Power Maps and Completions of Free Groups and of the Modular Group

191, 252]264 Ž1997. JA966925

JOURNAL OF ALGEBRA ARTICLE NO.

Power Maps and Completions of Free Groups and of the Modular Group John G. Thompson Department of Mathematics, Uni¨ ersity of Florida, 201 Walker Hall, Gaines¨ ille, Florida 32611-8000 Communicated by Walter Feit Received September 24, 1996

1. INTRODUCTION AND STATEMENT OF RESULTS If G is a group and n is an integer, the nth power map is Pn : G ª G, PnŽ x . s x n. Thus PnŽ G . s PynŽ G ., the set of nth powers of elements of G. If K is a normal subgroup of G and x g G, we say that x is an nth power Žmod K . if and only if there is y g G such that xy1 y n g K. Let PnŽ G mod K . be the set of all x in G such that x is an nth power Žmod K ., so that PnŽ G mod K . is the preimage in G of PnŽ GrK .. If K is a family of normal subgroups of G, we say that x is an nth power Žmod K . if and only if x is an nth power Žmod K . for all K g K, and we set Pn Ž G mod K . s

F Pn Ž G mod K . . Kg K

Thus, PnŽ G mod K . = PnŽ G .. For each group G, let Fin G be the set of all normal subgroups of G of finite index, and let G c be the completion of G in the profinite topology. THEOREM ŽLubotzky.. If F is a free group and n is an integer, then PnŽ F mod Fin F . s PnŽ F .. Set G s SLŽ2, Z., and for each N g N, set GN s

½ž

a c

b g G a y 1 ' b ' c ' d y 1 ' 0 Ž mod N . , d

5

/

the principal congruence subgroup of level N. Also, Z p and Q p denote the p-adic integers and the p-adic numbers, respectively. 252 0021-8693r97 $25.00 Copyright Q 1997 by Academic Press All rights of reproduction in any form reserved.

253

POWER MAPS AND COMPLETIONS

THEOREM 1. If n g N, 8 ¦ n, A g G, and A is an nth power Žmod GN . for all N s 1, 2, . . . , then there is B g SLŽ2, Q. such that B n s A. THEOREM 2. Ži. Žii.

If n is an integer ) 2, then there is A g G such that

A f PnŽ G . and A g PnŽ SLŽ2, Q..; A is an nth power Žmod GN . for all N s 1, 2, . . . .

Putting these results together, we get that Fin G and K, defined in the Corollary, behave differently with respect to power maps. COROLLARY. Ži. Žii.

Let K s  GN < N s 1, 2, . . . 4 , n g N.

PnŽ G mod Fin G . s PnŽ G .. If n ) 2, then PnŽ G mod K . ; PnŽ G ..

2. PROOF OF LUBOTZKY’S THEOREM AND A LEMMA The proof, due to Alex Lubotzky, is based on an idea in Lyndon and Schupp w3, p. 26x. Let F be a free group, f g F, n g N, and suppose that f is an nth power Žmod K . for every normal subgroup K of F of finite index. A moment’s thought shows that we may assume that F is of finite rank r ) 1, that f is cyclically reduced with respect to a basis X of F, and that, for each x g X, f f ² X y  x 4:. Write f s a1 ? ??? ? a k , a i g X j Xy1 , a i a iq1 / 1. We proceed by induction on k s length f ; in case k s 0, the Theorem visibly holds, as 1 s 1n for all n g Z. Write f s x 1m 1 ??? x rm r f 0 , m i g Z, f 0 g F9, X s  x 1 , . . . , x r 4 . Let p be a prime exceeding n and all < m i <. Let C be a group of order p with generator c. As r ) 1, there are i, 1 F i F r, and f g homŽ F, C . such that f Ž x i . s c, f Ž f . s 1. Thus, f Ž u. s f Ž ¨ y1 u¨ . for all u, ¨ g F. Replacing f by a cyclically reduced conjugate of f " 1 , we assume without loss of generality that a1 s x i . Relabelling X, we also assume without loss of generality that i s 1. Let F0 s ker f , and let T s  x 1j N 0 F j - p4 . Then T is a set of coset representatives for F0 in F, and T has the Schreier property that each initial segment of an element of T is in T. Let : F ª T be defined by u g T l F0 u. Then F0 is free on y1

U s  u g F < u / 1 and u s txtx

for some t g T , x g X 4 .

