In which of the following would the electric field be zero? Please explain why it is...

(multiple choice) There must be zero electric field a) in a region with no charges. b)...

(multiple choice) There must be zero electric field a) in a region with no charges. b) in a region with a constant magnetic field. c) in an ideal conductor. d) all of the above

Explain why the tangential components of the Electric field on the surface of conductor goes to...

Explain why the tangential components of the Electric field on the surface of conductor goes to zero when the conductor is please in Electrical field

Explain why the tangential component of electric field on the surface of a conductor goes to...

Explain why the tangential component of electric field on the surface of a conductor goes to zero when the conductor is placed in electric field till such a time the drift motion of charge would have stopped

Which of the following statements is/are true regarding behaviors of charged particles inside electric field? Positive...

Which of the following statements is/are true regarding behaviors of charged particles inside electric field? Positive charges are accelerated by electric fields toward points at higher electric potential; If the electric field at a certain region is zero, then the electric potential at the same region is constant; If a negative charge moves in the direction of the electric field, the field does positive work and the potential energy increases If a positive charge moves opposite to the electric field,...

please explain why there may be nonvanishing solution for electric and magnetic field in source-free regions?

please explain why there may be nonvanishing solution for electric and magnetic field in source-free regions?

The purpose of this problem is to see, roughly, how fast the electric field inside a...

The purpose of this problem is to see, roughly, how fast the electric field inside a conductor reaches zero (i.e., electrostatic equilibrium) if the conductor is placed in an electric field. a) Use ? = ??⃗ , where ? is the conductivity of the conductor, Gauss’s law ?⃗ ∙ ?⃗ = ?/?0 , and the continuity equation ?⃗ ∙ ? + ?? ?? = 0, to show that ??⃗ ?? = −(?????)?⃗ b) Determine the time constant c) Find the...

Which of the following statements correctly compare the ideal parallel-plate capacitor to the ideal solenoid? Select...

Which of the following statements correctly compare the ideal parallel-plate capacitor to the ideal solenoid? Select all that apply. A) The direction of the uniform electric field in the capacitor is parallel to the plates making up the capacitor, while the direction of the uniform magnetic field is parallel to the axis of the solenoid. B) In the ideal capacitor changing the distance between the plates does not affect the electric field. In the ideal solenoid changing the radius of...

The electric field is zero at a point along the line joining two charges. (a) Are...

The electric field is zero at a point along the line joining two charges. (a) Are the signs of the two charges equal or opposite? Explain. (b) Can the potential be zero at any point along the line? Explain.

The electric field is zero at a point along the line joining two charges. (a) Are...

The electric field is zero at a point along the line joining two charges. (a) Are the signs of the two charges equal or opposite? Explain. (b) Can the potential be zero at any point along the line? Explain.

Please write whether the statement is true or false, and if false please explain why it...

Please write whether the statement is true or false, and if false please explain why it is. “The more charges you put together in a region of space, the stronger the electric field gets.” “Electric field vectors never cross.” “Electric field lines always have to be straight.” “Electric field vectors always have to be straight.” “The motion of a charged particle in a uniform electric field is always a straight line.” “A charged particle in an electric field always moves...