Respuesta :
Answer:
q_2 = (+,-) 5.9 *10^-6 C , q_2 = (+,-) 3.4*10^-6 C
q_1 = (+,-) 3.4*10^-6 C , q_1 = (+,-) 5.9*10^-6 C
q_3 = q_4 = (+, -) 1.25*10^-6 C
Explanation:
Given:
F_1,2 = 0.7214 N
F_3,4 = 0.0562 N
separation r = 0.5 m (remains constant)
q_1 and q_2 opposite charged before transfer
q_3 and q_4 same charge after transfer
Solution:
F_1,2 = k*q_1*q_2 / r^2 = -0.7214 N (Attraction)
q_1*q_2 = -2.00612*10^-11 .... 1
F_3,4 = k*q_3*q_4 / r^2 = +0.0562 N (Repulsion)
q_3*q_4 = 1.5628*10^-12 .... 2
Conservation of charge:
Since, no charge is lost the total charge before and after transfer must be same. Hence,
q_1 + q_2 = q_3 + q_4 ..... 3
Also, electrons are transferred till the all the positive charge is neutralized. Such that after transfer both charges are equal, Hence:
q_3 = q_4 ..... 4
Now we have 4 equations and four unknowns q_1, q_2, q_3, and q_4. These equations can now be solved simultaneously as follows:
Solving for unknowns:
Using 3 and 4
q_3 = q_4 = 0.5*( q_1 + q_2 ) .... 5
Using 1 , 2, and 5
q_1 = -2.00612*10^-11 / q_2 ..... 6
0.25*( q_1 + q_2 )^2 = 1.5628*10^-12 .... 7
Using 6 and 7
(q_1 ^2 + 2*q_1*q_2 + q_2^2) = 6.2512*10^-12
(4.025*10^-22 / q_2^2) - (4.01224*10^-11) + q_2^2) = 6.2512*10^-12
q_2^4 - q_2^2 *4.6374*10^-11 + 4.025*10^-22 = 0
Making substitution for disguised quadratic:
q_2^2 = x
x^2 - x^2 *4.6374*10^-11 + 4.025*10^-22 = 0
[tex]x_1 = \frac{(4.6374*10^-11)+\sqrt{(4.6374*10^-11)^2 - 4(1)*(4.025*10^-22)} }{2} \\\\x_1 = \frac{(4.6374*10^-11)+ (2.325*10^-11)}{2} \\\\x_1 = 3.4812*10^-11\\\\x_2 = \frac{(4.6374*10^-11)-\sqrt{(4.6374*10^-11)^2 - 4(1)*(4.025*10^-22)} }{2} \\\\x_2 = \frac{(4.6374*10^-11)- (2.325*10^-11)}{2} \\\\x_2 = 1.15622*10^-11[/tex]
Hence,
After Back substitution:
q_2 = (+,-) 5.9 *10^-6 C , q_2 = (+,-) 3.4*10^-6 C
q_1 = (+,-) 3.4*10^-6 C , q_1 = (+,-) 5.9*10^-6 C
q_3 = q_4 = (+, -) 1.25*10^-6 C