If t g T and x g X, set y1

t Ž t , x . s txtx

,

t Ž t , xy1 . s t Ž txy1 , x .

y1

.

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JOHN G. THOMPSON

Thus k

fs

Ł t Ž a1 , . . . , aiy1 , ai . ,

is1

and as t Ž1, a1 . s 1, the U-length of f is - k. Let K 0 be a normal subgroup of F0 of finite index and let K s F x g F K 0x. Then K is a normal subgroup of F of finite index, so there is g g F such that fy1 g n g K. In particular g n g F0 . Since g p g F0 , and since Ž n, p . s 1, we get g g F0 . Since K : K 0 , we have fy1 g n g K 0 , so f, as an element of F0 , is an nth power Žmod K 0 .. This holds for all relevant K 0 , so, by induction on k, we get f g PnŽ F0 .. Since PnŽ F0 . : PnŽ F ., and since PnŽ F . s PynŽ F ., while F K g K K s  14 Žso that the Theorem holds for n s 0., the proof is complete. LEMMA 1. Suppose p is a prime, G is a group, and F is a normal free subgroup of G of index p. Suppose that CG Ž x . is cyclic for all x g F y  14 . If m g N and n s p m , then PnŽ G mod Fin G . s PnŽ G .. Proof. Since PnŽ G mod Fin G . = PnŽ G ., it suffices to show that Ž Pn G mod Fin G . : PnŽ G .. Suppose g g PnŽ G mod Fin G .. For each K g Fin G, choose g K in G such that gy1 g Kn g K. Set h K s g Kp . Then h K g F and gy1 h nKr p g K. Since Fin G l Fin F is cofinal in Fin F, it follows from Lubotzky’s theorem that g g Pn r p Ž F ., so there is h in F such that g s h n r p. In particular, g g F. If g s 1, then g g PnŽ G ., so we may assume that g / 1. Pick an element a g G, a f F. Set u s ay1 ga. Thus,  g, u4 : F. Case 1.

g and u are F-conjugate.

Choose f in F with fy1 uf s g. Set f 0 s af. Thus f 0 g CG Ž g . and f 0 f F. By hypothesis, CG Ž g . is cyclic. As < CG Ž g .rCF Ž g .< s p, it follows that CF Ž g . : Pp Ž G .. In particular, h g Pp Ž G ., so g g PnŽ G .. Case 2.

g and u are not F-conjugate.

Choose L g Fin F such that gL and uL are not conjugate in FrL; L exists by Lyndon and Schupp w3, p. 26x. Set M s F x g G Lx. Then M g Fin G, and gM, uM are not conjugate in FrM but are conjugate in GrM. We may assume that g f PnŽ F .. Choose R g Fin F such that gR f PnŽ FrR .. Set S s F x g G R x. Then S g Fin G, and gS f PnŽ FrS . but gS g PnŽ GrS .. Set T s M l S. Thus, T g Fin G, T : F, and gT, uT are not conjugate in FrT but are conjugate in GrT, and gT f PnŽ FrT ., gT g PnŽ GrT .. Choose b in G such that gy1 b n g T. Thus, b g G, b f F. In addition bT g CG r T Ž gT .. Choose c g G such that cy1 ucgy1 g T. Thus, c g G,

POWER MAPS AND COMPLETIONS

255

c f F. Since < GrF < is a prime, there is an integer i, 1 F i - p, such that c s fb i for some f g F. Thus byi fy1 ufb i gy1 g T. Since T eG, we get fy1 uf ? b i gy1 byi g T. Since bT g CG r T Ž gT ., we get fy1 ufgy1 g T. This is false, as uT and gT are not conjugate in FrT. The proof is complete.

