SOME ARITHMETIC PROPERTIES OF SHANKS'S ... - Semantic Scholar

SOME ARITHMETIC PROPERTIES OF SHANKS'S GENERALIZED EULER AND CLASS NUMBERS E. TESKE AND H. C. WILLIAMS Abstract. Over three decades ago Daniel Shanks discovered some integers c which generalize both the Euler numbers and the class numbers of imaginary quadratic elds. Little work appears to have been done on these numbers since their discovery apart from a few scattered results of Shanks that appear in some of his papers and in his correspondence with Mohan Lal. In this paper we investigate some arithmetic properties of these numbers and generalize Shanks's results. In particular, we establish some periodic properties of c modulo m and we partially answer the question of what primes can be divisors of c for a given value of a. a;n

a;n

a;n

1. Introduction Let D be a fundamental discriminant of an imaginary quadratic eld; then D  1 (mod 4) or D  8; 12 (mod 16). If we de ne the character  by (n) = D (n) = (D=n), where (D=n) is the Kronecker symbol, then the analytic class number formula gives p (1.1) L(1; ) = 2h(?a)=(w jDj) where j a = (2 ? jjD(2) (1.2) j)2 ; p h(?a) is the class number of the quadratic eld ( ?a), and w is the number of p roots of unity in ( ?a) (w = 2 if jDj > 4; w = 6 if jDj = 3; w = 4 if jDj = 4). Here Q

Q

(1.3) If we put

L(s; ) =

1 X

n=1

(n)n?s :

1  ?a  X ?s La (s) = 2n + 1 (2n + 1) ; n=0

Date : October 13, 1998. 1991 Mathematics Subject Classi cation. 11B68, 11R11. Secondary 11R29, 11Y40. Research of the second author supported by NSERC of Canada grant #A7649. 1

2

E. TESKE AND H. C. WILLIAMS

where (?a=2n+1) is the Jacobi symbol, then by using the Euler product representation of L(s; ), we get (1.4) La (s) = (1 ? (2)2?s)L(s; ) : In [15] Shanks showed that if we de ne ca;n by   2n+1 p ca;n a (2n)! = La (2n + 1) (a > 1) (1.5) 2a and 1   2n+1 c1;n = L (2n + 1) (a = 1) ; 2 2 (2n)! 1

then ca;n is an integer for a  1. He proved this interesting result by rst noting that if a = m2 b, where b is squarefree, then Y   ?b  ?s 1 ? p p Lb (s) : La (s) = pjm Thus, if cb;n is an integer, then so is ca;n; indeed, cb;n j ca;n. This reduced the problem to showing that ca;n is an integer if a is squarefree. In the sequel we will assume that a always represents a squarefree positive integer. Under this condition Shanks derived the recurrence   n X (1.6) ca;n?i(?a2 )i 2n 2i = Ca;n i=0 where 8 (aX ?1)=2   > k (a ? 4k)2n n > when a  3 (mod 4) n X ( ? 1) > : 2k +1 2k+1 1, then ( ca;0 = 3h(?a) if a  3 (mod 4) and a 6= 3 (1.7) h(?a) otherwise ; hence ca;0 2 . Furthermore, c1;n = En, the n?th Euler number. Because the values p of ca;n are integers and generalize the class number of ( ?a) in one direction and the Euler numbers in the other, Shanks called them \generalized Euler and class numbers". Z

Q

His interest in the ca;n numbers developed from his investigation of certain number theoretic constants. (See Shanks [14], p. 136.) In particular, he was concerned about how to obtain very precise values for ha , a number needed for determining the asymptotic density (under a conjecture of Hardy and Littlewood) of primes of the form x2 + a. In [13] he produced a technique for evaluating ha which required accurate values of La (s) for s = 1; 2; 3; : ::. In the case of La (2n + 1), we see from (1.5) that as soon as the value of ca;n is known, La (2n + 1) can be readily determined as precisely as needed. On the other hand, since ca;n is an integer, only

