XLII. On the Quantum Theory of Radiation and the Structure of the Atom. By N. Bohr, Dr. Phil. Copenhagen ; 
p. t. Reader in Mathematical Physics at the University of Manchester [Communicated by Sir Ernest Rutherford, F.R.S.] 



IN a series of papers in this periodical [citation redacted] the present writer 
has attempted to give the outlines of a theory of the 
constitution of atoms and molecules by help of a certain 



[header] 395 

application of the Quantum theory o£ radiation to the theory 
of the nucleus atom. As the theory has been made a subject 
of criticism, and as experimental evidence of importance 
bearing on these questions has been obtained in the meantime, an attempt will be made in this paper to consider 
some points more closely. 

§ 1. General assumptions. 

According to the theory proposed by Sir Ernest Rutherford, 
in order to account for the phenomena of scattering of [alpha]-rays, 
the atom consists of a central positively charged nucleus 
surrounded by a cluster of electrons. The nucleus is the 
seat of the essential part of the mass of the atom, and has 
linear dimensions exceedingly small compared with the 
distances apart of I he electrons in the surrounding cluster. 
From the results of experiments on scattering of alpha 
rays, Rutherford concluded that the charge on the nucleus 
corresponds to a number of electrons per atom approximately equal to half the atomic weight. Concordant 
evidence from a large number of very different phenomena 
has led to the more definite assumption that the number 
of electrons per atom is exactly equal to the atomic number, 
i. e., the number of the corresponding element in the periodic 
table. This view was first proposed by van den Brock [citation redacted]. 
While the nucleus theory has been of great utility in 
explaining many important properties of the atom [citation redacted], on the 
other hand it is evident that it is impossible by its aid 
to explain many other fundamental properties if we base 
our considerations on the ordinary electrodynamical theory ; 
but this can hardly be considered as a valid objection 
at the present time. It does not seem that there is any 
escape from the conclusion that it is impossible to account 
for the phenomena of temperature radiation on ordinary 
electrodynamics, and that the modification to be introduced 
in this theory must be essentially equivalent with the 
assumptions first used by Planck in the deduction of his 
radiation formula [citation redacted]. These assumptions are known as the 
Quantum theory. In my previous paper it was attempted 
to apply the main principles of this theory by introducing 
the following general assumptions : — 




396 [header]
 

A. An atomic system possesses a number of states in 
which no emission of energy radiation takes place, 
even if the particles are in motion relative to each 
other, and such an emission is to be expected on 
ordinary electrodynamics. The states are denoted 
as the " stationary " states of the system under 
consideration. 

B. Any emission or absorption of energy radiation will 
correspond to the transition between two stationary 
states. The radiation emitted during such a transition is homogeneous and the frequency v is determined by the relation 

[formula redacted] 

where h is Planck's constant and A x and A 2 are the 
energies of the system in the two stationary states. 

C. That the dynamical equilibrium of the systems in the 
stationary states is governed by the ordinary laws 
of mechanics, while these laws do not hold for the 
transition from one state to another. 

D. That the various possible stationary states of a system 
consisting of an electron rotating round a positive 
nucleus are determined by the relation 

[formula redacted] 

where T is the mean value of the kinetic energy of 
the system, [omega] the frequency of rotation, and n a 
whole number. 

It will be seen that these assumptions are closely analogous 
to those originally used by Planck about the emission of 
radiation in quanta, and about the relation between the 
frequency of an atomic resonator (of constant frequency) 
and its energy. It can be shown that, for any system containing one electron rotating in a closed orbit, the assumption 
C and the relation (2) will secure a connexion between the 
frequency calculated by (1) and that to be expected from 
ordinary electrodynamics, in the limit where the difference 
between the frequency of the rotation of the electron in 
successive stationary states is very small compared with the 
absolute value of the frequency (see IV. p. 310). On the 
nucleus theory this occurs in the region of very slow 
vibrations. If the orbit of the electron is circular, the 
assumption D is equivalent to the condition that the angular 
momentum of the system in the stationary states is an 
integral multiple of [formula redacted]. The possible importance of the 



[header] 397 

angular momentum in the discussion o£ atomic systems in 
relation to Planck's theory was first pointed out by 
J. W. Nicholson [citation redacted]. 

In paper I. it was shown that the above assumptions lead 
to an interpretation of the Balmer formula for the hydrogen 
spectrum, and to a determination of the Rydberg constant 
which was in close agreement with the measurements. In 
these considerations it is not necessary to make any assumption about the degree of excentricity of the orbit of the 
electron, and we shall see in the next section that it cannot 
be assumed that the orbit is always circular. 