3. PRELIMINARIES TO THE PROOF OF THEOREM 1 Assume the hypotheses of Theorem 1, and let As

ž

a c

b , d

/

t s a q d.

Set K s  GN < N s 1, 2, . . . 4 ,

P˜n Ž G . s Pn Ž SL Ž 2, Q . . l G.

Since PnŽ G ., P˜nŽ G ., and PnŽ G mod K . are all stable under conjugation by elements of G, it suffices to show that A 0 g P˜nŽ G . for some G-conjugate A 0 of A. For each prime p, A is an nth power Žmod Gp k . for all k s 1, 2, . . . , and since SLŽ2, Z p . is compact, Anp s A

for some A p g SL Ž 2, Z p . .

Ž 3.1.

In this section, the proof of Theorem 1 is carried out under the hypothesis that t g  y2, y1, 0, 1, 24 . With the Corollary in mind, we prove more than is required in Theorem 1, namely, we prove that Ž3.2. if t g  y2, y1, 0, 1, 24 , then A is an nth power in G. Case 1.

t g  y1, 0, 14 .

In this case, A has order 3, 4, 6 respectively, and as A is an nth power Žmod G5 ., it follows that n is relatively prime to the order of A. Setting B s An, we get A s B n and Ž3.2. holds. Case 2.

t s 2.

In this case, we assume without loss of generality that a s d s 1, c s 0, and we must show that b ' 0 Žmod n.. This is clear if b s 0, so suppose b / 0. For each prime l dividing n, choose A l g SLŽ2, Z l . with A nl s A. This gives b ' 0 Žmod n l ., where n l is the l-part of n, so A is an nth power in G. Case 3.

t s y2 and n is odd.

Here, yA g PnŽ G mod K ., so yA is an nth power in G by the preceding case. As y1 s Žy1. n, A is also an nth power in G.

256

JOHN G. THOMPSON

Case 4.

t s y2 and n is even.

Here we assume without loss of generality that a s d s y1, c s 0. Let A 2 g SLŽ2, Z 2 . with A n2 s A. As y1 is not a square in Z 2 it follows that b s 0, n ' 2 Žmod 4., and A s Ž y10 10 . 2 . Thus, Ž3.2. holds. To complete the proof of Theorem 1, it suffices to treat the case < t < G 3.

4. CHEBYSHEF POLYNOMIALS The nth Chebyshef polynomial is TnŽ x . g Zw x x, characterized by TnŽcos u . s cos nu . Set Un Ž x . s 2Tn

x

ž / 2

.

Then UnŽ x . g Zw x x, UnŽ x . is monic, and in Zw x, xy1 x, UnŽ x q xy1 . s x n q xyn . The major ingredient in the proof of Theorem 1 involves a property of certain Chebyshef polynomials. J.-P. Serre noted that the following lemma is a consequence of w1, Theorem 1, p. 82x. LEMMA. Suppose l is a prime, m g N, n s l m , 8 ¦ n, t g Z, < t < G 3, and, for each prime p, there is c p g Z p such that UnŽ c p . s t. Then there is c g Z such that UnŽ c . s t. Proof. Suppose the statement is false. Set f Ž x . s UnŽ x . y t. Thus f Ž x . has a zero in Z p for all primes p. To prove the lemma, it suffices to find a root of f in Q, as f is a monic polynomial with integer coefficients. The first thing to pin down is Ž4.1. One of the following holds: Ži. l / 2. Žii. t G 3. Suppose Ž4.1. fails, so that l s 2 and t F y3. Since n is even, A is a square in SLŽ2, Z p . for every prime p, so U2 Ž x . y t has a zero in each Z p . Since U2 Ž x . s x 2 y 2, it follows that t q 2 is a square Žmod p . for every prime p. This is false as t q 2 - 0, and quadratic reciprocity yields a prime p such that ŽŽ t q 2.rp . s y1. From Ž4.1., we get a real number j such that

j n q jyn s t ,

Ž 4.2.

