Part A A single circular loop of wire with radius $2\mathrm{.}40$ cm lies in the xy$-$plane. There is a uniform magnetic field that changes at a steady rate from $0\mathrm{.}140$ T in the $+$z$-$ direction at t $=0$ to $0\mathrm{.}110$ T in the $-$z$-$direction at t$=2\mathrm{.}00$ s$.$ Take the area vector for the loop to be in the $+$z$-$direction. Find the magnetic flux through the loop at t $=0.$ Express your answer with the appropriate units. $?=$ Value Units Submit Request Answer Part B Find the magnetic flux through the loop at t $=2\mathrm{.}00$ s$.$ Express your answer with the appropriate units. HA $?)=$ Value Units Submit Request Answer Part C Find the magnitude of the induced emf in the loop while the field is changing. Express your answer with the appropriate units. $?$ E $=$ Value Units Part A An isolated conducting rod of length $8\mathrm{.}00$ cm is oriented parallel to the x$-$axis. It moves in the $+$y$-$direction at $3\mathrm{.}90$ m$/$s in the presence of a uniform magnetic field of magnitude $0\mathrm{.}600$ T that points in the $-$z$-$direction. Find the magnitude of the motional emf in the rod. Express your answer with the appropriate units. HA $?$ E $=$ Value Units Submit Request Answer Part B Find the magnitude of the electric field produced in the rod. Express your answer with the appropriate units. $?$ E$-$ Value Units Submit Request Answer Part C Find the direction of the electric field produced in the rod. the $+$x$-$direction the $-$x$-$direction the $+$y$-$direction the$-$y$-$direction Submit Request Answer