So far we have considered systems which contain only one 
electron, but the general validity of the assumptions A and B 
seems strongly supported by the fact that they offer a simple 
interpretation of the general principle of combination of 
spectral lines (see IV. p. 507). This principle was originally 
discovered by Ritz to hold for the ordinary series spectra of 
the elements. It has recently acquired increased interest 
by Fowler's work on the series spectra of enhanced lines 
emitted from many elements when subject to a powerful 
electric discharge. Fowler showed that the principle of 
combination holds for these spectra although the laws 
governing the numerical relation between the lines at an 
important point (see section 3) differed from those of the 
ordinary series spectra. There is also, as we shall see in 
section I, some indication that the principle holds for the 
high frequency spectra revealed by interference in crystals. 
In this connexion it may also be remarked that the assumption A recently has obtained direct support by experiments 
of A. Einstein and J. W. do Haas [Einstein and Haas, [citation redacted]. That 
such a mechanical rotational effect was to be expected on the electron 
theory of magnetism was pointed out several years ago by 0. W. 
Richardson, [citation redacted]. ' Richardson tried to 
detect this effect but without decisive results.], who have succeeded in 
detecting and measuring a rotational mechanical effect produced when an iron bar is magnetized. Their results agree 
very closely with those to be expected on the assumption 
that the magnetism of iron is due to rotating electrons, and 
as pointed out by Einstein and Haas, these experiments 
therefore indicate very strongly that electrons can rotate in 
atoms without emission of energy radiation. 

When we try to apply assumptions, analogous with C and 
D, to systems containing more than one electron, we meet 
with difficulties, since in this case the application of ordinary 




398 [header]

mechanics in general does not lead to periodic orbits. An 
exception to this, however, occurs if the electrons are 
arranged in rings and rotate in circular orbits, and from 
simple considerations of analogy the following assumption 
was proposed (see I. p. 24). 

E. In any atomic or molecular system consisting of 

positive nuclei and electrons in which the nuclei are 
at rest relative to each other, and the electrons move 
in circular orbits, the angular momentum of each 
electron round the centre of its orbit will be equal 
to [formula redacted] in the " normal " state of the system, 
i. e. the state in which the total energy is a 
minimum. 

It was shown that in a number of different cases this 
assumption led to results in approximate agreement with experimental facts. In general, no stable configuration in which 
the electrons rotate in circular orbits can exist if the problem 
of stability is discussed on ordinary mechanics. This is no 
objection, however, since it is assumed already that the 
mechanics do not hold for the transition between two 
stationary states. Simple considerations led to the following 
condition of stability. 

F. A configuration satisfying the condition E is stable 

if the total energy of the system is less than in 
any neighbouring configuration satisfying the same 
condition of angular momentum of the electrons. 

As already mentioned, the foundation for the hypothesis E 
was sought in analogy with the simple system consisting of 
one electron and one nucleus. Additional support, however, 
was obtained from a closer consideration of the formation of 
the systems. It was shown how simple processes could be 
imagined by which the confluence of different rings of electrons could be effected without any change in the angular 
momentum of the electrons, if the angular momentum of 
each electron before the process was the same. Such 
considerations led to a theory of formation of molecules. 

It must be emphasized that only in the case of circular 
orbits has the angular momentum any connexion with the 
principles of the Quantum theory. If, therefore, the application of ordinary mechanics to the stationary states of the 
system does not lead to strictly circular orbits, the assumption 
E cannot be applied. This case occurs if we consider configurations in which the electrons are arranged in different 
rings which do not rotate with the same frequency. Such 
configurations, however, are apparently necessary in order 



[header] 399 

to explain many characteristic properties of the atoms. In 
my previous papers an attempt was made in certain cases to 
overcome this difficulty by assuming, that if a very small 
alteration of the forces would make circular orbits possible 
on ordinary mechanics, the configuration and energy of the 
actual system would only differ very little from that calculated for the altered system. It will be seen that this 
assumption is most intimately connected with the hypothesis F on the stability of the configurations. Such 
considerations were used to explain the general appearance 
of the Rydberg constant in the spectra of the elements, and 
were also applied in discussing possible configurations of the 
electrons in the atoms suggested by the observed chemical 
properties. These calculations have been criticised by 
Nicholson [citation redacted], who has attempted to show that the configurations chosen for the electrons in the atoms are inconsistent 
with the main principles of the theory, and has also attempted 
to prove the impossibility of accounting for other spectra by 
help of assumptions similar to those used in the interpretation of the hydrogen spectrum. 

Although I am quite ready to admit that these points 
involve great and unsolved difficulties, I am unable to agree 
with Nicholson's conclusions. In the first place, his calculations rest upon a particular application to non-circular 
orbits of the principle of constancy of angular momentum 
for each electron, which it does not seem possible to justify 
either on the Quantum theory or on the ordinary mechanics, 
and which has no direct connexion with the assumptions used 
in my papers. It has not been proved that the configurations proposed are inconsistent with the assumption C. But 
even if it were possible to prove that the unrestricted use of 
ordinary mechanics to the stationary states is inconsistent 
with the configurations of the electrons, apparently necessary 
to explain the observed properties of the elements, this 
would not constitute a serious objection to the deductions 
in my papers. It must be remarked that all the applications of ordinary mechanics are essentially connected 
with the assumption of periodic orbits. As far as the 
applications are concerned, the first part of the assumption 
might just as well have been given the following more 
cautious form : — 

" The relation between the frequency and energy of the 
particles in the stationary states can be determined by means 
of the ordinary laws of mechanics if these laws lead to 
periodic orbits." 



