Thomson Experiment with Exact Trajectory Geometry

Problem Statement

In a three-dimensional Cartesian coordinate system $(x, y, z)$(x,y,z), an electron (mass $m$m, charge $-e$−e, $e > 0$e>0) is accelerated from rest through a potential difference $V$V and injected from the origin $(0, 0, 0)$(0,0,0) in the $+x$+x direction with initial speed $v_0$v0​. Gravity and relativistic effects are negligible.

Step 1: Velocity Selector In the region $0 \le x \le L$0≤x≤L, a uniform electric field $\vec{E} = (0, E_0, 0)$E=(0,E0​,0) and a uniform magnetic field $\vec{B} = (0, 0, B_0)$B=(0,0,B0​) are applied simultaneously. The injected electron travels straight along the $x$x-axis without any deflection.

Step 2: Magnetic Deflection The electric field is turned off ($\vec{E} = \vec{0}$E=0), while the magnetic field $\vec{B}$B remains. The same electron with initial speed $v_0$v0​ is injected again from the origin. Inside $0 \le x \le L$0≤x≤L, the electron is deflected by the Lorentz force and follows a curved path in the $xy$xy-plane, exiting the magnetic field region through the plane $x = L$x=L.

Step 3: Drift Space The region $x > L$x>L is a field-free drift space. The electron travels in a straight line and hits a fluorescent screen (parallel to the $yz$yz-plane) placed at $x = L + D$x=L+D. The $y$y-coordinate of the impact point on the screen is recorded as displacement $Y$Y.

The instrument is precisely set up with drift length $D = \sqrt{3}L$D=3​L. The observed displacement on the screen is exactly $Y = (3 - \sqrt{3})L$Y=(3−3​)L.

From these results, find the specific charge $e/m$e/m of the electron.

Important: Do not use any small-angle approximation (such as $\sin\theta \approx \theta$sinθ≈θ or $y \approx L^2/(2R)$y≈L2/(2R)). Derive the result using exact geometric relations.

Constraints

• Uniform electric field strength: $E_0 = 1.76 \times 10^4\,\mathrm{V/m}$E0​=1.76×104V/m
• Uniform magnetic flux density: $B_0 = 1.0 \times 10^{-3}\,\mathrm{T}$B0​=1.0×10−3T
• Length of magnetic field region: $L = 5.0 \times 10^{-2}\,\mathrm{m}$L=5.0×10−2m

Input Format

The specific charge $e/m$e/m can be written as $A \times 10^{11}\,\mathrm{C/kg}$A×1011C/kg for some real number $A$A.

Compute $100A$100A and give the answer as a positive integer.