and the amount of the energy reflected in the same time
ρ
′
(
B
cos
r
−
c
)
=
ρ
′
B
(
cos
r
−
σ
)
.
{\displaystyle \rho '({\mathfrak {B}}\ \cos \ r-c)=\rho '{\mathfrak {B}}(\cos \ r-\sigma ).}
The difference of these two expressions must be equal to the work of the radiation pressure per unit time. Thus it must be
P
c
=
ρ
′
B
(
cos
r
−
σ
)
−
ρ
B
(
cos
i
+
σ
)
{\displaystyle Pc=\rho '{\mathfrak {B}}(\cos \ r-\sigma )-\rho {\mathfrak {B}}(\cos \ i+\sigma )}
Or
c
P
=
B
ρ
(
cos
i
+
σ
)
[
(
1
+
σ
cos
i
1
−
σ
cos
r
)
2
cos
r
−
σ
cos
i
+
σ
−
1
]
.
{\displaystyle cP={\mathfrak {B}}\rho (\cos \ i+\sigma )\left[\left({\frac {1+\sigma \cos \ i}{1-\sigma \cos \ r}}\right)^{2}{\frac {\cos \ r-\sigma }{\cos \ i+\sigma }}-1\right].}
With the aid of the easily derivable relation, already given by Abraham :[1]
1
+
σ
cos
i
1
−
σ
cos
r
=
σ
+
cos
i
σ
−
cos
r
=
sin
i
sin
r
{\displaystyle {\frac {1+\sigma \cos \ i}{1-\sigma \cos \ r}}={\frac {\sigma +\cos \ i}{\sigma -\cos \ r}}={\frac {\sin \ i}{\sin \ r}}}
and the equation:[2]
sin
r
=
sin
i
(
1
−
σ
2
)
1
+
σ
2
+
2
σ
cos
i
{\displaystyle \sin \ r={\frac {\sin \ i(1-\sigma ^{2})}{1+\sigma ^{2}+2\sigma \ \cos \ i}}}
it becomes
c
P
=
B
ρ
(
cos
i
+
σ
)
[
1
+
σ
2
+
2
σ
cos
i
i
−
σ
2
−
1
]
.
{\displaystyle cP={\mathfrak {B}}\rho (\cos \ i+\sigma )\left[{\frac {1+\sigma ^{2}+2\sigma \ \cos \ i}{\ i-\sigma ^{2}}}-1\right].}
and
P
=
2
ρ
(
cos
i
+
σ
)
2
1
−
σ
2
.
{\displaystyle P=2\rho {\frac {(\cos \ i+\sigma )^{2}}{1-\sigma ^{2}}}.}
The agreement with the value given by Abraham is thus a complete one (here,
σ
{\displaystyle \sigma }
has the opposite sign as earlier.)
Of course, upon this foundation one can calculate the values
p
1
{\displaystyle p_{1}}
and
p
2
{\displaystyle p_{2}}
, when one assumes that a moving body is emanating waves, whose amplitude is the same as in the stationary state, while the density of the radiation energy is inversely proportional to the square of the wavelength.
↑ L. c. eq. 7e.
↑ See F. Hasenöhrl , l. c. p. 489, eq. 12.