On the Aberration of Light

​

The general explanation of the phænomenon of aberration is so simple, and the coincidence of the value of the velocity of light thence deduced with that derived from observations of eclipses of Jupiter's satellites so remarkable, as to leave no doubt on the mind as to the truth of that explanation. But when we examine the cause of the phænomenon more closely, it is far from being so simple as it appears at first sight. On the theory of emissions, indeed, there is little difficulty; and it would seem that the more particular explanation of the cause of aberration usually given, which depends on the consideration of the motion of a telescope as light passes from its object-glass to its cross wires, has reference especially to this theory; for it does not apply to the theory of undulations, unless we make the rather startling hypothesis, that the luminiferous æther passes freely through the sides of the telescope and through the earth itself. The undulatory theory of light, however, explains so simply and so beautifully the most complicated phænomena, that we are naturally led to regard aberration as a phænomenon unexplained by it, but not incompatible with it.

The object of the present communication is to attempt an explanation of the cause of aberration which shall be in accordance with the theory of undulations. I shall suppose that the earth and planets carry a portion of the æther along with them so that the æther close to their surfaces is at rest relatively to those surfaces, while its velocity alters as we recede ​from the surface, till, at no great distance, it is at rest in space. According to the undulatory theory, the direction in which a heavenly body is seen is normal to the fronts of the waves which have emanated from it, and which have reached the neighbourhood of the observer, the æther near him being supposed to be at rest relatively to him. If the æther in space were at rest, the front of a wave of light at any instant being given, its front at any future time could be found by the method explained in Airy's Tracts. If the æther were in motion, and the velocity of propagation of light were infinitely small, the wave's front would be displaced as a surface of particles of the æther. Neither of these suppositions is however true, for the æther moves while light is propagated through it. In the following investigation I suppose that the displacements of a wave's front in an elementary portion of time due to the two causes just considered take place independently.

Let ${\displaystyle u,v,w}$ be the resolved parts along the rectangular axes of ${\displaystyle x,y,z}$, of the velocity of the particle of æther whose co-ordinates are ${\displaystyle x,y,z}$, and let ${\displaystyle V}$ be the velocity of light supposing the æther at rest. In consequence of the distance of the heavenly bodies, it will be quite unnecessary to consider any waves but those which are plane, except in so far as they are distorted by the motion of the æther. Let the axis of ${\displaystyle z}$ be taken in, or nearly in the direction of propagation of the wave considered, so that the equation to the wave's front at any time will be

${\displaystyle z=C+VT+\zeta }$

(1.)

${\displaystyle C}$ being a constant, ${\displaystyle t}$ the time, and ${\displaystyle \zeta }$ a small quantity, a function of ${\displaystyle x,y}$ and ${\displaystyle t}$. Since ${\displaystyle u,v,w}$ and ${\displaystyle \zeta }$ are of the order of the aberration, their squares and products may be neglected.

Denoting by ${\displaystyle \alpha ,\beta ,\gamma }$ the angles which the normal to the wave's front at the point ${\displaystyle (x,y,z)}$ makes with the axes, we have, to the first order of approximation,

${\displaystyle \cos \alpha =-{\frac {d\zeta }{dx}},\ \cos \beta =-{\frac {d\zeta }{dy}},\ \cos \gamma =1;}$

(2.)

and if we take a length ${\displaystyle Vdt}$ along this normal, the co-ordinates of its extremity will be

${\displaystyle x-{\frac {d\zeta }{dx}}Vdt,\ y-{\frac {d\zeta }{dy}}Vdt,\ z+Vdt}$

If the æther were at rest, the locus of these extremities would be the wave's front at the time ${\displaystyle t+dt}$, but since it is in motion, the co-ordinates of those extremities must be further increased by ${\displaystyle udt}$, ${\displaystyle vdt}$, ${\displaystyle wdt}$. Denoting then by ${\displaystyle x',y',z'}$ the co-ordinates of the point of the wave's front at the time ${\displaystyle t+dt}$, ​which corresponds to the point (${\displaystyle x,y,z}$) in its front at the time ${\displaystyle t}$, we have

${\displaystyle x'=x+\left(u-V{\frac {d\zeta }{dx}}\right)dt,\ y'=y+\left(v-V{\frac {d\zeta }{dy}}\right)dt,\ z'=z+(w+V)dt;}$

and eliminating ${\displaystyle x,y}$ and ${\displaystyle z}$ from these equations and (1.), and denoting ${\displaystyle \zeta }$ by ${\displaystyle f(x,y,t)}$, we have for the equation to the wave's front at the time ${\displaystyle t+dt}$

${\displaystyle z'-(w+V)dt=C+Vt+f\left\{x'-\left(u-V{\frac {d\zeta }{dx}}\right)dt,\ y'-\left(v-V{\frac {d\zeta }{dy}}\right)dt,t\right\}}$

or, expanding, neglecting ${\displaystyle dt^{2}}$ and the square of the aberration, and suppressing the accents of ${\displaystyle x,y}$ and ${\displaystyle z}$,

${\displaystyle z=C+VT+\zeta +(w+V)dt}$

(3.)

