TOPICS IN ALGEBRAIC AND ANALYTIC GEOMETRY BY PHILLIP GRIFFITHS AND JOHN ADAMS Preliminary Informal Notes of University Courses and Seminars in Mathematics MATHEMATICAL NOTES PRINCETON UNIVERSITY PRESS TOPICS IN ALGEBRAIC AND ANALYTIC GEOMETRY Notes £rom a course or PHILLIP GRIFFITHS Written and revised by JOHN ADAMS PRINCETON UNIVERSITY PRESS AND UNIVERSITY OF TOKYO PRESS PRINCETON, NEW JERSEY 1974 (S} Copyright 1974 by Princeton·University Press Published by Princeton University Press, Princeton and London All Rights Reserved L.C. Card: 74-2968 I.S.B.N.: 0-691-08151-4 Library of Congress Cataloging in Publication Data will be found on the last printed page of this book Published in Japan exclusively by University of Tokyo Press in other parts of the world by Princeton University Press Printed in the United States of America Introduction This is a revised version of the notes taken from a class taught at Princeton University in 1971-1972. The table of contents gives a good description of the material covered. The notes focus on comparison theorems between the algebraic, analytic, and continuous categories. CONTENTS Chapter One Section 1. Sheaf theory, ringed spaces l Section 2. Local structure of analytic and algebraic sets 9 Section 3. lPn 19 Chapter Two Section 1. Sheaves of modules 23 Section 2. Vector bundles 33 Section 3. Sheaf cohomology and computations on lPn 45 Chapter Three Section 1. Maximum principle and Schwarz lemma on analytic spaces 56 Section 2. Siegel's theorem 61 Section 3. Chow's theorem 69 Chapter Four Section 1. GAGA 73 Chapter Five Section 1. Line bundles, divisors, and maps to lPn 83 Section 2. Grassmannians and vector bundles 94 Section 3. Chern classes and curvature 112 Section 4. Analytic cocycles 128 Chapter Six Section 1. K-theory and Bott periodicity 136 Section 2, K -theory as a generalized cohomology theory 144 Chapter Seven Section 1. The Chern character and obstruction theory 154 Section 2. The Atiyah-Hirzebruch spectral sequence 164 Section 3. K-theory on algebraic varieties 183 Chapter Eight Section l, Stein manifold theory 196 Section 2. Holomorphic vector bundles on polydisks 203 Chapter Nine Concluding remarks 215 Bibliography 217 vi 1 Chapter One §I Sheaf theory, ringed spaces n On a: , the space of n complex variables, there is a sequence of sheaves defined in the usual topology: 0 :::) 0 :::) 0 :::) 0 cont diff hol alg where for an open set Uc a:n : r(u, 0 ) = continuous complex-valued functions defined on u . cont r(u, odiff ) = c"' complex-valued functions defined on u . = r(U, Ohol ) holomorphic functions defined on U • T(U, 0 a1g ) = rational holomorphic functions defined on U • (A holomorphic function cp on U is said to be rational just in case each a in U has a neighborhood W in U such that there are two polynomials p, q with q nowhere zero in W , with cp= p/q in W • In fact, because the polynomial ring a: [z1, ••• , zn] is a unique factorization domain, one can always = take W U.) If W is an open set prqperly contained in the open set U then there is always an element of r(W, 0 ) which does not extend to U, and similarly cont for 0 diff • But Ohol and 0 alg behave differently: We will prove a little theorem about this. I.l.2 2 I .A THEOREM (Hartog's removable singularities theorem) In case n ::::_ 2 and W .= U less a point, every holomorphic function on W extends to U • We may suppose that W = U - { (O, ••• , O)}. If 6 is a small positive number = { I such that An (6 ) z : sup J z i ~ 6 } is contained in U we define for each i=l, ... ,n f holomorphic in W J f(s, z2, ••• , zn) fl(zl' "., zn) = 211"l-1 de: s- zl Jz J=6 1 for z in the interior of the polydisk. It will suffice to show that f = f1 in the interior of the polydisk less its center. But for a point inside the polydisk with z2 "I 0 the formula f(zl' "., zn) = 211'/_l J f(s,z2, ... ,zn) de: e:- z - 1 Jz J= 1 Ii is valid, so f = f1 where both are defined. This type of behavior is more pronounced in the case of 0 a1g • Every holomorphic rational function on W will extend to U unless there is a poly- nomial with zeroes in U but no zeroes in W • The sheaf 0 a1g may naturally be restricted to a coarser topology on a:n , the Zariski topology . A set in a:n is a Zariski closed set in case it is the locus of zeroes of a set of polynomials- one can always take the set of polynomials to be an ideal in the polynomial ring. The Zari ski closed set associated to an ideal ~ will be denoted V(I) ("variety of I") • The complement of a Zariski closed set is a