Voi. 13, 1927
MA THEMA TICS: S. LEFSCHETZ
657
Moore, R. L., Trans. Amer. Math. Soc., 21, 1920 (345). Whyburn, G. T., ...
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Voi. 13, 1927
MA THEMA TICS: S. LEFSCHETZ
657
Moore, R. L., Trans. Amer. Math. Soc., 21, 1920 (345). Whyburn, G. T., "Cyclicly Connected Continuous Curves," these PROCEEDINGS, 13, 1927 (31-38). 4Moore, R. L., Fund. Math., 3, 1921 (233-237). 5 Moore, R. L., Math. Zeit., 15, 1922 (254-260). 6 Schoenflies, A., Die Entwickelung der Lehre von den Punktmannigfaltigkeiten, Leipzig, 1908, S. 237. 7Whyburn, G. T., "Concerning Continua in the Plane," Trans. Amer. Math. Soc., 29, 1927 (369-400). 8 Whyburn, G. T., these PROCEIDINGS, 12, 1926 (761-767). 9 Wilder, R. L., "Concerning Continuous Curves," Fund. Math., 7, 1925 (340-377), theorems 11 and 6. 10 For proofs of these and other related theorems for the case of the boundary of a complementary domain of a plane continuous curve, see Wilder, R. L., loc. cit. 1I Cf., for example, the proof of theorem 4 of my paper cited in ref. 8. Use will also be made here of Sierpinski's theorem that any continuum having property, S, is a continuous curve. See Sierpinski, W., Fund. Math., 1, 1920 (44-66). 12 That this set of points is a continuous curve has recently been proved by H. M. Gehman in his paper "Some Relations between a Continuous Curve and Its Subsets," Annals of Math. Ser. 2, 28, 1927 (103-111), theorem 8. 2 I
ON THE FUNCTIONAL INDEPENDENCE OF RATIOS OF THETA FUNCTIONS By S. LsvSCHPTZ DEPARTMSNT OF MATHEMATICS, PRINCXTON UNIVERSITY Communicated July 26, 1927
1. In the theory of multiply periodic functions there is a theorem which for many reasons it would be desirable to prove directly. Existing proofs either are not completely general or are very roundabout.' It may be stated thus: Consider a family of linearly independent e's of the same order and characteristic, in maximum number, attached to a definite period matrix, D. When the number of functions >p, their genus, then among their ratios to one of them there are p functionally independent. Let e, e2, . . . eGr be the functions and ul, . . ., up, the variables. The above theorem is equivalent to proving that the matrix eh
ash___
(1)
is of rank p + 1 when the (u)'s are arbitrary. This we shall do under the assumption that the order n is sufficiently great. Apparently restrictive, it is really immaterial in most cases. The proof, merely outlined here, is, as we shall see, not only direct but also very elementary.
MA THEMA TICS: S. LEFSCHETZ
658
PROC. N. A. S.
2. We take for Q the well-known normal form:
|lo, . .*, 0,1,0, .. .0; ajl, ... . and for e's those of characteristic zero: eh
ch)
=E exp [n7ri E aik(Mr + cj)(Mk + j,k
h(n
=
aj k
+2
ak,
E
(mj + cj)uJ;
= qh positive integer less than n).
The first summation is with respect to the m's which run through all integral values from -co to + co, while the q's are arbitrary within their limits. It will be observed that Q is not the most general normal matrix. In the general case the proof is the same but the formulas a little more involved. To establish our theorem it suffices to show that for fixed q's when the u's are all zero and n - co, (1) - a matrix of rank p + 1. We need, therefore, the limits of eh (0), 8eh(0), as n -
au,
co.
I say that the first expression-+ 1. Let a1k denote the imaginary part of akkX Since E a'jxk is a definite, positive, quadratic form, there exists a positive w such that 7rE ajkXjXk > heh( -)-1 | <-1 + exp[-nw (Mj + C-)2= + X
exp [nw(m +
-1 + I
Cj)2I.
The last exponential -*1 when m = 0, and - 0 for any other fixed value of m. Also for n greater than twice any q, and writing c for cj4, the ratio of that exponential to e_nwlml is less than exp- nw[rM2 (1 + 2c) m + C2] < 1 when m > 2, since owing to c < 1/2, the bracket is always negative. + X
| (3h() *Ev
where
e
-
1 | <
(1 + e + 2 E e _WWM) p
_
m=l
0 with 1/np. As the sum just written is equal to
e-nw 1
e
0 with
1/n,
e)h (0) - 1 as asserted. Concerning the second expression whose limit is desired, we have
VoiL. 13, 1927
PHYSICS: WATSON AND VAN DEN AKKER
|3h(O) i7rqh(0) | < n X bus -
which I say
o-
m, exp
-
nw
j
'd L
(mj + 4)2
0. Much as above it comes down to showing that +
n
o
E me-nwm m=1
, 0.
As m < em, this sum may be replaced by
nEe- (nw-l)m <
,.>o
t1
-en
e
Hence the limit of our expression is i7rqh. 3. Referring then to the matrix (1), among its determinants of order p + 1 there is one whose limit is
(ir)P
h , (h = 1, 2, ...p + 1; s = 1, 2, ...p).
Since after all the q's are arbitrary integers, we may so choose them that this determinant $0. This proves our theorem. 1 See the Encyklopadie article II B 7, Abelsche Functionen, by Krazer-Wirtinger, also the forthcoming bulletin of the National Research Council; selected topics in algebraic geometry, Ch. 17, ยง1.
THE DIRECTION OF EJECTION OF X-RA Y ELECTRONS By E. C. WATSON AND J. A. VAN DVN AKKER NORMAN BRIDGE LABORATORY OF PHYSICS, CALIFORNIA INSTITUTS oF TuCHNOLOGY
Communicated August 12, 1927
No conclusive evidence that the direction in which photo-electrons are ejected by X-rays depends in any way upon the nature of the atom from which the ejection takes place has as yet been brought forward. Auger,' using the C. T. R. Wilson cloud expansion-chamber method, showed that the most probable direction of ejection in a gas is a function of the frequency of the incident X-rays, but the variations which he found in this most probable direction with the nature of the gas used (oxygen or nitrogen, argon, krypton, xenon) were probably less than the experimental error, particularly as heterogeneous X-rays were used and the frequency of the X-rays which were most effective in ejecting electrons may have varied from gas to gas. Loughridge2 concluded that the most probable direction of ejection was the same for water-vapor, air and argon, but the absorption