A small sphere of charge q1 = 0.880 μC hangs from the end of a spring...
A small sphere of charge q1 = 0.864 µC hangs from the end of a spring as
in Figure a. When another small sphere of charge
q2 = -0.66
µC is held beneath the first sphere as in Figure b, the spring
stretches by d = 3.27
cm from its original length and reaches a new equilibrium position
with a separation between the charges of r = 4.80 cm. What is the force constant of the
spring?
N/m
A small pith ball with a charge of -0.600 µC hangs from the end
of a spring as in as in the figure. When another small pith ball of
charge 0.400 µC is held beneath the first pith ball, the spring
stretches by d from its original length and reaches a new
equilibrium position with a separation between the charges of r =
5.00 cm. If the spring constant of the spring is 56.0 N/m, what is
the distance d...
A small sphere of charge q-0.784 JC hangs from the end of a the spring stretches by d 3.21 cm from its original length and reaches a new equlbrium position with a separation between the charges of r 5.20 cm. What is the force constant of the N/m 91 Need Help?
Coulomb’s Law
A massless sphere of charge q1 = 0.640 µC is at the end of a
spring in equilibrium as shown below in figure a. When a charge q2
= -0.410 µC is held beneath the positively charged sphere as shown
in figure b, the spring stretches by a distance d = 3.60 cm from
its position in figure a. When equilibrium is reestablished, the
distance r between the charges is 5.20 cm. What is the spring
constant of...
el the forces (2) acting on q1 in figure P22.32b. Gravity (mg i s not a force in this problem ) Write down the equation for 2Fy, the forces acing on qi- This will be in terms of the variable k. c) Solve this equation for k. Remember to convert the distances from cm to m 32. A small sphere of charge Figure P22.31 = 0.800 μ C hangs from the end oa When another sina irst sphere as ins...
A small metal sphere, carrying a net charge of q1 = -2.70 μC , is held in a stationary position by insulating supports. A second small metal sphere, with a net charge of q2 = -7.50 μC and mass 1.70 g , is projected toward q1. When the two spheres are 0.800 m apart, q2 is moving toward q1 with speed 22.0 m/s (Figure 1). Assume that the two spheres can be treated as point charges. What is the speed...
A small metal sphere, carrying a net charge of q1 = -2.70 μC ,
is held in a stationary position by insulating supports. A second
small metal sphere, with a net charge of q2 = -7.50 μC and mass
1.70 g , is projected toward q1. When the two spheres are 0.800 m
apart, q2 is moving toward q1 with speed 22.0 m/s(Figure 1). Assume
that the two spheres can be treated as point charges. You can
ignore the force...
A small metal sphere, carrying a net charge of q1 = -2.70 μC , is held in a stationary position by insulating supports. A second small metal sphere, with a net charge of q2 = -7.50 μC and mass 1.80 g , is projected toward q1. When the two spheres are 0.800 m apart, q2 is moving toward q1 with speed 22.0 m/s (Figure 1). Assume that the two spheres can be treated as point charges. You can ignore the...
A tiny sphere with a charge of 9.2 μC is attached to a spring. Consider this position to be the origin. ONE other tiny charged sphere with a charge of − 7.6 μC, is placed in the position 18.2 cm directly vertically below and 13.3 cm to the right of the 9.2 μC charge. The spring stretches 3.4 cm from its previous equilibrium position toward the − 7.6 μC. Draw a diagram showing the position of the two charges and...
A positive charge q1 = 2.90 μc on a frictionless horizontal surface is attached to a spring of force constant k as in the figure shown below. when a charge of q2 =-9.100 μC is placed 9.50 cm away from the positive charge, the spring stretches by 5.00 mm, reducing the distance between charges to d = 9.00 cm. Find the value of k. The response you submitted has the wrong sign. N/m 1 42