Page:A Treatise on Electricity and Magnetism - Volume 2.djvu/128

The reading of the torsion circle should now be adjusted, so that the coefficient of ${\displaystyle \tau ^{\prime }}$ may be as nearly as possible zero. For this purpose we must determine ${\displaystyle \lambda }$, the value of ${\displaystyle \alpha -\beta }$ when there is no torsion. This may be done by placing a non-magnetic bar of the same weight as the magnet in the stirrup, and determining ${\displaystyle \alpha -\beta }$ when there is equilibrium. Since ${\displaystyle \tau ^{\prime }}$ is small, great accuracy is required. Another method is to use a torsion bar of the same weight as the magnet, containing within it a very small magnet whose magnetic moment is ${\displaystyle {\tfrac {1}{n}}}$ of that of the principal magnet. Since ${\displaystyle \tau }$ remains the same, ${\displaystyle \tau ^{\prime }}$ will become ${\displaystyle n\tau ^{\prime }}$, and if ${\displaystyle \zeta _{1}}$ and ${\displaystyle \zeta _{1}^{\prime }}$ are the values of ${\displaystyle \zeta }$ as found by the torsion bar,

${\displaystyle \delta ={\tfrac {1}{2}}(\zeta _{1}+\zeta _{1}^{\prime })+{\tfrac {1}{2}}n\tau ^{\prime }(\zeta _{1}+\zeta _{1}^{\prime }-2(\beta +\lambda )).}$

(12)

Subtracting this equation from (11),

${\displaystyle 2(n-1)(\beta +\lambda )=(n+{\frac {1}{\tau ^{\prime }}})(\zeta _{1}+\zeta _{1}^{\prime })-(1+{\frac {1}{\tau ^{\prime }}})(\zeta +\zeta ^{\prime }).}$

(13)

Having found the value of ${\displaystyle \beta +\lambda }$ in this way, ${\displaystyle \beta }$, the reading of

the torsion circle, should he altered till

${\displaystyle \zeta +\zeta ^{\prime }-2(\beta +\lambda )=0,}$

(14)

as nearly as possible in the ordinary position of the apparatus.

Then, since ${\displaystyle \tau ^{\prime }}$ is a very small numerical quantity, and since its coefficient is very small, the value of the second term in the expression for ${\displaystyle \delta }$ will not vary much for small errors in the values of ${\displaystyle \tau ^{\prime }}$ and ${\displaystyle \lambda }$, which are the quantities whose values are least accurately known.

The value of ${\displaystyle \delta }$, the magnetic declination, may be found in this way with considerable accuracy, provided it remains constant during the experiments, so that we may assume ${\displaystyle \delta ^{\prime }=\delta }$.

When great accuracy is required it is necessary to take account ot the variations of ${\displaystyle \delta }$ during the experiment. For this purpose observations of another suspended magnet should be made at the some instants that the different values of ${\displaystyle \zeta }$ are observed, and if ${\displaystyle \eta ,\eta ^{\prime }}$ are the observed azimuths of the second magnet corresponding to ${\displaystyle \zeta }$and ${\displaystyle \zeta ^{\prime }}$, and if ${\displaystyle \delta }$ and ${\displaystyle \delta ^{\prime }}$ are the corresponding values of ${\displaystyle \delta }$, then

${\displaystyle \delta ^{\prime }-\delta =\eta ^{\prime }-\eta .}$

(15)

Hence, to find the value of ${\displaystyle \delta }$ we must add to (11) a correction

${\displaystyle {\tfrac {1}{2}}(\eta -\eta ^{\prime }).}$

(15)

The declination at the time of the first observation is therefore

${\displaystyle \delta ={\tfrac {1}{2}}(\zeta _{1}+\zeta _{1}^{\prime }+\eta -\eta ^{\prime })+{\tfrac {1}{2}}\tau ^{\prime }(\zeta +\zeta ^{\prime }-2\beta -2\lambda ).}$

(16)