GENERALIZED EULER AND CLASS NUMBERS

3

an approximate value of La (2n + 1) is needed in order to x exactly what ca;n is. In collaboration with Mohan Lal, Shanks used his method of computing La (s) by means of Epstein zeta-functions to tabulate values of La (s) to 45 decimals. By using (1.5), Stirling's formula and the fact that La (2n + 1; ) is asymptotic to 1, it is easy to see that  4n 2n r 4n 2n+1=2 ; ca;n  e a hence, Shanks deduced that c100;9  6  1048 : Thus, given the level of accuracy for which they could compute La (s), they were able to produce a table of values for ca;n for a = 1(1)100 and n = 0(1)9 (see [16], p. 279). Of course, having only 45 decimals of La (2n+1), even for the range of n and a values above, is not enough to evaluate ca;n when ca;n is large, but Shanks discovered some congruences such as ca;n+2  ca;n (mod 60) (n  1) which are useful for determining the low order digits of ca;n . In [16] and in his 1968 correspondence with Lal, currently in the possession of the second author, he mentioned several such results, all without proof. He also mentioned in [16] another of his reasons for wanting to investigate the ca;n numbers. By results in x4 of [14], it is evident that for negative D, L(s; ) is rational for all s = 0; ?1; ?2; : : :. (This had actually been proved earlier by Leopoldt [11].) Shanks believed that these numbers, which are easily expressed in terms of his ca;n , would play a very signi cant role in a proof of the Extended Riemann Hypothesis that he felt might be produced from a proof of the Riemann Hypothesis. Whether this should prove to be the case or not, however, his ca;n numbers are of intrinsic interest and certainly merit further investigation. In this paper we shall derive a simple formula for evaluating ca;n, which is quite ecient as long as a is small. We use this to produce tables of values of ca;n. We then provide proofs of generalizations of all of Shanks's congruence results concerning ca;n. The methods that we will develop will work for all squarefree a, but because c1;n is de ned slightly dierently from ca;n (a > 1), we will assume for convenience that a > 1 in what follows. 2. Preliminary Results In order to compute values of ca;n and to derive some of their arithmetic properties, it is helpful to develop a formula for ca;n. A simple (and well known) approach to this is to make use of (1.3), together with the classical result on Gauss sums D  p X jDj   D e2ijm=jDj : D = (2.1) m j =1 j

4

E. TESKE AND H. C. WILLIAMS

From (1.3) we have

p

DL(2n + 1; ) =

hence, by (2.1)

p

DL(2n + 1; ) =

1  D  pD X m=1

m m2n+1 ;

jDj   X X D 1 e2ijm=jDj

j m=1 m2n+1 : Since L(2n + 1; ) is real, we observe on equating real and imaginary parts that jDX j?1   X p D 1 sin(2jm=jDj) : jDjL(2n + 1; ) = (2.2) m2n+1 j =1 j m=1 Since 0 < j=jDj < 1, we know by classical results (see, for example, Erdelyi et al [9], p. 38) that j 1 sin(2jm=jDj) (2)2n+1 (?1)n+1 X (2.3) = B 2n+1 jDj ; m2n+1 2(2n + 1)! m=1 where B2n+1(x) is the Bernoulli polynomial 2X n+1 2n + 1 (2.4) x2n+1? B B2n+1 (x) =   =0 and B denotes the  ? th Bernoulli number. Hence1 jDX j?1   D B2n+1(j=jDj) ; (2.5) ca;n = (?1)n+1 Mn ()D2n 2n + 1 j =1 j where ( 2n 2n+1 ? (2)) when a  ?1 (mod 4) Mn () = 2 (2 1 otherwise : Now it is well known that   D D (2.6) jDj ? j = ? j j =1

and (2.7) B2n+1(1 ? x) = ?B2n+1 (x) ([9], p. 37). It follows that  j  bjDXj=2c  D  j jDX j?1   D (2.8) B2n+1 jDj = 2 j B2n+1 jDj ; j =1 j j =1 and by (2.5) we get j n+1 n ()D2n bjD Xj=2c  D  (2.9) B ca;n = (?1) 2n2M +1 j 2n+1 jDj : j =1

1 We will often write formulas involving both D and a. In such formulas D and a are always related by (1.2).

GENERALIZED EULER AND CLASS NUMBERS

5

Using (2.9) in conjunction with (2.4), we were easily able to compute tables of ca;n for all squarefree values of a between 3 and 1000 and all values of n such that 0  n  120 when a < 20 and 0  n  40 otherwise. To obtain some insights concerning possible arithmetic properties of the ca;n values, we attempted to factor them. For all computations, we used the computer algebra system LiDIA [12]. Excerpts of some representative tables for a = 7; 11; 13 are presented below. The symbol Cn (Pn) denotes a composite (prime) cofactor of n digits with no prime factor below 106.