400 [header]

The possible necessity for an alteration of this kind in 
assumption C may perhaps not seem unlikely when it is 
remembered that the laws o£ mechanics are only known to 
hold for certain mean values of the motion of the electrons. 
In this connexion it should also be remarked that when 
considering periodic orbits only mean values are essential 
(comp. I. p. 7). The preliminary and tentative character of 
the formulation of the general assumptions cannot be too 
strongly emphasized, and admittedly they are made to suit 
certain simple applications. For example, it has been already 
shown in paper IV. that the assumption B needs modification 
in order to account for the effect of a magnetic field on 
spectral lines. In the following sections some of the recent 
experimental evidence on line spectra and characteristic 
Röntgen rays will be considered, and I shall endeavour to 
show that it seems to give strong support to the main 
principles of the theory. 

2. Spectra emitted from systems containing only one 
electron. 
In the former papers it was shown that the general 
assumptions led to the following formula for the spectrum 
emitted by an electron rotating round a positive nucleus 

[formula redacted]

Ne, —e, M, m are the electric charges and the masses of the 
nucleus and the electron respectively. The frequency of 
rotation and the major axis of the relative orbit of the 
particles in the stationary states are given by 

[formula redacted]

The energy necessary to remove the electron to infinite 
distance from the nucleus is 

[formula redacted] 

This expression is also equal to the mean value of the kinetic 
energy of the system. Since — W„ is equal to the total 
energy A n of the system we get from (4) and (5) 

[formula redacted] 

If we compare (6) with the relation (1), we see that the 


[header] 401 

connexion with ordinary mechanics in the region of slow 
vibration, mentioned in the former section, is satisfied. 

Putting N = l in (3) we get the ordinary series spectrum 
of hydrogen. Putting N = 2 we get a spectrum which, on 
the theory, should be expected to be emitted by an electron 
rotating round a helium nucleus. The formula is found very 
closely to represent some series of lines observed by Fowler [citation redacted] 
and Evans [citation redacted]. These series correspond to [formula redacted] and [formula redacted]. 
The theoretical value for the ratio between the second factor 
in (3) for this spectrum and for the hydrogen spectrum is 
1*000409 ; the value calculated from Fowler's measurements 
is 1*000408 [citation redacted]. Some of the lines under consideration have 
been observed earlier in star spectra, and have been ascribed 
to hydrogen not only on account of the close numerical relation with the lines of the Balmer series, but also on account 
of the fact that the lines observed, together with the lines 
of the Balmer series, constitutes a spectrum which shows a 
marked analogy with the spectra of the alkali metals. This 
analogy, however, has been completely disturbed by Fowler's 
and Evans' observations, that the two new series contain 
twice as many lines as is to be expected on this analogy. In 
addition, Evans has succeeded in obtaining the lines in such 
pure helium that no trace of the ordinary hydrogen lines 
could be observed [citation redacted]. The great difference between the conditions for the production of the Balmer series and the series 
under consideration is also brought out very strikingly by 
some recent experiments of Rau [citation redacted] on the minimum voltage 
necessary for the production of spectral lines. While about 
13 volts was sufficient to excite the lines of the Balmer series, 
about 80 volts was found necessary to excite the other series. 
These values agree closely with the values calculated from 
the assumption E for the energies necessary to remove the 
electron from the hydrogen atom and to remove both electrons 
from the helium atom, viz. 13*6 and 81'3 volts respectively. 
It has recently been argued [citation redacted] that the lines are not so sharp 
as should be expected from the atomic weight of helium on 
Lord Rayleigh's theory of the width of spectral lines. This 
might, however, be explained by the fact that the systems 

[footer]


402 [header]

emitting the spectrum, in contrast to those emitting the 
hydrogen spectrum, are supposed to carry an excess positive charge, and therefore must be expected to acquire great 
velocities in the electric field in the discharge-tube. 

In paper IV. an attempt was made on the basis of the 
present theory to explain the characteristic effect of an 
electric field on the hydrogen spectrum recently discovered 
by Stark. This author observed that if luminous hydrogen 
is placed in an intense electric field, each of the lines of the 
Balmer series is split up into a number of homogeneous 
components. These components are situated symmetrically 
with regard to the original lines, and their distance apart is 
proportional to the intensity of the external electric field. 
By spectroscopic observation in a direction perpendicular to 
the field, the components are linearly polarized, some parallel 
and some perpendicular to the field. Further experiments 
have shown that the phenomenon is even more complex than 
was at first expected. By applying greater dispersion, the 
number of components observed has been greatly increased, 
and the numbers as well as the intensities of the components 
are found to vary in a complex manner from line to line [citation redacted]. 
Although the present development of the theory does not 
allow us to account in detail for the observations, it seems that 
the considerations in paper IV. offer a simple interpretation 
of several characteristic features of the phenomenon. 

