1. Electric fields are E(x, y, z ;t) = Re [Es(x, y, z)ejwt] The magnetic field...

A proton travels through uniform magnetic and electric fields. The magnetic field is in the negative...

A proton travels through uniform magnetic and electric fields. The magnetic field is in the negative x direction and has a magnitude of 3.31 mT. At one instant the velocity of the proton is in the positive y direction and has a magnitude of 2560 m/s. At that instant, what is the magnitude of the net force acting on the proton if the electric field is (a) in the positive z direction and has a magnitude of 5.15 V/m, (b)...

An electric field traveling through vacuum can be described as a plane wave E(r,t) = Eoexp[-i(ωt...

An electric field traveling through vacuum can be described as a plane wave E(r,t) = Eoexp[-i(ωt + k•z)]. (a) What is the angular frequency, wavelength, wave number, velocity, direction of propagation, and electric and magnetic field amplitude of this light wave? (b) Write equations describing the electric and magnetic fields in sinusoidal form, with all known quantities expressed numerically. (c) Write equivalent equations in complex exponential form. (d) What would be the maximum electric and magnetic forces exerted by this...

The x, y, and z components of a magnetic field are Bx = 0.098 T, By...

The x, y, and z components of a magnetic field are Bx = 0.098 T, By = 0.16 T, and Bz = 0.21 T. A 24-cm wire is oriented along the z axis and carries a current of 4.6 A. What is the magnitude of the magnetic force that acts on this wire? *Please put answer in 2 significant digits*

Flowing through all space is an electric field E(x, y, z) = αyz(x hat) + αxz(y...

Flowing through all space is an electric field E(x, y, z) = αyz(x hat) + αxz(y hat) + αxy(z hat). Show that the curl of the electric field vanishes, ∇ × E = 0. Use the definition of electric potential to find the potential difference between the origin and r = x(x hat) + y(y hat) + z(z hat), V (r) − V (0) = −(integral from 0 to r of (E · dl)). As the line integral is independent...

Al electromagnetic wave of 4.0 GHz has an electric field, E(z/t) and a magnitude of E0...

Al electromagnetic wave of 4.0 GHz has an electric field, E(z/t) and a magnitude of E0 + = 120π.If the wave propagastes throguh a material with conductivity σ = 7.5 x 10−3 S/m, relative permeability µr = 1.0, and relative permittivity εr = 14.0: a. Determine the constant of propagation, γ = α + jβ. b. Determine the intrinsic impedance, η. c. Determine the velocity oft he phase of the wave. d. Determine the ”skin depth”. e. Determine the value...

Problem 1 An electromagnetic wave propagates along the +y direction. If the electric field at the...

Problem 1 An electromagnetic wave propagates along the +y direction. If the electric field at the origin is along the +z direction, what is the direction of the magnetic field 2 If an electromagnetic wave has components Ey = E0 sin(kx - ?t) and Bz = B0 sin(kx - ?t), in what direction is it traveling?

An election is placed into a region permeated by a Uniform electric field (E=E x) and...

An election is placed into a region permeated by a Uniform electric field (E=E x) and a uniform magnetic field (B= B z). show that the path of motion is in the form of a cycloid : X= a sin(wt)+bt, Y= a(1-cos(wt)), z= 0

1. A particle of positive charge q and mass m enters parallel uniform electric and magnetic...

1. A particle of positive charge q and mass m enters parallel uniform electric and magnetic fields (of magnitudes E and B, respectively) both directed in the +z direction with a velocity v = v0i perpendicular to both fields. (a) What is the the particle’s initial acceleration? You can give your answer as a vector in component form. (b) What is the radius of the particle’s path (looking down the z-axis) if the magnetic field is B = Bk? Does...

The magnetic field in a plane monochromatic electromagnetic wave with wavelength λ = 684 nm, propagating...

The magnetic field in a plane monochromatic electromagnetic wave with wavelength λ = 684 nm, propagating in a vacuum in the z-direction is described by B⃗ =(B1sin(kz−ωt))(i^+j^)B→=(B1sin⁡(kz−ωt))(i^+j^) where B1 = 5.3 X 10-6 T, and i-hat and j-hat are the unit vectors in the +x and +y directions, respectively. 5) Which of the following equations describes the spatial and time dependence of the electric field oscillations? 6) What is tmax, the first time after t = 0, when the magnitude...

The electric field of a sinusoidal electromagnetic wave obeys the equation E=−(350V/m)sin[(5.89×1015rad/s)t+(1.96×107rad/m)x]E=−(350V/m)sin⁡[(5.89×1015rad/s)t+(1.96×107rad/m)x]. a)what is the amplitude...

The electric field of a sinusoidal electromagnetic wave obeys the equation E=−(350V/m)sin[(5.89×1015rad/s)t+(1.96×107rad/m)x]E=−(350V/m)sin⁡[(5.89×1015rad/s)t+(1.96×107rad/m)x]. a)what is the amplitude of the electric field of this wave? b)what is the amplitude of the magnetic field of this wave? c) what is the frequency of the wave? d)what is the wavelength of the wave? e) what is the period of the wave? f) speed of the wave?