6

E. TESKE AND H. C. WILLIAMS

n 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40

ca;n 26 29
31 210
73
127 214
73
8831 214
11
23
73
89
701 217
173
8191
266447 218
31
151
145764975331 223
52181
131071
14859029 222
29
53
1459
23039
45599
524287 225
11
127
139
313
337
2389
23810336513 226
23
47
178481
27702422544842164391 230
31
47
601
1801
P22 230
73
17189
69151
262657
2074051907495337899 233
29
233
1103
2089
13866977
83889121
4897938881587 234
11
191
2147483647
P30 240
23
59
89
9281
9923
599479
P26 238
31
71
127
181
8191
122921
332273565017
P22 241
37
223
2399
30403
59359
616318177
P28 242
79
149
8191
121369
7059090067
227637367699153
48821335008117761009 246
11
13367
C56 246
43
53
431
9719
C55 249
23
31
73
137
151
631
23311
C53 250
29
691
2351
4513
C62 255
127
353
383
C69 254
11
103
1129
2143
11119
131071
587053
C57 257
53
83
6361
63703
69431
C68 258
23
31
89
881
3191
10711
201961
C69 262
29
541
3449
32377
524287
C75 262
193
179951
C91 265
11
1453
2203
C94 266
73
127
337
92737
649657
P89 273
31
83
113
503
8191
32083
C93 270
23
67
1097
3299
370213
C100 273
47
178481
C112 274
11
47
53
71
2063
228479
C109 278
37
439
C124 278
292
31
151
601
1801
100801
C115 281
23
89
127
C132 282
73
79
2687
3023
C131 287
11
73
2593
71119
75217
129953
262657
C119 Table 1. a = 7

GENERALIZED EULER AND CLASS NUMBERS

n 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40

7

ca;n 23
33 25
32
52
17 27
33
17
43
71 29
34
53
19
4999 211
32
43
269
683
14923 213
33
52
787
2731
1183579 215
33
331
428708869630871 217
32
52
43691
1146770634498019 219
34
8297
174763
7168193
50233429 221
33
53
17
43
5419
96167
153246640574641 223
32
17
23
2659
2796203
707401237
60295211117 225
33
52
251
487
4051
3958601
44660027
127805701711 227
35
19
73
1297
87211
P28 229
32
55
59
39847
441101
1016263
3033169
6204475921023883 231
33
31
42677
1019251
35929499
715827883
6353757847606928069 233
33
52
67
179
683
20857
1788911
4902713
40607227
1761795619636066741 235
32
43
281
46919
86171
P43 237
34
52
17
37
1777
28657
25781083
4575315629
P31 239
33
17
2731
C60 241
32
53
83
C65 243
33
173
399577
935537
C59 245
34
52
19
23
331
1171
1627
49871
C59 247
32
47
283
C78 249
33
53
43
C83 251
33
307
2857
6529
43691
101411
C71 253
32
52
17
43
53
107
C88 255
35
17
79
107
683
1201
2971
C84 257
33
52
571
174763
C95 259
32
59
313
2833
37171
531793
C91 261
33
53
31
C110 263
34
19
43
313
5419
30841
C104 265
32
52
131
2731
28081
409891
C106 267
33
23
67
1823
C121 269
33
53
17
139
C127 271
32
17
71
61667
C130 273
34
52
37
1753
C135 275
33
251
331
4051
6389
C135 277
32
52
43
71
617
683
78233
C137 279
33
C157 281
36
53
19
89
163
19603
87211
135433
786211
C132 Table 2. a = 11

