1)Write down the coordinate free definition of divergence of a vector field. 2)Derive an expression for...

Write down Divergence law in integral form: o Derive the differential form of Divergence law from...

Write down Divergence law in integral form: o Derive the differential form of Divergence law from the integral form by using a integral form

Derive the expression for the electric field inside of a uniformly charged solid (non- conducting) sphere...

Derive the expression for the electric field inside of a uniformly charged solid (non- conducting) sphere of radius R using Gauss’ law. (b) Graph the electric field magnitude as a function of distance from the sphere center (include distances both less than and greater than the sphere’s radius); be sure to adequately label the graph.

Verify the Divergence Theorem for the vector field F(x, y, z) = < y, x ,...

Verify the Divergence Theorem for the vector field F(x, y, z) = < y, x , z^2 > on the region E bounded by the planes y + z = 2, z = 0 and the cylinder x^2 + y^2 = 1. By Surface Integral: By Triple Integral:

By showing that this electric field obeys Gauss' law, as well as the Maxwell Faraday equation...

By showing that this electric field obeys Gauss' law, as well as the Maxwell Faraday equation and write down in words what conditions need to be met. Consider both the differential and integral forms, whichever is most appropriate. For example, do you "see" the correct charge enclosed in a closed surface? How can I integrate electric field with da using Cartesian coordinate? Please also write the range (Integral from 0 to ~). If possible, please write the equations to represent...

(a) Write down the equations that relate: (i) The ?− component of the electric field at...

(a) Write down the equations that relate: (i) The ?− component of the electric field at a point specified by position vector ? to the to the electric potential ?(?) at that point. (ii) The ?− component of the electrostatic force acting on a particle of charge ? to the ?− component of the electric field at the position of the particle. And hence deduce an expression for: (iii) The ?− component of the electrostatic force acting on a particle...

(a) Is the vector field F = <e^(−x) cos y, e^(−x) sin y> conservative? (b) If...

(a) Is the vector field F = <e^(−x) cos y, e^(−x) sin y> conservative? (b) If so, find the associated potential function φ. (c) Evaluate Integral C F*dr, where C is the straight line path from (0, 0) to (2π, 2π). (d) Write the expression for the line integral as a single integral without using the fundamental theorem of calculus.

1- Write Gauss’ Law. 2- Consider an electric field line passing through a closed surface. What...

1- Write Gauss’ Law. 2- Consider an electric field line passing through a closed surface. What is the sign of the flux if: a) The line passes from inside to outside? b)The line passes from outside to inside? Think of a conductor as having both positive and negative mobile charges. Consider a conductor in electrostatic equilibrium – that is, whose charges are stationary. 3- Given that all of the charges are stationary, what must the E-field be at any point...

2. Consider the line integral I C F · d r, where the vector field F...

2. Consider the line integral I C F · d r, where the vector field F = x(cos(x 2 ) + y)i + 2y 3 (e y sin3 y + x 3/2 )j and C is the closed curve in the first quadrant consisting of the curve y = 1 − x 3 and the coordinate axes x = 0 and y = 0, taken anticlockwise. (a) Use Green’s theorem to express the line integral in terms of a double...

Intro to Quantum Mechanics (Free particle) a). Write the relations between the wave vector and angular...

Intro to Quantum Mechanics (Free particle) a). Write the relations between the wave vector and angular frequency of a free particle and its momentum vector and energy. b) What is the general form in one dimension of the wave function for a free particle of mass m and momentum p? c) Can this wave function ever be entirely real? If so, show how this is possible. If not, explain why not. d) What can you say about the integral of...

1. A trail of ants on a silo is described by the helix ?: ?⃗(?) =...

1. A trail of ants on a silo is described by the helix ?: ?⃗(?) = (cos ?)?̂+ (sin ?)?̂+ (3?)?̂ , for 0 ≤ ? ≤ 4?. The “linear ant density” along the trail is given by : ?(?, ?, ?) = 5? 2 + 5? 2 + 12? ???? ? . Evaluate the line integral : ∫ ?(?, ?, ?) ? ?? , and describe what this value represents. 2. Given the function: ?(?, ?) = 2?? −...