The calculation can be made considerably simpler than in 
the former paper by an application of Hamilton's principle. 
Consider a particle moving in a closed orbit in a stationary 
field. Let [omega] be the frequency of revolution, T the mean 
value of the kinetic energy during the revolution, and W the 
mean value of the sum of the kinetic energy and the potential 
energy of the particle relative to the stationary field. We 
have then for a small arbitrary variation of the orbit 

[formula redacted] 

This equation was used in paper IV. to prove the equivalence 
of the formulæ (2) and (6) for any system governed by 
ordinary mechanics. The equation (7) further shows that if 
the relations (2) und (6) hold for a system of orbits, they will 
hold also for any small variation of these orbits for which the 
value of W is unaltered. If a hydrogen atom in one of its 
stationary states is placed in an external electric field and the 
electron rotates in a closed orbit, we shall therefore expect 
that W is not altered by the introduction of the atom in. 



[header] 403 

the field, and that the only variation of the total energy of 
the system will be due to the variation of the mean value 
of the potential energy relative to the external field. 

In the former paper it was pointed out that the orbit of the 
electron will be deformed by the external field. This deformation will in course of time be considerable even if the 
external electric force is very small compared with the force 
of attraction between the particles. The orbit of the electron 
may at any moment be considered as an ellipse with the 
nucleus in the focus, and the length of the major axis will 
approximately remain constant, but the effect of the field 
will consist in a gradual variation of the direction of the 
major axis as well as the excentricity of the orbit. A detailed 
investigation of the very complicated motion of the electron 
was not attempted, but it was simply pointed out that the problem allows of two stationary orbits of the electron, and that 
these may be taken as representing two possible stationary 
states. In these orbits the excentricity is equal to 1, and the 
major axis parallel to the external force ; the orbits simply 
consisting of a straight line through the nucleus parallel to 
the axis of the field, one on each side of it. It c;m very simply 
be shown that the mean value of the potential energy relative 
to the field for these rectilinear orbits is equal to [formula redacted], 
where E is the external electric force and 2a the major axis of 
the orbit, and the two signs correspond to orbits in which the 
direction of the major axis from the nucleus is the same or 
opposite to that of the electric force respectively. Using the 
formulae (I) and (5) and neglecting the mass of the electron 
compared with that of the nucleus, we get, therefore, for the 
energy of the system in the two states 

[formula redacted] 

respectively. This expression is the same as that deduced in 
paper IV. by an application of (G) to the expressions for the 
energy and frequency of the system. Applying the relation 
(1) and using the same arguments as in paper IV. p. 515, we 
are therefore led to expect that the hydrogen spectrum in an 
electric field will contain two components polarized parallel 
to the field and of a frequency given by 

[formula redacted]

The table below contains Stark's recent measurements of 
the frequency difference between the two strong outer components polarized parallel to the field for the five first lines 

[footer]



404 [header]



in the Balmer series [citation redacted]. The first column gives the values for 
the numbers n 1 and n 2 . The second and fourth columns give 
the frequency difference Au corresponding to a field of 28500 
and 74000 volts per cm. respectively. The third and fifth 
columns give the values of 


[formula redacted]

where u should be a constant for all the lines and equal to 
unity. 


[table redacted]



Considering the difficulties of accurate measurement of the 
quantities involved, it will be seen that the agreement with 
regard to the variation of the frequency differences from line 
to line is very good. The fact that all the observed values 
are a little smaller than the calculated may be due to a slight 
over-estimate of the intensity of the fields used in the 
experiments [citation redacted]. Besides 
the two strong outer components polarized parallel to the 
field, Stark's experiments have revealed a large number of 
inner weaker components polarized in the same way, and also 
a number of components polarized perpendicular to the field. 
This complexity of the phenomenon, however, cannot be considered as inconsistent with the theory. The above simple 
calculations deal only with the two extreme cases, and we 
may expect to find a number of stationary states correspond- 
ing to orbits of smaller excentricity. In a discussion of such 
non-periodic orbits, however, the general principles applied 
are no longer sufficient guidance. 

Apart from the agreement with the calculations, Stark's 
experiments seem to give strong support to the interpretation 
of the origin of the two outer components. It was found 
that the two outer components have not always equal intensities ; when the spectrum is produced by positive rays, it 



[header] 405 

was found that, the component of highest frequency is the 
stronger if the rays travel against, the electric field, while if 
it travels in the direction of the field the component of 
smallest frequency is the stronger (Joe cit. p. 40). This 
indicates that the components are produced independently 
of each other — a result to be expected if they correspond to 
quite different orbits of the electron. That the orbit of the 
electron in general need not be circular is also very strongly 
indicated by the observation that the hydrogen lines emitted 
from positive rays under certain conditions are partly 
polarized without the presence of a strong external field 
(Joe. (it. p. 12). This polarization, as well as the observed 
intensity differences of the two components, would be 
explained if we can assume that for some reason, when the 
atom is in rapid motion, there is a greater probability for 
the orbit of the electron to lie behind the nucleus rather 
than in front of it. 

§ 3. Spectra emitted from systems containing more than 
one electron. 

According to Rydberg and Ritz, the frequency of the 
lines in the ordinary spectrum of an element is given by 

[formula redacted]

where n 1 and n 2 are whole numbers and [formula redacted] , are a 

series of functions of n which can be expressed hv 

[formula redacted] 

where K is a universal constant and [phi] a function which for 
large values of n approaches unity. The complete spectrum 
is obtained by combining the numbers n 1 and w 3 as well as 

the functions f1, f2 in every possible way. 