8

E. TESKE AND H. C. WILLIAMS

n 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40

ca;n

2
151 2
128657 2
7
13
1087
2683 2
61
263
63477859 2
11
17
43
1663
11119
42223 2
7
31
2609
24419
4105617731 2
1951
3881
103020283
907058147 2
17
19
31
P25 2
7
13
19
97
P28 2
11
110729
135805619
20602775603
1861737262019 2
37
36494716387
366229898594827
405993740912827 2
7
73
971
530027
289340068611211
99757182964606125701 2
17
677
402991
41952180440214788539
P22 2
29
971
65609
967787
P40 2
7
11
13
31
C56 2
17
134059
C59 2
19
C69 2
7
19
197
10463
C67 2
139
C78 2
11
1061
C81 2
72
13
17
312
89
401
244121
C73 2
61
163
443
751
C86 2
31
47
C97 2
7
17
2797
7877
C96 2
11
241
409
2473
22573
312217
C92 2
19
43
53
149
6521
C106 2
7
13
19
C118 2
29
1741
C122 2
17
37
59
40493
931003
C117 2
7
11
31
61
P132 2
71
757
5023
P135 2
17
C147 2
7
13
67
C150 2
61
202567
C152 2
11
19
71
737207
C155 2
7
19
31
281
P164 2
17
33563
C170 2
31
1489
809189
C171 2
7
132
83
283
P180 2
11
17
547
212167
C183 Table 3. a = 13

GENERALIZED EULER AND CLASS NUMBERS

9

Notice that when a = 7; 11, we get a large power of 2 as a factor of ca;n, a power that increases with increasing n, but when a = 13 it appears that 2 j j c13;n for all n. Also, it seems that there are more factors of ca;n when a = 7; 11 than when a = 13 and that very often (but not always) a prime p divides ca;(p?1)=2. We will explain these and other phenomena concerning ca;n in the sequel. It will be convenient to consider the following exponential sums. We de ne Sm () = Tm () =

jDj X

(j)j m

j =1 bjDX j=2c j =1

(j)j m :

We can now write (2.5) as n+1 2n + 1 n+1 Mn () 2X ( ? 1) (2.10) B jDj ?1S2n+1? () ca;n = 2n + 1   =0 and (2.9) as n+1 2n + 1 n+1Mn () 2X 2( ? 1) (2.11) B jDj ?1T2n+1? () : ca;n = 2n + 1   =0 Also, it is well known that (2.12) S0 () = 0 and by classical results of Dirichlet we have T0() = w2 (2 ? (2))h(?a) ; (2.13) S1 () = w2 Dh(?a) :

(2.14) Furthermore, Sm () = hence, by (2.6) (2.15)

bjDX j=2c j =1

(j)j m +

Sm () = Tm () ?

Putting m = 1, we get

bjDX j=2c j =1

(jDj ? j j)(jDj ? j)m ;

m m X

(?1)i jDjm?i Ti () : i i=0

S1 () = 2T1 () ? jDjT0() ; therefore, by (2.13) and (2.14), we get 2T1 () = w2 (1 ? (2))jDjh(?a) : (2.16) In his correspondence with Lal, Shanks noted, but did not provide a proof, that if a  3 (mod 8) and a 6= 3, then 3 j ca;n for all n. In fact, he must have had a proof

10

E. TESKE AND H. C. WILLIAMS

of this because it is easy to modify the method of Ayoub, Chowla and Wallum [2] to prove that S3 () = D(ca;1 ? 4D2 ca;0 )=12 whenever D  5 (mod 8). (See Lehmer, Lehmer, Shanks [10], p. 442.) Suppose 3 a. Since 3 j ca;0, it is clear that2 3 j ca;1. Now by (1.6) ca;1 ? a2ca;0 = Ca;1 ; hence 3 j Ca;1. For any n  1, we get Ca;n  (?1)n+1 Ca;1  0 (mod 3) : If 3 j a, then Ca;n  (?1)n+1 T2 ()  (?1)n+1 T0()  0 (mod 3) : It follows by (1.6) that 2n n X 2 i ca;n?i(?a ) 2i  0 (mod 3) : i=0 By induction on n, it is easy to see that 3 j ca;n if a 6= 3 and a  3 (mod 8). We have now proved the following theorem. Theorem 2.1. If a  3 (mod 8), a 6= 3, then 3 j ca;n for all n  0. -

