10.) An electron is circularly orbiting a proton. The magnitude of acceleration of the electron is 1.44×10–8 m/s2 . What is the electron’s orbital radius?
10.) An electron is circularly orbiting a proton. The magnitude of acceleration of the electron is...
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electron is orbiting a proton. Find the velocity of this orbit
3. (a)(6 pts) An electron is orbiting a proton. Find the velocity of this orbit. (The radius of the electron orbit = 0.529x10-10 m) (b)(8 pts) Find the voltage and the electric field strength this electron sees from the (C)(11 pts) Find the Kinetic Energy and Potential Energy for the electron in this orbit. When you combine the KE and PE, the Total Energy will be negative. Find...
3. (a) (6 pts) An electron is orbiting a proton. Find the force between the electron and the proton (b) (8 pts) Find the voltage and the electric field strength this electron sees from the proton (c) (11 pts) in the Bohr model of the hydrogen atom, the electron orbits the proton at the radius of the electron's orbit. Find the current created by the electron orbiting the proton in the Bohr model of the hydrogen atom.
3. An electron is orbiting a stationary proton in a circular orbit of radius 0.053nm. Derive a symbolic answer for the period and the frequency of the motion. Calculate a numerical value for the frequency. Hint: Newton's 2nd law and centripetal acceleration
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. 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?
An electron (m=9.11×10-31 kg) caught in a magnetic field travels in a circular path of radius 30 cm with a period of 3.14×10-8 s. (a) What is the electron’s frequency? (b) What is the electron’s speed? (c) What is the electron’s centripetal acceleration?
#6) The electron is imagined to move in a circular orbit about a stationary proton in the Bohr model (we will talk more about the Bohr model later). If the speed of the electron were 6.5 x 105 m/s, what would be the corresponding orbital radius? Mass of an electron is 9.11 x 101 kg, and magnitude of charge for an electron and proton is 1.60 x 10 1s Ceach. Coulomb's constant k is 9.0x 10 N m2/c2 6.5 x...
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.
E18M.6 The Rutherford model of the hydrogen atom (pro- posed by Ernst Rutherford in roughly 1910) imagines the electron as orbiting the proton in a circle (a) Use Newton's second law, Coulomb's law, and what you know about acceleration in circular motion to show that the electron's acceleration in a circular orbit of radius r is ã/(4me,mr) and its orbital kinetic energy is K-72/ (8πεο r), where e is the proton's charge and m is the electron's mass. (b) Show...
06) The electron is imagined to move in a circular orbit about a stationary proton in the Bohr model (we will talk more about the Bohr model later). If the speed of the electron were 6.5x 10 m/s, what would be the corresponding orbital radius? Mass of an electron is 9.11 x 10" kg, and magnitude of charge for an electron and proton is 1.60 x 10 19 C each. Coulomb's constant k is 9.0x 10° N-m2/C2. #7) A 5.0...