Algebraic topology

Algebraic topology is a branch of mathematics that uses tools from abstract algebra to study topological spaces The basic goal is to find algebraic invariants that classify topological spaces up to homeomorphism though usually most classify up to homotopy equivalence A torus one of the most frequently studied objects in algebraic topology Although algebraic topology primarily uses algebra to study topological problems using topology to solve algebraic problems is sometimes also possible Algebraic topology for example allows for a convenient proof that any subgroup of a free group is again a free group Main branchesBelow are some of the main areas studied in algebraic topology Homotopy groups In mathematics homotopy groups are used in algebraic topology to classify topological spaces The first and simplest homotopy group is the fundamental group which records information about loops in a space Intuitively homotopy groups record information about the basic shape or holes of a topological space Homology In algebraic topology and abstract algebra homology in part from Greek ὁmos homos identical is a certain general procedure to associate a sequence of abelian groups or modules with a given mathematical object such as a topological space or a group Cohomology In homology theory and algebraic topology cohomology is a general term for a sequence of abelian groups defined from a cochain complex That is cohomology is defined as the abstract study of cochains cocycles and coboundaries Cohomology can be viewed as a method of assigning algebraic invariants to a topological space that has a more refined algebraic structure than does homology Cohomology arises from the algebraic dualization of the construction of homology In less abstract language cochains in the fundamental sense should assign quantities to the chains of homology theory Manifolds A manifold is a topological space that near each point resembles Euclidean space Examples include the plane the sphere and the torus which can all be realized in three dimensions but also the Klein bottle and real projective plane which cannot be embedded in three dimensions but can be embedded in four dimensions Typically results in algebraic topology focus on global non differentiable aspects of manifolds for example Poincare duality Knot theory Knot theory is the study of mathematical knots While inspired by knots that appear in daily life in shoelaces and rope a mathematician s knot differs in that the ends are joined so that it cannot be undone In precise mathematical language a knot is an embedding of a circle in three dimensional Euclidean space R3 displaystyle mathbb R 3 Two mathematical knots are equivalent if one can be transformed into the other via a deformation of R3 displaystyle mathbb R 3 upon itself known as an ambient isotopy these transformations correspond to manipulations of a knotted string that do not involve cutting the string or passing the string through itself Complexes A simplicial 3 complex A simplicial complex is a topological space of a certain kind constructed by gluing together points line segments triangles and their n dimensional counterparts see illustration Simplicial complexes should not be confused with the more abstract notion of a simplicial set appearing in modern simplicial homotopy theory The purely combinatorial counterpart to a simplicial complex is an abstract simplicial complex A CW complex is a type of topological space introduced by J H C Whitehead to meet the needs of homotopy theory This class of spaces is broader and has some better categorical properties than simplicial complexes but still retains a combinatorial nature that allows for computation often with a much smaller complex Method of algebraic invariantsAn older name for the subject was combinatorial topology implying an emphasis on how a space X was constructed from simpler ones the modern standard tool for such construction is the CW complex In the 1920s and 1930s there was growing emphasis on investigating topological spaces by finding correspondences from them to algebraic groups which led to the change of name to algebraic topology The combinatorial topology name is still sometimes used to emphasize an algorithmic approach based on decomposition of spaces In the algebraic approach one finds a correspondence between spaces and groups that respects the relation of homeomorphism or more general homotopy of spaces This allows one to recast statements about topological spaces