On the present theory, this indicates that the system 
which emits the spectrum possesses a number of series of 
stationary states for which the energy in the nth state in the 
rth series is given by (see IV. p. 511) 

[formula redacted] 

where C is an arbitrary constant, the same for the whole 
system of stationary states. The first factor in the second 
term is equal to the expression (5) if N = 1. 

In the present state of the theory it is not possible to 
account in detail for the formula (13), but it was pointed 



406 [header] 

out in my previous papers that a simple interpretation can 
be given of the fact that in every series [phi](n) approaches 
unity for large values of n. It was assumed that in the 
stationary states corresponding to such values of n, one of 
the electrons in the atom moves at a distance from the 
nucleus large compared with the distance of the other 
electrons. If the atom is neutral, the outer electron will be 
subject to very nearly the same forces as the electron in the 
hydrogen atom, arid the formula (13) indicates the presence 
of a number of series of stationary states of the atom in 
which the configuration of the inner electrons is very nearly 
the same for all states in one series, while the configuration 
of the outer electron changes from state to state in the series 
approximately in the same way as the electron in the 
hydrogen atom. From the considerations in the former 
sections it will therefore appear that the frequency calculated from the relations (1) and (13) for the radiation emitted 
during the transition between successive stationary states 
within each series will approach that to be expected on 
ordinary electrodynamics in the region of slow vibrations [* On this view we should expect the Rydberg constant in (13) 
to be not exactly the same for all elements, since the expression (5) 
depends to a certain extent on the mass of the nucleus. The correction 
is very small ; the difference in passing from hydrogen to an element of 
high atomic weight being only 0'05 per cent, (see IV. p. 512). In a 
recent paper [citation redacted], Nicholson has concluded that this consequence of the theory is inconsistent with the 
measurements of the ordinary helium spectrum. It seems doubtful, 
however, if the measurements are accurate enough for such a conclusion. 
It must be remembered that it is only for high values of n that the 
theory indicates values of [phi] very nearly unity ; but for such values of n, 
the terms in question are very small, and the relative accuracy in the 
experimental determination not very high. The only spectra for which 
a sufficiently accurate determination of K seems possible at present are 
the ordinary hydrogen spectrum and the helium spectrum considered in 
the former section, and in these cases the measurements agree very 
closely with calculation.]. 
From (13) it follows that for high values of n the configuration of the inner electrons possesses the same energy 
in all the series of stationary states corresponding to the 
same spectrum (11). The different series of stationary states 
must therefore correspond to different types of orbits of the 
outer electron, involving different relations between energy 
and frequency. In order to fix our ideas, let us for a 
moment consider the helium atom. This atom contains only 
two electrons, and in the previous papers it was assumed 
that in the normal state of the atom the electrons rotate in a 
circular ring round a nucleus. Now the helium spectrum 
contains two complete systems of series given by formulæ of 





[header] 407 

"the type (11) and the measurements of Rau mentioned below 
indicate that the configuration of the inner electron in the 
two corresponding systems of stationary states possesses the 
same energy. A simple assumption is therefore that in one 
of the two systems the orbit of the electron is circular and 
in the other very flat. For high values of n the inner 
electron in the two configurations will act on the outer electron very nearly as a ring of uniformly distributed charge 
with the nucleus in the centre or as a line charge extending 
from the nucleus, respectively. In both cases several 
different types of orbit for the outer electron present themselves, for instance, circular orbits perpendicular to the axis 
of the system or very flat orbits parallel to this axis. The 
different configurations of the inner electrons might be 
due to different ways of removing the electron from the 
neutral atom : thus, if it is removed by impact perpendicular 
to the plane of the ring, we might expect the orbit of the 
remaining electron to be circular, if it is removed by an 
impact in the plane of the ring we might expect the orbit to 
be flat. Such considerations may offer a simple explanation 
of the fact that in contrast with the helium spectrum the 
lithium spectrum contains only one system of series of the 
type (11). The neutral lithium atom contains three electrons, 
and according to the configuration proposed in paper II. the 
two electrons move in an inner ring and the other electron 
in an outer orbit ; for such a configuration we should expect 
that the mode of removal of the outer electron would be 
of no influence on the configuration of the inner electrons. 
It is unnecessary to point out the hypothetical nature of 
these considerations, but the intention is only to show that 
it does not seem impossible to obtain simple interpretations 
of the spectra observed on the general principles of the 
theory. However, in a quantitative comparison with the 
measurements we meet with the difficulties mentioned in 
the first section of applying assumptions analogous with 
C and D to systems for which ordinary mechanics do not 
lead to periodic orbits. 

