A conductor carries a current that is decreasing exponentially with time. The current is modeled as...

A conductor carries a current of I = 14.4 A in the direction of the plus...

A conductor carries a current of I = 14.4 A in the direction of the plus x axis. The current is such that it is perpendicular to a uniform magnetic field. The magnetic force acting on the unit length of the conductor is 0.121 N / m and it is in the minus y direction. a) Find the magnitude of the magnetic field in the region where the current passes? b) Find the direction of the magnetic field?

A long straight horizontal wire carries a current I = 1.80 A to the left. A...

A long straight horizontal wire carries a current I = 1.80 A to the left. A positive 1.00 C charge moves to the right at a distance 5.00 m above the wire at constant speed v = 1250 m/s . (Figure 1) What are the magnitude and the direction of the magnetic force on the charge? What is the magnitude B of the magnetic field at the location of the charge due to the current-carrying wire? Express your answer in...

deal with a current-carrying fuse of diameter 0.3 mm, which may be modeled as a cylindrical...

deal with a current-carrying fuse of diameter 0.3 mm, which may be modeled as a cylindrical conductor. (a) Suppose the current density along a circular cross-section is 90 A/cm2. What is the total charge that flows through a cross section of the fuse in 5 seconds? (b)The fuse will "blow" if the current density in the fuse exceeds 700 A/cm2. What is the maximum current, I, that the fuse can withstand?

Q.7 A cylindrical conductor with circular cross-section has radius a and resistivity p and carries a...

Q.7 A cylindrical conductor with circular cross-section has radius a and resistivity p and carries a constant current I in the +j direction. (c) What are the magnitude and direction of the Poynting vector S at the same point ( just inside the wire at a distance a from the axis)? (d) Use the result in part (c) to find the rate of flow of energy into the volume occupied by a length L of the conductor. Compare your result...

A long straight horizontal wire carries a current I = 1.80 A to the left. A...

A long straight horizontal wire carries a current I = 1.80 A to the left. A positive 1.00 C charge moves to the right at a distance 5.00 m above the wire at constant speed v = 1250 m/s . (Figure 1) What are the magnitude and the direction of the magnetic force on the charge? If the charge were located a distance 10.0 m from the wire, how would the net magnetic force on the charge compare to that...

The current in a 70.0-mH inductor changes with time as i = 4.00t2 ? 8.00t, where...

The current in a 70.0-mH inductor changes with time as i = 4.00t2 ? 8.00t, where i is in amperes and t is in seconds. (a) Find the magnitude of the induced emf at t = 1.00 s. in mV (b) Find the magnitude of the induced emf at t = 4.00 s. in mV (c) At what time is the emf zero? in s

Two horizontal, parallel conductors are connected to each other at the left end via an ammeter...

Two horizontal, parallel conductors are connected to each other at the left end via an ammeter of internal resistance of r = 2 Ω. A conductor of length L = 0.5 m, resistance R = 8 Ω and mass m = 5 kg can slide (no friction) along the horizontal rails. The whole system is inside a uniform magnetic field of magnitude 2 T and direction perpendicular to the plane formed by the two parallel conductors (i.e., pointing into the...

An AC power supply is connected to a capacitor of capacitance 3.5 μF. At time t...

An AC power supply is connected to a capacitor of capacitance 3.5 μF. At time t = 0 the power supply is switched on and starts providing a time-dependent voltage v(t) = V0 cos(ωt) across the capacitor, where V0 = 4.1 V and ω = 372 rad/s. The capacitor is initially uncharged. A)Find the current, in milliamperes with its sign, through the capacitor at time t = 2.5 s. B)Calculate the voltage across the capacitor, in volts with its sign,...

The current through a coil as a function of time is represented by the equation I(t)...

The current through a coil as a function of time is represented by the equation I(t) = Ae−bt sin(ωt), where A = 5.25 A, b = 1.75 ✕ 10−2 s−1, and ω = 375 rad/s. At t = 0.880 s, this changing current induces an emf in a second coil that is close by. If the mutual inductance between the two coils is 4.35 mH, determine the induced emf. (Assume we are using a consistent sign convention for both coils....

10. A spherical conductor of radius R = 1.5cm carries the charge of 45μ, (a) What...

10. A spherical conductor of radius R = 1.5cm carries the charge of 45μ, (a) What is the charge density (ρ) of the sphere? (b) Calculate the electric field at a point r = 0.5cm from the center of the sphere. (c) What is the electric field on the surface of the sphere? 11. Two capacitors C1 and C2 are in series with a voltage V across the series combination. Show that the voltages V1 and V2 across C1 and...