Consider a hydrogen atom with radius R=5.29×10^-11 m.
Treat the orbiting electron as a current loop. If this electron
proton system is placed in a magnetic field of 0.400T which is
perpendicular to the magnetic moment of the loop, what is the
torque?
Consider a hydrogen atom with radius R=5.29×10^-11 m. Treat the orbiting electron as a current loop....
Consider a hydrogen atom with radius R=5.29×10^-11 m. Treat the orbiting electron as a current loop. If this electron proton system is placed in a magnetic field of 0.400T which is perpendicular to the magnetic moment of the loop, what is the torque?
5. Consider a Hydrogen atom with radius R = 5.29x10m. current loop. If Treat the orbiting electron as a this electron-proton system is placed in a magnetic field of 0.400T which is perpendicular to the magnetic moment of the loop, what is the torque ? (me = 9.11x10-31 kg 191- 1.60*10-19 C)
ON as Consider Hydrogen atom with radius R = 5.29x10 m. Treat the orbiting electron current loop. If this electron-proton system is placed in a magnetic field of 0.400 T which is perpendicular to the magnetic moment of the loop, what is the torque ? (me=9.11*10-31 kg 191-1.60x1019C
with required formula the position 5. Consider a electron as Hydrogen atom with radius R = 5.29x10"m. current loop. If Treat the on orbiting this electron-proton system is placed in a magnetic field of 0.400T which is perpendicular to the magnetic moment of the loop, what is the torque ? (me = 9.11*10-31 kg , 1968- 1.60*10'SC)
2. An electron moves in a circle of radius r = 5.66 x 10-11 m with a speed 2.09 x 10 m/s. Treat the circular path as a current loop with a constant current equal to the ratio of the electrons charge magnitude to the period of the motion. If the circle lies in a uniform magnetic field of magnitude B = 6.39 mT, what is the maximum possible magnitude of the torque, T, produced on the loop by the...
The electron and the protone of a hydrogen atom in the basic condition are r=5.29·10-11 m From each other, and the gravity between them is FG=3.63·10-47 N. If their electric charge was respectively. -q And +q Instead of the Elemar, what should q So be that the electrical cancer between them was the same size as the FG?
A flat circular loop of wire of radius R carrying a current I is placed in a uniform magnetic field B that is directed in the plane of the current loop. What is the magnetic moment M of the loop? What is the magnitude of the torque acting on the loop? In which direction the loop will rotate under the influence of this torque?
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-...
Consider a hydrogen atom modeled as a stationary proton with an electron orbiting in uniform circular motion. The radius of the orbit is a value given the name Bohr radius (you will have to look up this value). Calculate the total energy required to ionize the hydrogen atom.
Constants Consider a model of a hydrogen atom in which an electron is in a circular orbit of radius r = 5.57×10−11 m around a stationary proton What is the speed of the electron in its orbit?