The above interpretation of the formulæ (11) and (12) 
has recently obtained very strong support by Fowler's work 
on series of enhanced lines on spark spectra [citation redacted]. Fowler 
showed that the frequency of the lines in these spectra, as of 
the lines in the ordinary spectra, can be represented by the 
formula (11). The only difference is that the Rydberg 
constant K in (12) is replaced by a constant 4K, It will be 
seen that this is just what we should expect on the present 



408 [header]

theory if the spectra are emitted by atoms which have lost 
two electrons and are regaining one of them. In this case, 
the outer electron will rotate round a system o£ double 
charge, and we must assume that in the stationary states it 
will have configurations approximately the same as an electron rotating round a helium nucleus. This view seems in 
conformity with the general evidence as to the conditions of 
the excitation of the ordinary spectra and the spectra of 
enhanced lines. From Fowler's results, it will appear that 
the helium spectrum given by (3) for N — 2 has exactly the 
same relation to the spectra of enhanced lines of other 
elements as the hydrogen spectrum has to the ordinary 
spectra. It may be expected that it will be possible to 
observe spectra of a new class corresponding to a loss of 
3 electrons from the atom, and in which the Rydberg constant K is replaced by 9K. No definite evidence, however, 
has so far been obtained of the existence of such spectra [citation redacted]. 

Additional evidence of the essential validity of the interpretation of formula (13) seems also to be derived from the 
result of Stark's experiments on the effect of electric fields 
on spectral lines. For other spectra, this effect is even more 
complex than for the hydrogen spectrum, in some cases 
not only are a great number of components observed, but the 
components are generally not symmetrical with regard to 
the original line, and their distance apart varies from line 
to line in the same series in a far more irregular way than 
for the hydrogen lines [citation redacted]. Without attempting to account 
in detail for any of the electrical effects observed, we shall 
see that a simple interpretation can be given of the general 
way in which the magnitude of the effect varies from series 
to series. 

In the theory of the electrical effect on the hydrogen 
spectrum given in the former section, it was. supposed that 
this effect was due to an alteration of the energy of the 
systems in the external field, and that this alteration was 
intimately connected with a considerable deformation of 
the orbit of the electron. The possibility of this deformation is due to the fact that without the external 
field every elliptical orbit of the electron in the hydrogen 
atom is stationary. This condition will only be strictly 
satisfied if the forces which act upon the electron vary 
exactly as the inverse square of the distance from the 
nucleus, but this will not be the case for the outer electron 
in an atom containing more than one electron. It was pointed 


[header] 409

out in paper IV. that the deviation of the function [phi](n) 
from unity gives us an estimate for the deviation of the 
forces from the inverse square, and that on the theory we 
can only expect a Stark effect of the same order of magnitude as for the hydrogen lines for those series in which [phi]. 
differs very little from unity. 

This conclusion was consistent with Stark's original 
measurements of the electric effect on the different series in 
the helium spectrum, and it has since been found to be 
in complete agreement with the later measurements for a 
great number of other spectral series. An electric effect of 
the same order of magnitude as that for hydrogen lines has 
been observed only for the lines in the two diffuse series of 
the helium spectrum and the diffuse series of lithium. This 
corresponds to the observation that for these three series [phi] is 
very much nearer to unity than for any other series ; even for 
n = 5 the deviation of [phi] from 1 is less than one part in a 
thousand. The distance between the outer components for 
all three series is smaller than that observed for the hydrogen 
line corresponding to the same value of n, but the ratio 
between this distance and that of the hydrogen lines approaches rapidly to unity as n increases. This is just what 
would be expected on the above considerations. The series 
for which the effect, although much smaller, comes next in 
magnitude to the three series mentioned, is the' principal 
single line series in the helium spectrum. This corresponds 
to the fact that the deviation of [phi] from unity, although 
several times greater than for the three first series, is much 
smaller for this series than for any other of the series examined by Stark. For all the other series the effect was 
very small, and in most cases even difficult of detection. 

Quite apart from the question of the detailed theoretical 
interpretation of the formula (13), it seems that it may be 
possible to test the validity of this formula by direct 
measurements of the minimum voltages necessary to produce 
spectral lines. Such measurements have recently been made 
by Rau [citation redacted] for the lines in the ordinary helium spectrum. 
This author found that the different lines within each series 
appeared for slightly different voltages, higher voltages 
being necessary to produce the lines corresponding to higher 
values of n, and he pointed out that the differences between 
the voltages observed were of the magnitude to be expected from the differences in the energies of the different 
stationary states calculated by (13). In addition Rau found 
that the lines corresponding to high values of n appeared for 



410 [header]

very nearly the same voltages for all the different series in 
both helium spectra. The absolute values for the voltages 
could not be determined very accurately with the experimental arrangement, but apparently nearly 30 volts was 
necessary to produce the lines corresponding to high values 
of n. This agrees very closely with the value calculated on 
the present theory for the energy necessary to remove one 
electron from the helium atom, viz., 29*3 volts. On the 
other hand, the later value is considerably larger than the 
ionization potential in helium (20*5 volts) measured directly 
by Franck and Hertz [citation redacted]. This apparent disagreement, 
however, may possibly be explained by the assumption, 
that the ionization potential measured does not correspond to 
the removal of the electron from the atom but only to a transition from the normal state of the atom to some other stationary 
state where the one electron rotates outside the other, and 
that the ionization observed is produced by the radiation 
emitted when the electron falls back to its original position. 
This radiation would be of a sufficiently high frequency to 
ionize any impurity which may be present in the helium 
gas, and also to liberate electrons from the metal part of the 
apparatus. The frequency of the radiation would be 