into statements about groups which have a great deal of manageable structure often making these statements easier to prove Two major ways in which this can be done are through fundamental groups or more generally homotopy theory and through homology and cohomology groups The fundamental groups give us basic information about the structure of a topological space but they are often nonabelian and can be difficult to work with The fundamental group of a finite simplicial complex does have a finite presentation Homology and cohomology groups on the other hand are abelian and in many important cases finitely generated Finitely generated abelian groups are completely classified and are particularly easy to work with Setting in category theoryIn general all constructions of algebraic topology are functorial the notions of category functor and natural transformation originated here Fundamental groups and homology and cohomology groups are not only invariants of the underlying topological space in the sense that two topological spaces which are homeomorphic have the same associated groups but their associated morphisms also correspond a continuous mapping of spaces induces a group homomorphism on the associated groups and these homomorphisms can be used to show non existence or much more deeply existence of mappings One of the first mathematicians to work with different types of cohomology was Georges de Rham One can use the differential structure of smooth manifolds via de Rham cohomology or Cech or sheaf cohomology to investigate the solvability of differential equations defined on the manifold in question De Rham showed that all of these approaches were interrelated and that for a closed oriented manifold the Betti numbers derived through simplicial homology were the same Betti numbers as those derived through de Rham cohomology This was extended in the 1950s when Samuel Eilenberg and Norman Steenrod generalized this approach They defined homology and cohomology as functors equipped with natural transformations subject to certain axioms e g a weak equivalence of spaces passes to an isomorphism of homology groups verified that all existing co homology theories satisfied these axioms and then proved that such an axiomatization uniquely characterized the theory ApplicationsClassic applications of algebraic topology include The Brouwer fixed point theorem every continuous map from the unit n disk to itself has a fixed point The free rank of the nth homology group of a simplicial complex is the nth Betti number which allows one to calculate the Euler Poincare characteristic One can use the differential structure of smooth manifolds via de Rham cohomology or Cech or sheaf cohomology to investigate the solvability of differential equations defined on the manifold in question A manifold is orientable when the top dimensional integral homology group is the integers and is non orientable when it is 0 The n sphere admits a nowhere vanishing continuous unit vector field if and only if n is odd For n 2 this is sometimes called the hairy ball theorem The Borsuk Ulam theorem any continuous map from the n sphere to Euclidean n space identifies at least one pair of antipodal points Any subgroup of a free group is free This result is quite interesting because the statement is purely algebraic yet the simplest known proof is topological Namely any free group G may be realized as the fundamental group of a graph X The main theorem on covering spaces tells us that every subgroup H of G is the fundamental group of some covering space Y of X but every such Y is again a graph Therefore its fundamental group H is free On the other hand this type of application is also handled more simply by the use of covering morphisms of groupoids and that technique has yielded subgroup theorems not yet proved by methods of algebraic topology see Higgins 1971 Topological combinatorics Notable peopleFrank Adams Michael Atiyah Enrico Betti Armand Borel Karol Borsuk Raoul Bott Luitzen Egbertus Jan Brouwer William Browder Ronald Brown Henri Cartan Shiing Shen Chern Albrecht Dold Charles Ehresmann Samuel Eilenberg Hans Freudenthal Peter Freyd Pierre Gabriel Israel Gelfand Alexander Grothendieck Allen Hatcher Friedrich Hirzebruch Heinz Hopf Michael J Hopkins Witold Hurewicz Egbert van Kampen Daniel Kan Hermann Kunneth Ruth Lawrence Solomon Lefschetz Jean Leray Saunders Mac Lane Mark Mahowald J Peter May Barry Mazur John Milnor John Coleman Moore Jack Morava Joseph Neisendorfer Emmy