A thin insulating rod of length L has a charge Q spread uniformly along it. Point...

A thin rod of length L=80 cm carries a total charge of +5 nC uniformly distributed...

A thin rod of length L=80 cm carries a total charge of +5 nC uniformly distributed over its left half and -5 nC over its right half. Find the electric field on the axis of the rod at distance r=400 cm from its rightmost end. What is the magnitude of the electric field at point P. (N/C)?

A thin rod of length l and uniform charge per unit length λ lies along the...

A thin rod of length l and uniform charge per unit length λ lies along the x axis as shown figure. (a) Show that the electric field at point P, a distance y from the rod, along the perpendicular bisector has no x component and is given by E=(2kλsinθ0)/y. (b) Using your result to (a), show that the field of a rod of infinite length is given by E=2kλ/y.

A thin glass rod of length ?has a linear charge density that is constant along the...

A thin glass rod of length ?has a linear charge density that is constant along the length of the rod. a)What is the electric potential on a charge q at a distance h above the middle of the rod? b) Using the answer from part (a), find the field very far from the rod (when h>>?). c) Using the answer from part (a), find the field very close to the rod (when h<<?).

Positive charge Q is distributed uniformly along a rod of length L that lies along the...

Positive charge Q is distributed uniformly along a rod of length L that lies along the x-axis from x=L to x=2L. How much charge is contained within a segment of the rod of length dx? Integrate to find the total electric potential at the origin (x=0) due to the rod. Express your answer in terms of the electric constant ϵ0epsilon_0 and variables Q,L

Positive electric charge QQ is distributed uniformly along a thin rod of length 2aa. The rod...

Positive electric charge QQ is distributed uniformly along a thin rod of length 2aa. The rod lies along the xx-axis between x=−ax=−a and x=+ax=+a (Figure 1). Calculate how much work you must do to bring a positive point charge qq from infinity to the point x=+Lx=+L on the xx-axis, where L>aL>a. What does your result for the potential energy U(x=+L) become in the limit a→0? Express your answer in terms of some or all of the variables Q, q, a,...

A thin rod of length L is non-uniformly charged. The charge density is described by the...

A thin rod of length L is non-uniformly charged. The charge density is described by the expression λ=cx, where c is a constant, λ is the charge per length, and x is the coordinate such that x=0 is one end of the rod and x=L is the other. Find the total charge on the rod and the electric potential at a field point just touching the rod at the x=0 end.

3) A thin ring made of uniformly charged insulating material has total charge Q and radius...

3) A thin ring made of uniformly charged insulating material has total charge Q and radius R. The ring is positioned along the x-y plane of a 3d coordinate system such that the center of the ring is at the origin of the coordinate system. (a) Determine an expression for the potential at an arbitrary location along the z-axis in terms of Q, R, and z. (b) Use this expression to determine an expression for the magnitude of the electric...

A rod (length L, total charge +Q) with charge density lambda = a(y+b), where a and...

A rod (length L, total charge +Q) with charge density lambda = a(y+b), where a and b are constants, is positioned along the y-axis such that the upper end is at the origin. (a) Determine the electric field (magnitude and direction) at point P, on the y-axis, distance b from the upper end of the rod (b) Set up, but do not integrate, an integral that would allow you to determine the electric potential at point P. (c) Extra credit:...

Consider a thin non conducting ring of radius a, which has a charge Q uniformly spread...

Consider a thin non conducting ring of radius a, which has a charge Q uniformly spread around it. Find an expression for the electric force vector on a point charge q placed at point P, which is located on the x axis of the ring at a distance of x from the center. Verbally explain your reasoning. Let x=6 cm and Q=6 microC. Calculate the magnitude (in N) and the direction of the elctric force

A total charge Q is uniformly distributed, with surface charge density, over a very thin disk...

A total charge Q is uniformly distributed, with surface charge density, over a very thin disk of radius R. The electric field at a distance d along the disk axis is given by E where n is a normal unit vector perpendicular to the disk. What is the best approximation for the electric field magnitude E at large distances from the disk?