3. Properties of ca;n modulo 2k In a letter to Lal in February of 1968, Shanks mentioned that he noted \but did not formally prove" that if a  3 (mod 8) [a 6= 3], then 3
22n+1 j ca;n : This conjecture allowed him to determine the value of c11;9 (32 digits) from only a 25 digit approximation of L11 (9). We have already seen that 3 j ca;n whenever a  3 (mod 8) (a 6= 3). In this section we will prove that 22n+1 j ca;n whenever a  3 (mod 8), and we will establish several other divisibility results concerning ca;n with respect to powers of 2. By using the method of x2, we get (3.1)

p

jDjLa (2n + 1) =

jDj   X X D 1 sin2(2m + 1)j=jDj j =1

(2m + 1)2n+1

j m=0

:

For any j  1, let x = j=jDj. By (2.3) 1 sin 4mx X 1 sin2(2m + 1)x (?1)n+1 (2)2n+1 B X 2n+1(x) ; + 2n+1 2n+1 = (2m) (2m + 1) 2(2n + 1)! m=1 m=0 where x < 1, and 1 sin 2m(2x) (?1)n+1 2n+1 B 1 sin 4mx X 1 X 2n+1(2x) ; = 2n+1 22n+1 2n+1 = (2m) m 2(2n + 1)! m=1 m=1 2 Indeed, if one examines values of c for n = 0; 1, one might begin to believe that c 0 c 1 for all a; but, in fact, as Shanks noted in a letter to Lal, c47 0 c47 1 . (c47 0 = 5, c47 1 = 27 32 7.) a;n

a;

;

-

;

;

;




j

a;




GENERALIZED EULER AND CLASS NUMBERS

where 2x < 1. Since we have

sin 2m(2x ? 1) = sin 4mx ;

1 sin 4mx (?1)n+1 2n+1B X 2n+1 (2x ? 1) =

m=1 (2m)

2n+1

11

2(2n + 1)!

(1 < 2x < 2) :

It follows that 1 sin 2(2m + 1)x (?1)n+1 (2)2n+1B X 2n+1 (x) 2n+1 = (2m + 1) 2(2n + 1)! m=0 ( n+1 2n+1 B2n+1 (2x) when x < 1=2 ( ? 1) ? 2(2n + 1)! B (2x ? 1) when 1=2 < x < 1 : 2n+1 From this, (3.1) and (1.5), we get 0 jDj     n +1 2 n 2 n a 2 @X D 22n+1B2n+1 j ca;n = (2 (??j1)(2)j)(2n + 1) j =1 j jDj

?

bjDX j=2c 

 D

 2j 

jDj X

D

 2j

1 ?1 A :

j B2n+1 jDj ? j =bjDj=2c+1 j B2n+1 jDj By (2.8), (2.6) and (2.7), this becomes (3.2) 0bjDj=2c   1     n +1 2 n 2 n +1 X j 2j A : D 2 2n+1 @ ca;n = (2(??1)j(2)aj)(2n + 1) j =1 j 2 B2n+1 jDj ? B2n+1 jDj j =1

When a  ?1 (mod 4) and n  1, we can write (3.2) as 2n 2n + 1 n+1 22n+1 X ?
( ? 1) a (2B ) 22n ? 22n? T2n+1? () ; (3.3) ca;n = a(2n + 1)   =0 ?
?
on using (2.4) and the fact that B2n+1 = 0. Since 2n+1 =(2n + 1) = 2?n1 =, we also have 2n 2n a X ?22n+1 ? 22n?
T () : B (3.4) ca;n = (?1)n+1 22n+1  +1 2n?  =0   + 1 Now it is well known that 2B  1 (mod 2); hence, if n > 1, then (3.5) 2n 2n + 1 X  (2B ) ?22n ? 22n?
T2n+1? ()  ?(2n + 1)a2n2B2nT1 () (mod 8) : a   =0 If n = 1, then 2n 2n + 1 X ?
(3.6) a (2B ) 22n ? 22n? T2n+1? () = ?6aT2 () + 3a2 T1() :   =0 If a  3 (mod 8), then (2) = ?1 and T1 ()  h(?a) (mod 2) by (2.16); hence, by (3.3), we see that ca;n  0 (mod 22n+1) and 22n+1 j j ca;n if h(?a) is odd.