[formula redacted] , which is of the same order of magnitude 

as the characteristic frequency calculated from experiments 
on dispersion in helium, viz., [formula redacted] [citation redacted] 

Similar considerations may possibly apply also to the 
recent remarkable experiments of Franck and Hertz on 
ionization in mercury vapour [citation redacted]. These experiments show 
strikingly that an electron does not lose energy by collision 
with a mercury atom if its energy is smaller than a certain 
value corresponding to 4*9 volts, but as soon as the energy 
is equal to this value the electron has a great probability 
of losing all its energy by impact with the atom. It 
was further shown that the atom, as the result of such 
an impact, emits a radiation consisting only of the ultraviolet 
mercury line of wave-length 2536, and it was pointed out 
that if the frequency of this line is multiplied by Planck's 
constant, we obtain a value which, within the limit of experimental error, is equal to the energy acquired by an electron 
by a fall through a potential difference of 4'9 volts. Franck 
and Hertz assume that 4'9 volts corresponds to the energy 
necessary to remove an electron from the mercury atom, but 
it seems that their experiments may possibly be consistent 





[header] 411 

with the assumption that this voltage corresponds only to the 
transition from the normal state to some other stationary 
state of the neutral atom. On the present theory we should 
expect that the value for the energy necessary to remove an 
electron from the mercury atom could be calculated from 
the limit of the single line series of Paschen, 1850, 1403, 
1269 [citation redacted]. For since mercury vapour absorbs light of wave- 
length 1850 [citation redacted], the lines of this series as well as the line 2536 
must correspond to a transition from the normal state of the 
atom to other stationary states of the neutral atom (see I. 
p. 16). Such a calculation gives 10*5 volts for the ionization 
potential instead of 4*9 volts [This value is of the same order of magnitude as the value 
12*6 volts recently found by McLennan and Henderson [citation redacted] to he the minimum voltage necessary to 
produce the usual mercury spectrum. The interesting observations 
of single-lined spectra of zinc and cadmium given in their paper are 
analogous to Franck and Hertz's results for mercury, and similar 
considerations may therefore possibly also hold for them.]. If the above considerations 
are correct it will be seen that Franck and Hertz's measurements give very strong support to the theory considered in 
this paper. If, on the other hand, the ionization potential 
of mercury should prove to be as low as assumed by Franck 
and Hertz, it would constitute a serious difficulty for the 
above interpretation of the Rydberg constant, at any rate 
for the mercury spectrum, since this spectrum contains lines 
of greater, frequency than the line 2536. 

It will be remarked that it is assumed that all the spectra 
considered in this section are essentially connected with the 
displacement of a single electron. This assumption — which 
is in contrast to the assumptions used by Nicholson in his 
criticism of the present theory — does not only seem supported 
by the measurements of the energy necessary to produce the 
spectra, but it is also strongly advocated by general reasons 
if we base our considerations on the assumption of stationary 
states. Thus it may happen that the atom loses several 
electrons by a violent impact, but the probability that the 
electrons will be removed to exactly the same distance from 
the nucleus or will fall back into the atom again at exactly 
the same time would appear to be very small. For molecules, 
i. e. systems containing more than one nucleus, we have 
further to take into consideration that if the greater part of 
the electrons are removed there is nothing to keep the nuclei 
together, and that we must assume that the molecules in such 
cases will split up into single atoms (com p. III. p. 858). 

 



412 [header] 

§ 4. The high frequency spectra of the elements. 

In paper II. it was shown that the assumption E led to an 
estimate of the energy necessary to remove an electron from 
the innermost ring of an atom which was in approximate 
agreement with Whiddington's measurements of the minimum kinetic energy of cathode rays required to produce the 
characteristic Röntgen radiation of the K type. The value 
calculated for this energy was equal to the expression (5) if 
n = l. In the calculation the repulsion from the other 
electrons in the ring was neglected. This must result in 
making the value a little too large, but on account of the 
complexity of the problem no attempt at that time was made 
to obtain a more exact determination of the energy. 

These considerations have obtained strong support through 
Moseley's important researches on the high frequency spectra, 
of the elements [citation redacted]. Moseley found that the frequency of the 
strongest lines in these spectra varied in a remarkably simple 
way with the atomic number of the corresponding element. 
For the strongest line in the K radiation he found that 
the frequency for a great number of elements was 
represented with considerable accuracy by the empirical 
formula 

[formula redacted] 

where K is the Rydberg constant in the hydrogen spectrum. 
It will be seen that this result is in approximate agreement 
with the calculation mentioned above if we assume that the 
radiation is emitted as a quantum hv. 