POWER MAPS AND COMPLETIONS

257

or, equivalently, f Ž j q jy1 . s 0.

Ž 4.3.

Denote by Q the set of all algebraic complex numbers, and for each k g N, let m k be the set of kth roots of 1 in Q. Set E s Q Ž mn , j . . Set Rqs  jz < z g m n 4 ,

Rys  jy1z < z g m n 4 ,

R s Rqj Ry, S s  jz q Ž jz .

y1

< z g mn 4 .

Obviously, as j / 0, we have < Rq< s < Ry< s n.

Ž 4.4.

If Rql Ry/ B, we get j 2 g m n , which is false as < t < G 3 and Ž4.2. holds. So < R < s 2 n.

Ž 4.5.

Suppose z 1 , z 2 g m n , z 1 / z 2 , but

jz 1 q Ž jz 1 .

y1

s jz 2 q Ž jz 2 .

y1

.

Then y1 j Ž z 1 y z 2 . s jy1 Ž zy1 2 y z1 . ,

so

j2s

y1 zy1 2 y z1

z1 y z2

y1 s zy1 1 z2 ,

which is false. So if we set g Ž z . s jz q Ž jz .y1 , then S s g Ž z . < z g mn 4 ,

< S < s n.

Ž 4.6.

Since deg f s n, Ž4.6. implies that Ž4.7.

S is the set of all roots of f in Q.

For all subfields F of Q, let GF be the profinite group of all automorphisms of Q which fix F elementwise, and let OF be the ring of integers of F. If F is a Galois extension of Q, and H is a subgroup of GQ rGF , F H denotes the set of fixed points of H on F.

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JOHN G. THOMPSON

Since f g Qw x x, Ž4.7. implies that S is GQ -stable. This implies that R is GQ -stable, as each element of R is a root of an equation X 2 y g Ž z . X q 1, both of whose roots lie in R for all z g m n . Since Q Ž R . s Q Ž mn , j . , it follows that E is a Galois extension of Q, with Galois group G s GQ rGE . Identifying GQ rGQŽ m n . with ŽZrnZ.=, we get an exact sequence =

1 ª H ª G ª Ž ZrnZ . ª 1,

Ž 4.8.

where H s GQŽ m n .rGE . For each r g R, let f r Ž x . be the monic irreducible polynomial in Ž Q m n .w x x which satisfies f r Ž r . s 0. We check that < H < s deg f r Ž x . ,

all r g R.

Ž 4.9.

To see this, observe that as E is Galois, H permutes transitively the roots of f r Ž x ., all of which lie in E. If h g H, and r 1 is a root of f r Ž x . fixed by h , then since r 1 s j ez 1 , e g  1, y14 , z 1 g m n , it follows that h Ž j . s j . Since E s QŽ m n , j ., we get h s 1, yielding Ž4.9.. Set h s < H <. Thus, for each r g R and each z g m n , z h f r Ž zy1 x . s f rz Ž x .. Also, f r Ž0. is in OE= , as each element of R is in OE= , so f ry1 Ž x . s f r Ž0.y1 x h f r Ž xy1 .. Define the integer e by e s <  fr Ž x . < r g R4 < , so that 2 n s he.

Ž 4.10.

Write

 f r Ž x . < r g R 4 s  F1Ž x . , . . . , Fe Ž x . 4 . For each i s 1, . . . , e, set R i s  r g R < Fi Ž r . s 0 4 , q Rq i s Ri l R ,

y Ry i s Ri l R .

Next, we use a well-known theorem to get Ž4.11. of G.

E C contains an element of S for every cyclic subgroup C

POWER MAPS AND COMPLETIONS

259

To see this, let C be a cyclic subgroup of G. Set Ds

Ł Ž s y s9. 2 .

s, s9gS s/s9

By a theorem of Frobenius w2x, there is a prime p such that p does not ramify in E, p ¦ D, and such that there is a prime ideal p of OE which contains p such that C is the stabilizer of p in G, and in addition such that < OErp < s p
for all i s 1, . . . , e.

