Answer:
[tex]=2,012,319.36 \ m/s[/tex]
Explanation:
-The only relevant force is the electrostatic force
-The formula for the electrostatic force is:
[tex]F = Eq[/tex]
E is the electric field and q is the magnitude of the charge.
#Since the electric field is the same in both cases, and the charge of the protons and electrons have the same magnitude, you can state that the magnitude of the electric forces acting in both proton and electron are the same.
[tex]F_e = F_p\\\\F_e= Force \ on \ electron\\F_p = Force \ on \ proton[/tex]
-Applying Newton's 2nd Law:
[tex]F=ma[/tex]
[tex]F_e=M_ea_e[/tex]
[tex]F_p=M_pa_p[/tex]
#equate the two forces:
[tex]F_e = F_p\\\\M_ea_e=M_pa_p\\\\a_e=\frac{M_pa_p}{M_e}[/tex]
#The equations for velocity in uniform acceleration:
[tex]V_f^2=V_o^2+2ad\\\\V_o^2=0\\\\\therefore V_f^2=2ad[/tex]
#For the proton:
[tex]V_f^2=2a_pd\\\\a_p=\frac{V_f^2}{2d}\\\\a_p=\frac{47000m/s)^2}{2d}[/tex]
#For the electron:
[tex]V_f^2=2{a_e}^2\times 2d\\\\A_e=M_p\times A_p/M_e\\\\V_f^2=M_p\times (47000m/s)^2/2d\times2d/M_e\\\\V_f^2=M_p\times (47000m/s)^2/M_e\\\\V_f=47000m/s\times\sqrt{\frac{M_p}{M_e}}[/tex]
The mass values of the proton and electron are:
[tex]M_p=1.67\times 10^{-27} kg\\\\M_e=9.11\times10^{-31}kg[/tex]
The speed of the ion is therefore calculated as:
[tex]V_f=47000m/s\times\sqrt{\frac{M_p}{M_e}}\\\\=47000m/s\times\sqrt{\frac{1.67\times10^{-27}}{9.11\times10^{-31}}\\\\=2,012,319.36 \ m/s[/tex]
Hence, the ion's speed at the negative plate is [tex]=2,012,319.36 \ m/s[/tex]
