radient dB/dz 2.6 x 102 T/m. (a) Whatis Suppose a hydrogen atom in its ground state...
Question 1: Consider the following situation: For the hydrogen atom in its ground state pictured on the right, classically orbiting at the Bohr Radius 20 = 5.29 + 10-11m, calculate: a) The speed the electron is traveling at. b) The angular momentum 1 =7 x 5 of the electron. Compare it to = 1.055 10-34J.s. c) The magnetic field due to the electron at the position of the proton. Is it into the page or out of the page? on-...
A proton moves at 4.50 x 105 m/s in the horizontal direction. It enters a uniform vertical electric field with a magnitude of 9.60 x 103 N/C. Ignoring any gravitational effects, find (a) the time interval required for the proton to travel 5.00 cm horizontally, (b) its vertical displacement during the time interval in which it travels 5.00 cm horizontally, and (c) the horizontal and vertical components of its velocity after it has traveled 5.00 cm horizontally.25a) Find the (x,y)...
A proton moves at 4.40 x 105 m/s in the horizontal direction. It enters a uniform vertical electric field with a magnitude of 9.00 × 103 NC. Ignore any gravitational effects. (a) Find the time interval required for the proton to travel 5.50 cm horizontally 125 ns (b) Find its vertical displacement during the time interval in which it travels 5.50 cm horizontally. (Indicate direction with the sign of your answer.) (c) Find the horizontal and vertical components of its...
As shown in the figure, an electron is fired with a speed of 3.73 x 10 m/s through a hole in one of the two parallel plates and into the region between the plates separated by a distance of 0.24 m. There is a magnetic field in the region between the plates and, as shown, it is directed into the plane of the page (perpendicular to the velocity of the electron). Determine the magnitude of the magnetic field so that...
state the equation that you use Semiconductor Germanium has a density of 5323 a. cm- and atomic mass of 72.63u. If we assume that Germanium can contribute 1 conducting electron per atom, calculate the maximum number of conducting electrons in a silicon sample of 2cm X 10cm X 10cm. E1, frd = eftew+1E2, ~êr = ()**; Superconductor E3, M05T, = constant; E4, E,0) = 3.54k87c; E5, E,(T) = 1.74E,(0)(1-3)*; E6, critical magnetic field B.(T) = B_(0)(1-). Order of energy of...