But from the definition of ${\displaystyle \zeta }$ it follows that the equation to the wave's front at the time ${\displaystyle t+dt}$ will be got from (1.) by putting ${\displaystyle t+dt}$ for ${\displaystyle t}$, and we have therefore for this equation,

${\displaystyle z=C+VT+\zeta +\left(V+{\frac {d\zeta }{dt}}\right)dt}$

(4.)

Comparing the identical equations (3.) and (4.), we have

This equation gives ${\displaystyle \zeta =\int wdt}$: but in the small term ${\displaystyle \zeta }$ we may replace ${\displaystyle \int wdt}$ by ${\displaystyle {\tfrac {1}{V}}\int wdz}$: this comes to taking the approximate value of ${\displaystyle z}$ given by the equation ${\displaystyle z=C+Vt}$, instead of ${\displaystyle t}$, for the parameter of the system of surfaces formed by the wave's front in its successive positions. Hence equation (1.) becomes

${\displaystyle z=C+Vt+{\frac {1}{V}}\int wdz}$

Combining the value of ${\displaystyle \zeta }$ just found with equations (2.), we get, to a first approximation,

${\displaystyle \alpha -{\frac {\pi }{2}}={\frac {1}{V}}\int {\frac {dw}{dx}}dz,\ \beta -{\frac {\pi }{2}}={\frac {1}{V}}\int {\frac {dw}{dy}}dz}$

(5.)

equations which might very easily be proved directly in a more geometrical manner.

If random values are assigned to ${\displaystyle u,v}$ and ${\displaystyle w}$, the law of aberration resulting from these equations will be a complicated ​one; but if ${\displaystyle u,v}$ and ${\displaystyle w}$ are such that ${\displaystyle udv+vdy+wdz}$ is an exact differential, we have

${\displaystyle {\frac {dw}{dx}}={\frac {du}{dz}},\ {\frac {dw}{dy}}={\frac {dv}{dz}}}$

whence, denoting by the suffixes 1, 2 the values of the variables belonging to the first and second limits respectively, we obtain

${\displaystyle \alpha _{2}-\alpha _{1}={\frac {u_{2}-u_{1}}{V}},\ \beta _{2}-\beta _{1}={\frac {v_{2}-v_{1}}{V}}}$

(6.)

If the motion of the æther be such ${\displaystyle udx+vdy+wdz}$ is an exact differential for one system of rectangular axes, it is easy to prove, by the transformation of co-ordinates, that it is an exact differential for any other system. Hence the formulae (6.) will hold good, not merely for light propagated in the direction first considered, but for light propagated in any direction, the direction of propagation being taken in each case for the axis of ${\displaystyle z}$. If we assume that ${\displaystyle udx+vdy+wdz}$ is an exact differential for that part of the motion of the æther which is due to the motions of translation of the earth and planets, it does not therefore follow that the same is true for that part which depends on their motions of rotation. Moreover, the diurnal aberration is too small to be detected by observation, or at least to be measured with any accuracy, and I shall therefore neglect it.

It is not difficult to show that the formulae (6.) lead to the known law of aberration. In applying them to the case of a star, if we begin the integrations in equations (5.) at a point situated at such a distance from the earth that the motion of the æther, and consequently the resulting change in the direction of the light, is insensible, we shall have ${\displaystyle u_{1}=0,\ v_{1}=0}$; and if, moreover, we take the plane ${\displaystyle xz}$ to pass through the direction of the earth's motion, we shall have

and

that is, the star will appear to be displaced towards the direction in which the earth is moving, through an angle equal to the ratio of the velocity of the earth to that of light, multiplied by the sine of the angle between the direction of the earth's motion and the line joining the earth and the star.

In considering the effect of aberration on a planet, it will be convenient to divide the integrations in equation (5.) into three parts, first integrating from the point considered on the surface of the planet to a distance at which the motion of the ​æther may be neglected, then to a point near the earth where we may still neglect the motion of the æther, and lastly to the point of the earth's surface at which the planet is viewed. For the first part we shall have ${\displaystyle u_{2}=0,\ v_{2}=0}$, and ${\displaystyle u_{1},v_{1}}$ will be the resolved parts of the planet's velocity. The increments of ${\displaystyle \alpha }$ and ${\displaystyle \beta }$ for the first interval will be, therefore, ${\displaystyle -{\tfrac {u_{1}}{V}},\ {\tfrac {v_{1}}{V}}}$. For the second interval ${\displaystyle \alpha }$ and ${\displaystyle \beta }$ will remain constant, while for the third their increments will be ${\displaystyle {\tfrac {u_{2}}{V}},\ {\tfrac {v_{2}}{V}}}$, just as in the case of a star, ${\displaystyle u_{2}}$ and ${\displaystyle v_{2}}$ being now the resolved parts of the earth's velocity.

