds 1028:American Mathematical Society 950:Mathematical Research Letters 844:Instantons and four-manifolds 597: 1085:"Four-dimensional manifolds" 674:Donaldson, Simon K. (1987). 236:{\displaystyle \mathbb {Z} } 214:{\displaystyle \mathbb {Z} } 181:{\displaystyle \mathbb {Z} } 7: 1090:Encyclopedia of Mathematics 983:The topology of 4-manifolds 555: 482:The solution to the smooth 460:Four is the only dimension 10: 1174: 932:Princeton University Press 439:Kirby–Siebenmann invariant 131:Kirby–Siebenmann invariant 963:10.4310/mrl.2001.v8.n3.a5 877:Freedman, Michael Hartley 852:10.1007/978-1-4684-0258-2 417:Seiberg–Witten invariants 1153:Low-dimensional topology 1083:Matveev, S. V. (2001) , 248:finitely presented group 1057:Mandelbaum, R. (1980), 926:Topology of 4-manifolds 66:Topological 4-manifolds 35:is a 4-manifold with a 1063:Bull. Amer. Math. Soc. 900:10.4310/jdg/1214437136 803:10.4310/jdg/1214437665 693:10.4310/jdg/1214441179 288:Kirby–Siebenmann class 251:isomorphic.) As there 237: 215: 182: 123: 238: 216: 183: 129:invariant called the 124: 1134:at Wikimedia Commons 1101:Scorpan, A. (2005), 916:Freedman, Michael H. 815:Kronheimer, Peter B. 680:J. Differential Geom 422:symplectic manifolds 351: − 3 225: 203: 170: 98: 84:Michael Freedman 29:topological manifold 930:, Princeton, N.J.: 840:Uhlenbeck, Karen K. 811:Donaldson, Simon K. 784:Donaldson, Simon K. 721:J. Amer. Math. Soc. 651:Hopkins, Michael J. 499:h-cobordism theorem 484:Poincaré conjecture 296:Donaldson's theorem 253:can be no algorithm 151:If the form is the 146:Poincaré conjecture 90:) implies that the 27:is a 4-dimensional 1148:Geometric topology 995:10.1007/BFb0089031 773:. pp. 97–104. 716:Manolescu, Ciprian 517:simplicial complex 402:Dolgachev surfaces 260:Smooth 4-manifolds 233: 211: 178: 161:simplicial complex 119: 52:General Relativity 16:Mathematical space 1130:Media related to 1004:978-3-540-51148-9 567:Algebraic surface 521:Ciprian Manolescu 80:intersection form 60:pseudo-Riemannian 33:smooth 4-manifold 1165: 1129: 1115: 1097: 1079: 1078: 1053: 1051: 1038: 1020:Gompf, Robert E. 1015: 979:Kirby, Robion C. 974: 965: 944: 929: 911: 902: 872: 836:Freed, Daniel S. 831: 806: 805: 775: 774: 772: 761: 755: 754: 736: 712: 706: 705: 695: 671: 665: 663: 662: 647: 641: 639: 620: 608: 387:of rank 62 with 242: 240: 239: 234: 232: 220: 218: 217: 212: 210: 187: 185: 184: 179: 177: 128: 126: 125: 120: 118: 110: 105: 76:simply connected 58:is modeled as a 37:smooth structure 1173: 1172: 1168: 1167: 1166: 1164: 1163: 1162: 1138: 1137: 1122: 1113: 1049:math.GT/9803101 1005: 987:Springer-Verlag 942: 862: 829: 779: 778: 770: 762: 758: 743:10.1090/jams829 713: 709: 672: 668: 648: 644: 618: 609: 605: 600: 558: 546:"Whitney trick" 530: 430: 386: 323: 315: 262: 228: 226: 223: 222: 206: 204: 201: 200: 173: 171: 168: 167: 166:If the form is 135:unimodular form 114: 106: 101: 99: 96: 95: 68: 17: 12: 11: 5: 1171: 1161: 1160: 1155: 1150: 1136: 1135: 1121: 1120:External links 1118: 1117: 1116: 1111: 1098: 1080: 1054: 1039: 1016: 1003: 975: 945: 940: 912: 893:(3): 357–453, 873: 860: 832: 827: 807: 796:(2): 279–315, 777: 776: 756: 707: 686:(1): 141–168. 