A charge of 19 nC is uniformly distributed along a straight rod of length 4.2 m...
A charge of 17 nC is uniformly distributed along a straight rod of length 4.4 m that is bent into a circular arc with a radius of 2.1 m. What is the magnitude of the electric field at the center of curvature of the arc?
A charge of 18 nC is uniformly distributed along a straight rod of length 11 m that is bent into a circular arc with a radius of 3.7 m. What is the magnitude of the electric field at the center of curvature of the arc?
8. A charge of 20 nC is uniformly distributed along a straight rod of length 4.0m. If is then bent into a circular arc of radius 2.0 m. What is the magnitude of the electric field at the center of curvature of the arc?
In the figure shown above, a plastic rod having a uniformly distributed charge -4.2 mu or micro C has been bent into a circular arc of radius 24 cm and central angle 101degrees (degrees). With V = 0 at infinity, what is the electric potential at P, the center of curvature of the rod?
Could you please show all work, so I can better understand this problem? A charge of 15 nC is uniformly distributed along a straight rod of length 4.8 m that is bent into a circular arc with a radius of 2.1 m. What is the magnitude of the electric field at the center of curvature of the arc? N/C
Question1 Charge +Q +1.10 nC is uniformly distributed along the right half of a thin rod bent into a semicirle of radius R- 3.20 cm, while charge Q1.10 nC is uniformly distributed along the left half of the rod, as shown in the figure. What is the magnitude of the electric field at point P the centre of the circle? Magnitude:
+3.20 nC of charge is uniformly distributed along the top half of a thin rod of total length L = 3.40 cm, while -3.20 nC of charge is uniformly distributed along the bottom half of the rod, as shown in the figure, what is the magnitude of the electric field at the dot, a distance r= 20.0 cm from the centre of the rod?
Charge Q is uniformly distributed along a thin, flexible rod of length L. The rod is then bent into the semicircle shown in the figure (Figure 1).Part AFind an expression for the electric field \(\vec{E}\) at the center of the semicircle. Hint: A small piece of arc length \(\Delta s\) spans a small angle \(\Delta \theta=\Delta s / R,\) where R is the radius.Express your answer in terms of the variables Q, L, unit vectors \(\hat{i}, \hat{j},\) and appropriate constants.Part BEvaluate the field...
Figure below shows a insulating rod having a uniformly distributed charge Q, the rod has been bent in a 120 degree circular arc of radius r. We place coordinate axes such that the axis of symmetry of the rod lies along the x axis and the origin is at the center of curvature P of the rod. In terms of Q and r, (a) what is the electric field due to the rod at point P (b) What is the...
A straight, nonconducting plastic wire 8.50 cm long carries a charge density of 100 nC/m distributed uniformly along its length. It is lying on a horizontal tabletop. Part C If the wire is now bent into a circle lying flat on the table, find the magnitude and direction of the electric field it produces at a point 4.50 cm directly above its center.