Ž 4.12.

Rq i ,

Suppose the statement is false for i, and jz 1 , jz 2 g where z 1 , z 2 g m n , and z 1 / z 2 . Thus, there is h g H with h Ž jz 1 . s jz 2 . Let C s ²h :. Thus h Ž j . s jz 3 , where z 3 s z 2 zy1 1 / 1, and it follows that h fixes no element of S. This violates Ž4.11., and so yields Ž4.12.. From Ž4.12., we get e G n. Thus, Ž4.10. implies that Ž4.13. one of the following holds: Ži. e s 2 n and h s 1. Žii. e s n and h s 2. We next argue that Ž4.14.

G is not cyclic.

This is an immediate consequence of Ž4.11.. If e s 2 n and h s 1, then since 8 ¦ n, we get that G is cyclic, against Ž4.14.. So Ž4.13. implies that e s n and h s 2. Since ŽZrnZ.= is cyclic, while G is not cyclic, it follows that G s H = G0 ,

=

G 0 ( Ž ZrnZ . .

Let F s E G 0 , so that F s QŽ'M ., where M is an integer such that

'M f QŽ m n ..

We first study the case l / 2. Let H s ²h :, G 0 s ² s :, and let t be complex conjugation on E. Thus s Ž'M . s 'M and s Ž z . s z g , z g m n , where g is an integer which is a primitive root Žmod n.. Also, h Ž'M . s y 'M , and h Ž z . s z , t Ž z . s zy1 , t Ž'M . s sg Ž M .'M . Since e s n, we get

h Ž j . s jy1z 0 ,

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JOHN G. THOMPSON

for some z 0 g m n , and fj Ž x . s Ž x y j .Ž x y jy1z 0 .. Since G s H = ²hs :, we assume without loss of generality that s Ž j . s jz 1 , z 1 g m n . By Ž4.11., there is g Ž z 2 . g E ² s : for some z 2 g m n . This gives yg y1 y1 jz 1 z 2g q jy1zy1 1 z 2 s jz 2 q j z 2 ,

whence

z 1 s z 21y g .

Ž 4.15.

Since G9 s 1, so also t Žg Ž z 2 .. s s Žt Žg Ž z 2 ..., and since t Žg Ž z 2 .. s ., we get g Ž zy1 2 qg z 1 s zy1 . 2

Ž 4.16.

By Ž4.15. and Ž4.16., we conclude that z 1 s 1, and so z 2 s 1. Thus, s fixes g Ž1. s j q jy1 , whence M ) 0, since otherwise j q jy1 g Q, and the lemma holds. On the other hand, h Žg Ž1.. g QŽ'M ., and as h Žg Ž1.. s y1 y1 y1 . Ž y1 jy1z 0 q jzy1 , whence z 0 s 1. 0 , we get j z 0 q jz 0 s s j z 0 q jz 0 Ž Ž .. Ž . Ž . This forces h g 1 s g 1 , so g 1 is fixed by s and by h , so g Ž1. g Q, and the lemma holds. It remains to treat the case e s n, h s 2, l s 2. Since 8 ¦ n, we have n s 2 or 4. Since G is not cyclic and < G < s 2 f Ž n., it follows that n s 4. In this case, yM is not a square and G 0 s ² s :, where s Ž i . s yi, s Ž'M . s 'M , h Ž i . s i, h Ž'M . s y 'M . The three quadratic subfields of E are E ² s : , E ²h : , E ² sh : , and by Ž4.11., each of these quadratic subfields contains an element of S. As S s yS : Q=, each of the quadratic subfields contains at least two elements of S. As < S < s 4, the lemma holds in case n s 4. The proof is complete. Remark. Setting f Ž x . s U8 Ž x . y 64,514, we find that f Ž x . s Ž x 2 y 18.Ž x 2 q 14.Ž x 4 y 4 x 2 q 256.. The roots of f Ž x . are thus "3'2 , " 'y 14 , " Ž3 " 'y 7 ., so f Ž x . has no rational root. Since y7 is a square in Q 2 , 2 is a square in Q 7 , and since one of 2, y7, y14 is a square in Q p for each prime p f  2, 74 , it follows that f Ž x . has a root in Z p for all primes p. Thus, the condition 8 ¦ n in the lemma is necessary.