12

E. TESKE AND H. C. WILLIAMS

Theorem 3.1. If a  3 (mod 8) and n  1, then 22n+1 j ca;n. If 2 h(?a), then 22n+1 j j ca;n; otherwise, 22n+2 j ca;n. -

If a  7 (mod 8), then (2) = 1 and T1 () = 0 by (2.16). Thus if n > 1, we nd from (3.3) and (3.5) that 22n+4 j ca;n. When n = 1 we get (3.7) ca;1  ?16a3T2 () (mod 64) from (3.5). To proceed further we need a simple lemma. Lemma 3.2. If D 6 5 (mod 8), then S3 ()  S1 () (mod 4). Proof. We have

jDj   X D

j(j 2 ? 1) j j =1  D  bjDXj=2c  D   D   2 2 i i = 2 2 T1 () (mod 4) : i=1

S3 () ? S1 () =

The result now follows easily from (2.16). Corollary 3.2.1. If D  1 (mod 8), then 4 j T2(). Proof. From (2.15) with m = 3, we get

S3 () = 2T3() ? 3jDjT2 () + 3D2T1 () ? jDj3T0 () ; hence, by the lemma, we get S1 () = 2T1 () ? jDjT0 ()  2T3 () ? 3jDjT2() ? T1 () ? jDjT0() (mod 4) : Since T3 ()  T1 ()  0 (mod 2), we get jDjT2()  3T1 ()  0 (mod 4).

By Corollary 3.2.1 and (3.7), we get 64 j ca;1. Theorem 3.3. If a  7 (mod 8) and n  1, then 22n+4 j ca;n. We next consider the case of a 6 ?1 (mod 4). In this case we can write (3.2) as 2n 2n + 1 1)n+1 X   ?1 ca;n = (? (3.8) 2n + 1  =1  B (2 ? 1)(2a) T2n+1? () : It is very easy to see that (3.9) T2n+1 ()  T1 () = 2ah(?a) (mod 8) ; and if a 6= 2, we get 2 j h(?a); thus 4 j T2n+1() (n  0). It follows from (3.8) that     1)n+1 ? 2n + 1 T () + 2n + 1 aT () (mod 16) : (3.10) ca;n  (? 2n?1 2n + 1 2 2n 2 We note further that  T () when 2 n  T2n ()  T2 () when 2 j n (mod 16) : 0 -

GENERALIZED EULER AND CLASS NUMBERS

Thus, if 2 j n we get and by (3.10),

13

T2n()=2  h(?a) (mod 8) ; ca;n  h(?a) (mod 8) :

If 2 n, we must investigate T2 () (mod 16). It is a simple matter to verify that for any odd j, we have   j 2  5 ? 4 2j (mod 16) ; hence, jDX j=2   2D (mod 16) : T2 ()  5T0() ? 4 j =1 j If 8 D, then a  1 (mod 4) and 2D = ?8a is a fundamental discriminant. By (2.13) we get jDj   X 2D = 2h(?2a) ; j =1 j and since (2D=(jDj ? j)) = (2D=j), we can deduce that jDX j=2   2D = h(?2a) : j =1 j If 8 j D, then D=8 must be odd and either D=8 or 4D=8 is a fundamental discriminant. We get jDX j=2   jDX j=2  2D = j=2  4(D=8)  = jDX D=8  = 0 j j j =1 j j =1 j =1 by (2.12). By putting all these results in (3.10) we get the theorem below. Theorem 3.4. If a 6 ?1 (mod 4), then ca;n  (?1)nh(?a) (mod 8) when 2 j a or a  1 (mod 4) and 2 j n. If a  1 (mod 4) and 2 n, then ca;n  h(?a) + 2h(?2a) (mod 8) : -