Moseley pointed out the analogy between the formula (14); 
and the formula (3) in section 2, and remarked that the 
constant 3/4 was equal to the last factor in this formula, if 
we put n 1 = l and n 2 = 2. He therefore proposed the explanation of the formula (14), that the line was emitted' 
during a transition of the innermost ring between two states 
in which the angular momentum of each electron was equal 

to [formula redacted] and [formula redacted] respectively. From the replacement of N 2: 

by [formula redacted] he deduced that the number of electrons in the 
ring was equal to 4. This view, however, can hardly be 
maintained. The approximate agreement mentioned above 
with Whiddington's measurements for the energy necessary 
to produce the characteristic radiation indicates very strongly 
that the spectrum is due to a displacement of a single electron, and not to a whole ring. In the latter case the energy 




[header] 413 

should be several times larger. It is also pointed out by 
Nicholson [citation redacted] that Moseley's explanation would imply the 
emission of several quanta at the same time ; but this 
assumption is apparently not necessitated for the explanation 
of other phenomena. At present it seems impossible to 
obtain a detailed interpretation of Moseley's results, but 
much light seems to be thrown on the whole problem by 
some recent interesting considerations by W. Kossel [citation redacted]. 

Kossel takes the view of the nucleus atom and assumes 
that the electrons are arranged in rings, the one outside the 
other. As in the present theory, it is assumed that any 
radiation emitted from the atom is due to a transition of the 
system between two steady states, and that the frequency of 
the radiation is determined by the relation (1). He considers now the radiation which results from the removal of 
an electron from one of the rings, assuming that the radiation is emitted when the atom settles down in its original 
state. The latter process may take place in different ways. 
The vacant place in the ring may be taken by an electron 
coming directly from outside the whole system, but it may 
also be taken by an electron jumping from one of the outer 
rings. In the latter case a vacant place will be left in that 
ring to be replaced in turn by another electron, etc. For 
the sake of brevity, we shall refer to the innermost ring as 
ring 1, the next one as ring 2, and so on. Kossel now 
assumes that the K radiation results from the removal of an 
electron from ring 1, and makes the interesting suggestion 
that the line denoted by Moseley as K a corresponds to the 
radiation emitted when an electron jumps from ring 2 to 
ring 1, and that the line Kp corresponds to a jump from ring 3 
to ring 1. On this view, we should expect that the K radiation 
consists of as many lines as there are rings in the atom, the 
lines forming a series of rapidly increasing intensities. For 
the L radiation, Kossel makes assumptions analogous to 
those for the K radiation, with the distinction that the 
radiation is ascribed to the removal of an electron from 
ring 2 instead of ring 1. A possible M radiation is ascribed 
to ring 3, and so on. The interest of these considerations is 
that they lead to the prediction of some simple relations 
between the frequencies v of the different lines. Thus it 
follows as an immediate consequence of the assumption used 
that we must have 

[formula redacted]


414 [header]

It will be seen that these relations correspond exactly to the 
ordinary principle of combination of spectral lines. By 
using Moseley's measurements for K a and K[beta] and extrapolating for the values of L a by the help of MoseleyV 
empirical formula, Kossel showed that the first relation was 
closely satisfied for the elements from calcium to zinc. 
Recently T. Maimer [citation redacted] has measured the wave-length of K a 
and K^ for a number of elements of higher atomic weight, 
and it is therefore possible to test the relation over a wider 
range and without extrapolation. The table gives Maimer's 
values for [formula redacted] and Moseley's values for [formula redacted] , all values 

being multiplied by 10 17 . 

[formula redacted]

It is seen that the agreement is close, and probably within 
the limits of experimental error. A comparison with the 
second relation is not possible at present, and we meet also 
here with a difficulty arising from the fact that Moseley 
observed a greater number of lines in the L radiation than 
should be expected on Kossel's simple scheme [citation redacted] . 

There is another point in connexion with the above considerations which appears to be of interest. In a recent 
paper W. H. Bragg [citation redacted] has shown that, in order to excite any 
line of the K radiation of an element, the frequency of the 
exciting radiation must be greater than the frequency of all 
the lines in the K radiation. This result, which is in striking 
contrast to the ordinary phenomena of selective absorption, 
can be simply explained on Kossel's view. The simple 
reverse of the process corresponding to the emission of, for 
instance, K a would necessitate the direct transfer of an electron from ring 1 to ring 2, but this will obviously not be 
possible unless at the beginning of the process there was a 
vacant place in the latter ring. For the excitation of any 
line in the K radiation, it is therefore necessary that the 
electron should be completely removed from the atom. 
Another consequence of Kossel's view is that it should be 
impossible to obtain the K series of an element without the 
simultaneous emission of the L series. This seems to be in. 


[header] 415 

agreement with some recent experiments of C. Gr. Barkla [citation redacted] 
on the energy involved in the production of characteristic 
Röntgen radiation. From these examples it will be seen 
that even if Kossel's considerations will need modification 
in order to account in detail for the high frequency spectra, 
they seem to offer a basis for a further development. 

As in the former section, it is assumed that the spectra 
considered above are due to the displacement of a single 
electron. If, however, several electrons should happen to be 
removed from one of the rings by a violent impact, the considerations at the end of the former section would not apply, 
since the electrons removed in this case can be replaced by 
electrons in the other rings. We might therefore possibly 
expect that the rearrangement of the electrons, consequent 
to the removal of more than one electron from a ring, would 
give rise to spectra of still higher frequency than those 
considered in this section. 

University of Manchester, 
August 1915.