5. THE PROOF OF THEOREM 1 Assume the hypotheses of Theorem 1. Let As

ž

a c

b , d

/

t s a q d.

If t g  y2, y1, 0, 1, 24 , then Theorem 1 holds for A by Ž3.2.. So we assume that < t < G 3.

POWER MAPS AND COMPLETIONS

261

Set C s CG LŽ2, Q .Ž A.. Then C j  04 is a commutative field which is a quadratic extension field of Q ? I, and  I, yI 4 is the set of elements of finite order in C. For each prime l, write n s n l ? n l9 , where n l is the l-part of n. Since A is an nth power Žmod GN . for all N s 1, 2, . . . , it follows that A is an n l th power Žmod GN . for all N s 1, 2, . . . , so for each prime p, there is AŽ p, l . g SLŽ2, Z p . such that AŽ p, l . n l s A. Set t Ž p, l . s tr AŽ p, l ., and set f l Ž x . s Un lŽ x . y t. Then t Ž p, l . is a root of f l Ž x . in Z p , and so by the lemma on Chebyshef polynomials, there is c l g Q such that f l Ž c l . s 0. Set 0 B˜l s y1

1 c l g SL Ž 2, Q . .

ž

/

Thus tr B˜ln l s t, so there is X l g GLŽ2, Q. such that

˜n l Xy1 l Bl X l s

ž

0 y1

1 . t

/

Since tr A s t, there is Yl g GLŽ2, Q. such that Yly1

ž

0 y1

1 Y s A. t l

/

nl ˜ Ž . Set Bl s Yly1 Xy1 l Bl X l Yl . Then Bl g SL 2, Q and Bl s A. Thus the group generated by  Bl < l is a prime4 is a subgroup of CS LŽ2, Q .Ž A., so is abelian. Choose integers r l such that Ý l < n r l n l9 s 1. Set B s Ł l Blr l . Then

Bn s

Ł Blr n l

l9 n l

s

l

Ł Ar n l

l9

s A,

l

and the proof is complete.

6. THE PROOF OF THEOREM 2 First, assume that n s l m , m g N, l a prime. Case 1.

l / 2.

Let p be a prime ' 1 Žmod n.. Let ¨ be a positive integer which has order n Žmod p ., and let w be a positive integer such that ¨ w ' 1 Žmod p .. Write ¨ w y 1 s xy, where x, y are integers and p ¦ x. Write ¨

B0 s y

ž

x w ,

/

A 0 s B0n .

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JOHN G. THOMPSON

Then A 0 g Gp , B0 g G. Set p 0

0 1

p As 0

0 1

Bs

ž ž

y1

B0

p 0

0 ¨ s yp 1

A0

p 0

0 . 1

xrp , w

/ ž / ž / ž / y1

/

Then B n s A g G, and B g SLŽ2, Z r ., for every prime r / p. Also A s Ž ac db ., where a ' d ' 1 Žmod p ., c ' 0 Žmod p .. Since l / p, it follows that A is an nth power in SLŽ2, Z p ., as the nth power map induces a permutation of Vp s u g SL Ž 2, Z p . < u s

½

ž

u0 u2

u1 , u 0 ' u 3 ' 1 Ž mod p . , u3

/

5

u 2 ' 0 Ž mod p . . So A is an nth power in SLŽ2, Z r . for all primes r. By the Chinese remainder theorem, A is an nth power Žmod GN . for all N s 1, 2, . . . . Obviously, tr A f  y2, y1, 0, 1, 24 , so  I, yI 4 is the set of all elements of finite order in CS LŽ2, Q .Ž A.. As B n s A and B f G, it follows that A f PnŽ G .. Case 2.

l s 2.