666: 642: 631:(6): 804–809, 602: 601: 599: 596: 595: 594: 589: 584: 579: 574: 569: 564: 562:Kirby calculus 557: 554: 529: 526: 525: 524: 513: 506: 495: 480: 458: 454: 429: 426: 397: 396: 384: 324:(−1) for some 321: 313: 306: 303: 300:Donaldson 1983 284: 283: 280: 261: 258: 231: 209: 197: 196: 189: 176: 164: 149: 117: 113: 109: 104: 67: 64: 15: 9: 6: 4: 3: 2: 1170: 1159: 1156: 1154: 1151: 1149: 1146: 1145: 1143: 1133: 1128: 1124: 1123: 1114: 1112:0-8218-3749-4 1108: 1104: 1099: 1096: 1092: 1091: 1086: 1081: 1077: 1072: 1068: 1064: 1060: 1055: 1050: 1045: 1040: 1037: 1033: 1029: 1025: 1021: 1017: 1014: 1010: 1006: 1000: 996: 992: 988: 984: 980: 976: 973: 969: 964: 959: 955: 951: 946: 943: 941:0-691-08577-3 937: 933: 928: 927: 921: 917: 913: 910: 906: 901: 896: 892: 888: 887: 882: 878: 874: 871: 867: 863: 861:0-387-96036-8 857: 853: 849: 845: 841: 837: 833: 830: 828:0-19-850269-9 824: 820: 816: 812: 808: 804: 799: 795: 791: 790: 785: 781: 780: 769: 768: 760: 752: 748: 744: 740: 735: 730: 726: 723: 722: 717: 711: 703: 699: 694: 689: 685: 681: 677: 670: 661: 656: 652: 646: 638: 634: 630: 626: 625: 617: 613: 607: 603: 593: 590: 588: 587:Casson handle 585: 583: 580: 578: 575: 573: 570: 568: 565: 563: 560: 559: 553: 551: 547: 543: 539: 535: 532:According to 522: 518: 514: 511: 507: 504: 500: 496: 493: 489: 488:exotic sphere 485: 481: 478: 477: 471: 467: 463: 459: 455: 452: 448: 444: 440: 436: 435: 434: 425: 423: 418: 414: 413: 407: 403: 394: 390: 382: 378: 374: 370: 366: 362: 358: 354: 350: 346: 343: 339: 335: 331: 327: 319: 311: 307: 304: 301: 297: 293: 292: 291: 290:must vanish. 289: 281: 278: 277: 276: 273: 271: 267: 257: 254: 249: 244: 194: 190: 165: 162: 158: 154: 150: 147: 143: 142: 141: 138: 136: 132: 111: 107: 93: 92:homeomorphism 89: 85: 81: 77: 73: 72:homotopy type 63: 61: 57: 53: 48: 46: 45:diffeomorphic 42: 38: 34: 30: 26: 22: 1102: 1088: 1066: 1062: 1023: 982: 953: 949: 925: 920:Quinn, Frank 890: 884: 843: 818: 793: 787: 766: 759: 724: 719: 710: 683: 679: 669: 645: 628: 622: 612:Milnor, John 606: 592:Akbulut cork 549: 541: 537: 531: 492:PL manifolds 475: 469: 465: 461: 450: 446: 442: 431: 411: 405: 398: 392: 388: 380: 376: 368: 364: 360: 356: 352: 348: 341: 337: 333: 329: 325: 317: 312:copies of II 309: 285: 274: 270:PL manifolds 263: 245: 198: 139: 69: 62:4-manifold. 49: 41:homeomorphic 32: 24: 18: 1158:4-manifolds 1132:4-manifolds 956:: 279–291, 727:: 147–176. 534:Frank Quinn 497:The smooth 457:structures. 373:Furuta 2001 345:K3 surfaces 320:copies of E 157:E8 manifold 21:mathematics 1142:Categories 660:1812.04052 598:References 577:5-manifold 572:3-manifold 510:handlebody 464:for which 355:copies of 153:E8 lattice 140:Examples: 25:4-manifold 1095:EMS Press 1069:: 1–159, 734:1303.2354 503:Donaldson 56:spacetime 981:(1989), 922:(1990), 879:(1982), 842:(1984), 817:(1997), 751:16403004 614:(2011), 556:See also 246:For any 43:but not 1036:1707327 1013:1001966 972:1839478 909:0679066 870:0757358 702:0892034 637:2839925 536:, "Two 474:exotic 410:exotic 391:=3 and 379:=2 and 86: ( 1109: 1034: 1011: 1001: 970: 938: 907: 868: 858: 825: 749: 700: 635: 408:; see 1044:arXiv 771:(PDF) 747:S2CID 729:arXiv 655:arXiv 619:(PDF) 363:. 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