-

-

4. Periodic Properties of ca;n modulo m As mentioned earlier, Shanks had observed that (4.1) ca;n+2  ca;n (mod 60) when n  1. He also mentioned in a letter to Lal that if
n = ca;n+2 ? ca;n, then (4.2)
n+2 
n (mod 100) (n  1) ;

14

E. TESKE AND H. C. WILLIAMS

furthermore, in a subsequent letter he noted that 4ca;3  3ca;1 + ca;9 (mod 100) ; ca;3  ca;9 (mod 819) ; ca;1  ca;9 (mod 17) : The rst of these last three follows on repeated application of (4.2), but all of the others suggest that there must be some general underlying periodic properties of the ca;n modulo m. In this section we will derive some of these properties. If by Bn we denote the generalized Bernoulli numbers of Leopoldt [11] (these numbers had in fact been mentioned as early as 1890 by Berger [3] and later in 1952 by Ankeny, Artin and Chowla[1]), then as noted by Carlitz [6] nX ?1 n

jDjj ?1Bj Sn?j () : j j =0 It follows from (2.10) that for n  1 B 2n+1 ca;n = (?1)n+1 Mn () 2n + 1 : (4.3) In 1959 Carlitz showed that B2n+1 is an integer as long as D 6= ?p, where p is a prime  ?1 (mod 4). He also showed that in the exceptional case, B2n+1=(2n+1) would be an integer as long as p 1 + g2n+1 , where g is any primitive root of pk (k = 1; 2; 3; : : :). However, it is a very easy matter to show that if p j j g2n+1 + 1, then p j 22n+1 ? (2); hence, by (4.2) and Carlitz's reasoning in x3 of [6], we see that ca;n must always be an integer. Thus, an alternate proof of the integrality of ca;n can easily be derived from the work of Carlitz. Bn =

-

Carlitz also proved in [6] that Bn satis es the Kummer-type congruence r Bn+1+su r X  r ? s (?1)  0 (mod (pn; per )) ; s n + 1 + su s=0

where p is any prime, pe?1(p ? 1) j u and either p D or jDj 6= p. Thus, by (4.3) we see that  r X (?1)s(u=2?1) rs ca;n+su=2  0 (mod (p2n; per )) (4.4) s=0 -

when 2 j u, pe?1 (p ? 1) j u and a 6 ?1 (mod 4). In fact, it can be shown that (4.4) holds for all squarefree values of a. We rst note that if a  ?1 (mod 4), then (4.4) holds when p = 2 by Theorems 3.1 and 3.3. We may therefore assume that p is odd. If, for a xed value of n, we de ne k = ak Bk+1 =(k + 1) ; k = 22n+1(22n+1 ? 2k )Tk () ;

GENERALIZED EULER AND CLASS NUMBERS

then by (3.4) we get (4.5)

2n 2n X n +1  2n? (?1) ca;n =  =0 

15

:

By Kummer's congruence for the Bernoulli numbers we have for any positive integer m r B r X m+1+su  0 (mod (pm ; per )) : r ? s (?1) s m + 1 + su s=0 Also, r r X r ? s (?1) am+su = am (au ? 1)r  0 (mod pr ) (r  m) : s s=0 Thus, by Theorem 10 of Carlitz [4], we get r r X r r ? s (4.6) (?1) s m+su  0 (mod p ) (r  m) : s=0 Since  r X (?1)r?s rs m+su s=0 = 22n+1



bjDX j=2c

k=1 0 (mod pr ) ;

?
(k) 22n+1km (ku ? 1)r ? (2k)m ((2k)u ? 1)r

we see by (4.6) and results in Carlitz [5] that r r X r ? s

m+su  0 (mod per ) (er  m) ; (?1) s s=0 where we de ne k k X  k? :

k =  =0  By (4.5) we get r r X r ? s (?1)n+1+su=2ca;n+su=2  0 (mod per ) (er  2n) : (?1) s s=0 Thus, we have proved the following theorem. Theorem 4.1. For all squarefree values of a, (4.4) must hold for any prime p. De nition 4.1. For a given positive integer m, put L = lcm[pe?1(p ? 1)=2 : pe j j m] ;

where the least common multiple is evaluated over all the distinct odd primes which divide m. We de ne ( when k  1 (m) = Lk?2 2 L when k  2 ;

16

E. TESKE AND H. C. WILLIAMS

where 2k j j m.