Fig. 1 represents what is conceived to take place. ${\displaystyle P}$ is the planet in the position it had when the light quitted it; ${\displaystyle E}$ the earth in the position it has when the light reaches it. The lines ${\displaystyle ab,cd}$, &c. represent a small portion of a wave of light in its successive positions. The arrows represent the directions in which ${\displaystyle P}$ and ${\displaystyle E}$ may be conceived to move. The breadth ${\displaystyle ab}$ is supposed to be comparable to the breadth of a telescope. In fig. 2, ${\displaystyle pmne}$ represents an orthogonal trajectory to the surfaces ${\displaystyle ab,cd}$, &c. ; ${\displaystyle p}$ is the point of the planet from which the light starts, ${\displaystyle e}$ the point of the earth which it reaches. The trajectory ${\displaystyle pmne}$ may be considered a straight line, except near the ends ${\displaystyle p}$ and ${\displaystyle e}$, where it will be a little curved, as from ${\displaystyle p}$ to ${\displaystyle m}$ and from ${\displaystyle e}$ to ${\displaystyle n}$. The curvature at ${\displaystyle e}$ will have the same effect on the apparent position of the planet as it would have on that of a star in the same direction : as to the curvature at ${\displaystyle p}$, if we draw ${\displaystyle pq}$ perpendicular to ${\displaystyle mn}$ produced, the curvature will have the effect of causing ${\displaystyle p}$ to be seen as if it were at ${\displaystyle q}$. Now the angle between the tangents at ${\displaystyle p}$ and ${\displaystyle m}$ being that through which a star in the direction of ${\displaystyle e}$ is displaced by aberration to an observer at ${\displaystyle p}$, and the distance ​${\displaystyle pm}$ being by hypothesis small (two or three radii of the planet suppose), it follows that the angle ${\displaystyle peq}$ is extremely small, and may be neglected. Hence a planet will appear to be displaced from the position which it had when the light left it, just as a star in the same direction is displaced. But besides this, the planet has moved from ${\displaystyle P}$ while the light has been travelling to ${\displaystyle E}$. These two considerations combined lead to the formula for aberration, which is applicable to the planets, as is shown in treatises on astronomy. The same reasoning which applies to a planet will apply equally to the sun, the moon, or a comet.

To give an idea of the sort of magnitudes neglected in neglecting ${\displaystyle pq}$, suppose ${\displaystyle pm}$ equal to the diameter of ${\displaystyle P}$, and suppose the curvature from ${\displaystyle p}$ to ${\displaystyle m}$ uniform. Let ${\displaystyle r}$ be the radius of ${\displaystyle P}$, ${\displaystyle v}$ its velocity, and ${\displaystyle R}$ the distance ${\displaystyle PE}$. The greatest possible value of the angle between the tangents at ${\displaystyle p}$ and ${\displaystyle m}$ is ${\displaystyle {\tfrac {v}{V}}}$. In this case we should have ${\displaystyle \angle pep={\tfrac {vr}{VR}}={\tfrac {v}{V}}D}$, ${\displaystyle D}$ being the semidiameter of ${\displaystyle P}$ as seen from ${\displaystyle E}$. Hence the angle ${\displaystyle peq}$ must be very much greater for the moon than for any other body of the solar system; for in the case of the planets the value of ${\displaystyle v}$ is in no instance double its value for the earth or moon, while their discs are very small compared with that of the moon; and in the case of the sun, although its disc is about as large as that of the moon, its velocity round the centre of gravity of the solar system is very small. It would indeed be more correct to suppose the sun's centre absolutely at rest, since all our measurements are referred to it, and not to the centre of gravity of the solar system. Taking then the case of the moon, and supposing ${\displaystyle {\tfrac {v}{V}}={\tfrac {20''}{180^{\circ }}}\pi }$, ${\displaystyle D}$ =15′, we find that the angle ${\displaystyle peq}$ is about ${\displaystyle {\tfrac {1}{11}}}$th of a second, an insensible quantity.

If we suppose the whole solar system to be moving in space with a velocity comparable with that of the earth round the sun, it follows from the linearity of the equations employed, that we may consider this motion separately. It is easy to show, that as far as regards this motion, the sun, moon, and planets will come into the positions in which they are seen just at the instant that the light from them reaches the earth. With respect to the stars also, that part of the aberration which varies with the time of year, the only part which can be observed, will not be affected. If we suppose the æther which fills the portion of space occupied by the solar system to be moving in a current, with a velocity comparable with that of the earth in its orbit, the result will still be the same. For if ​we suppose a velocity equal and opposite to that of the æther to be impressed, both on the æther and on the bodies of the solar system, the case is reduced to that of the solar system moving through the æther supposed to be at rest.