Since n ) 2, we have m G 2. Let B0 s Bs

ž ž

1 1

1 , 2

3 0

0 1

A 0 s B04 s

/ / ž y1

B0

3 0

0 , 1

ž

13 21

21 , 34

/

A s B4.

/

Then Bs

1 3

1 3

ž / 2

,

As

ž

13 63

7 . 34

/

Then A is a fourth power in SLŽ2, Z 3 ., since the fourth power map in SLŽ2, Z 3 . induces a permutation of V3 . Since B g SLŽ2, Z r . for all primes r / 3, it follows that A is a fourth power in SLŽ2, Z r . for all primes r. my 2 Thus A2 is an nth power in SLŽ2, Z r . for all primes r, so by the my 2 Chinese remainder theorem, A2 is an nth power Žmod GN . for all 2 my 2 N s 1, 2, . . . . Since tr A ) 2,  I, yI 4 is the set of all elements of finite my 2 order in CS LŽ2, Q .Ž A., and since B n s A2 , where B g SLŽ2, Q., B f G,

263

POWER MAPS AND COMPLETIONS my 2

we have A2 f PnŽ G .. This completes the proof of Theorem 2 in case n is a prime power. The general case is now immediate, since there is a prime l such that n l ) 2. 7. PROOF OF THE COROLLARY From Theorem 2, we know that PnŽ G mod K . > PnŽ G . if n ) 2, so it only remains to prove that PnŽ G . s PnŽ G mod Fin G ., or, equivalently, that PnŽ G mod Fin G . : PnŽ G .. Set Xs

ž

y1 0

y2 , y1

Ys

/

y1 2

ž

0 . y1

/

We compute that

ž ž ž

0 y1

0 y1

1 y1

0 y1

1 y1

1 0

y1

/ ž / ž / ž X

y1

0 y1

1 s Y, 0

/ / /

X

0 y1

1 s Xy1 Yy1 , y1

Y

0 y1

1 s X, y1

y1

and so F s ² X, Y :e G. We see that G2 s F = ² y I : ,

< G : F < s 12.

As is well known and easy to check, F is free of rank 2. Suppose A g PnŽ G mod Fin G .. If
l ) 3.

Set B s A12 . Then B g PnŽ F mod Fin F ., so there is C in F with C s B. Since ² A, C : : C G Ž B ., and since C G Ž B . is abelian, we get A g PnŽ G .. n

Case 2.

l s 3.

Set B s A4 ,

¦ ž

G s F,

0 y1

1 y1

/;

.

264

JOHN G. THOMPSON

Thus B g PnŽ G mod Fin G .. By Lemma 1, we get B g PnŽ G ., so there is C in G with C n s B. Since ² A, C : is abelian, we have A g PnŽ G .. Case 3.

l s 2.

Since n is a positive power of 2, we conclude from Theorem 1 that A s A20 for some A 0 g SLŽ2, Q.. Since
ž

8 3

21 8

4

/

.

Then tr A s 64,514, so by the remark in Sect. 4, A is not an eighth power in SLŽ2, Q.. By the same remark, if p is a prime, then there are a p , bp g Q p such that

ž

ap

7bp

bp

ap

8

/

s A,

U8 Ž2 a p . s 64,514, and a2p y 7bp2 s 1. If p f  2, 74 , then since 2 a p g Z p , we get a p , bp g Z p . Also, 2 a2 s "Ž3 " 'y 7 ., so a2 g Z 2 whence b 2 g Z 2 . Finally, a7 s "3r '2 and 7b 72 s 92 y 1 s 72 , so b 7 g Z 7 . By the Chinese remainder theorem, A is an eighth power Žmod GN ., N s 1, 2, . . . . REFERENCES 1. E. Artin and J. Tate, ‘‘Class Field Theory.’’ 2. G. Frobenius, ‘‘Gesammelte Abhandlung,’’ Band II, pp. 719]733. 3. R. Lyndon and P. Schupp, ‘‘Combinatorial Group Theory,’’ Springer-Verlag, BerlinrNew York, 1977.