Corollary 4.1.1. If pe j j m and re  2n for each prime power which divides m,

then

r X

(4.7)

s=0

(?1)s( (m)?1)

r

r s ca;n+s (m)  0 (mod m ) :

By Corollary 4.1.1 with r = 1 we get (4.8) ca;n+ (m)  (?1) (m) ca;n (mod m) as long as e  2n for all e such that pe j j m. This is a generalization of (4.1) as (60) = 2. Note further that (819) = 6 and (17) = 8. If we put r = 2 in (4.7), we get ca;n+2 (m) ? 2(?1) (m) ca;n+ (m) + ca;n  0 (mod m2 ) as long as e  n for all pe j j m. Since (10) = 2, we get ca;n+4 ? 2ca;n+2 + ca;n  0 (mod 100) for n  1; this is the same as (4.2). 5. Primes that divide ca;n . If w(pe) is the least positive integer n such that pe j ca;n, then by (4.8) we must have w(pe) < e=2 + pe?1(p ? 1)=2. If, for example, we examine Table 1, we note that neither 5, 13 nor 19 can ever be a divisor of c7;n because for each of these values of p, p c7;n for all 1  n  (p ? 1)=2. The general question of just what primes can divide ca;n for some n for a prime value of a seems to be very dicult. In this section we will provide a partial answer to this question. -

We have already seen that 3 j ca;1 when a 6= 3 and a  3 (mod 8); also, Shanks mentioned to Lal that 5 j ca;2 whenever a  1 (mod 5). We will now investigate the more general question of when pe j ca;n, where n is a multiple of pe?1 (p ? 1)=2 and p is an odd prime. By (5.5) of [6] and (2.14) it is easy to see that B2n+1 2 e 2n + 1  ? w (1 ? (p))h(?a) (mod p ) when p a and pe?1(p ? 1) j 2n. Hence, by (4.3) we get  ?a  2(2 ? (2)) m ( p ? 1) = 2 e (5.1) ca;mpe?1 (p?1)=2  (?1) (2 ? j(2)j)w (1 ? p )h(?a) (mod p ) for any integer m > 0. 5.1. If p a and m is a positive integer, then pe j ca;mpe?1 (p?1)=2 if  Theorem ?a = 1 or if pe j h(?a). p -

-

 

GENERALIZED EULER AND CLASS NUMBERS

17

Thus, if ?pa = 1 or p a and p j h(?a), we nd that p j ca;(p?1)=2. In the case of p = 5, e = 1, we see that 5 j ca;2 if (?a=5) = 1 or a  1 (mod 5). We now consider this problem when p j a. We know by a result that goes back to Legendre that if  = (j ? )=(p ? 1), where  is the sum of the digits of j (> 0) when written in base p, then p j j j!. Thus, since   1, we get   j ? 1 (j  1). It follows that if pe?1
(p ? 1) j 2n and e  2i, then for i  1 2n e?2i 2i  0 (mod p ) ; therefore, for all e  1, 2n 2 i (?a ) 2i  0 (mod pe) : By (1.6) we get (5.2) ca;n  Ca;n (mod pe) : Now if a  ?1 (mod 4), we get

k

Since p

-

Ca;n = (?1)n

(aX ?1)=2 



k 2n a (a ? 4k) :

k=1 = 0 when p j k and (a ? 4k)2n  1 (mod pe) when

Ca;n  (?1)n By (2.13) and (5.2) we get

(aX ?1)=2  k=1

p k, we have -

?a  = (?1)n T () (mod pe ) : k

0

ca;mpe?1 (p?1)=2  (?1)m(p?1)=2 2(2 ?w(2)) h(?a) (mod pe ) :

If a 6 ?1 (mod 4), then 4 j D and  D  D  (5.3) jDj=2 + j = ? j : By this result and (2.6) we get  D  D  jDj=2 ? j = j : Since D = ?4a, it is now easy to show that X  ?a  n = (?1)n 21 T0 () (mod pe ) : Ca;n  (?1) 2b + 1 2b+1