Noether Sergei Novikov Grigori Perelman Henri Poincare Lev Pontryagin Nicolae Popescu Mikhail Postnikov Daniel Quillen Jean Pierre Serre Isadore Singer Stephen Smale Edwin Spanier Norman Steenrod Dennis Sullivan Rene Thom Hiroshi Toda Leopold Vietoris Hassler Whitney J H C Whitehead Gordon Thomas WhyburnImportant theoremsBlakers Massey theorem Borsuk Ulam theorem Brouwer fixed point theorem Cellular approximation theorem Dold Thom theorem Eilenberg Ganea theorem Eilenberg Zilber theorem Freudenthal suspension theorem Hurewicz theorem Kunneth theorem Lefschetz fixed point theorem Leray Hirsch theorem Poincare duality theorem Seifert van Kampen theorem Universal coefficient theorem Whitehead theoremSee alsoAlgebraic K theory Exact sequence Glossary of algebraic topology Grothendieck topology Higher category theory Higher dimensional algebra Homological algebra K theory Lie algebroid Lie groupoid Serre spectral sequence Sheaf Topological quantum field theoryNotesFraleigh 1976 p 163 Frechet Maurice Fan Ky 2012 Invitation to Combinatorial Topology Courier Dover Publications p 101 ISBN 9780486147888 Henle Michael 1994 A Combinatorial Introduction to Topology Courier Dover Publications p 221 ISBN 9780486679662 Spreer Jonathan 2011 Blowups slicings and permutation groups in combinatorial topology Logos Verlag Berlin GmbH p 23 ISBN 9783832529833 ReferencesWikimedia Commons has media related to Algebraic topology Wikiquote has quotations related to Algebraic topology Allegretti Dylan G L 2008 Simplicial Sets and van Kampen s Theorem Discusses generalized versions of van Kampen s theorem applied to topological spaces and simplicial sets Bredon Glen E 1993 Topology and Geometry Graduate Texts in Mathematics vol 139 Springer ISBN 0 387 97926 3 Brown R 2007 Higher dimensional group theory archived from the original on 2016 05 14 retrieved 2022 08 17 Gives a broad view of higher dimensional van Kampen theorems involving multiple groupoids Brown R Razak A 1984 A van Kampen theorem for unions of non connected spaces Arch Math 42 85 88 doi 10 1007 BF01198133 S2CID 122228464 Gives a general theorem on the fundamental groupoid with a set of base points of a space which is the union of open sets Brown R Hardie K Kamps H Porter T 2002 The homotopy double groupoid of a Hausdorff space Theory Appl Categories 10 2 71 93 Brown R Higgins P J 1978 On the connection between the second relative homotopy groups of some related spaces Proc London Math Soc S3 36 2 193 212 doi 10 1112 plms s3 36 2 193 The first 2 dimensional version of van Kampen s theorem Brown Ronald Higgins Philip J Sivera Rafael 2011 Nonabelian Algebraic Topology Filtered Spaces Crossed Complexes Cubical Homotopy Groupoids European Mathematical Society Tracts in Mathematics vol 15 European Mathematical Society arXiv math 0407275 ISBN 978 3 03719 083 8 archived from the original on 2009 06 04 This provides a homotopy theoretic approach to basic algebraic topology without needing a basis in singular homology or the method of simplicial approximation It contains a lot of material on crossed modules Fraleigh John B 1976 A First Course In Abstract Algebra 2nd ed Reading Addison Wesley ISBN 0 201 01984 1 Greenberg Marvin J Harper John R 1981 Algebraic Topology A First Course Revised edition Mathematics Lecture Note Series Westview Perseus ISBN 9780805335576 A functorial algebraic approach originally by Greenberg with geometric flavoring added by Harper Hatcher Allen 2002 Algebraic Topology Cambridge Cambridge University Press ISBN 0 521 79540 0 A modern geometrically flavoured introduction to algebraic topology Higgins Philip J 1971 Notes on categories and groupoids Van Nostrand Reinhold ISBN 9780442034061 Maunder C R F 1970 Algebraic Topology London Van Nostrand Reinhold ISBN 0 486 69131 4 tom Dieck Tammo 2008 Algebraic Topology EMS Textbooks in Mathematics European Mathematical Society ISBN 978 3 03719 048 7 van Kampen Egbert 1933 On the connection between the fundamental groups of some related spaces American Journal of Mathematics 55 1 261 7 JSTOR 51000091Further readingHatcher Allen 2002 Algebraic topology Cambridge University Press ISBN 0 521 79160 X and ISBN 0 521 79540 0 Algebraic topology Encyclopedia of Mathematics EMS Press 2001 1994 May JP 1999 A Concise Course in Algebraic Topology PDF University of Chicago Press Archived PDF from the original on 2022 10 09 Retrieved 2008 09 27 Section 2 7 provides a category theoretic presentation of the theorem as a colimit in the category of groupoids