Potential Energy of a Point Charge Placed at a Point with Non Zero Potential
Trending Questions
Q. An alpha particle is accelerated through a potential difference of 106 volt. Its kinetic energy will be
- 1 MeV
- 2 MeV
- 4 MeV
- 8 MeV
Q. A pellet carrying charge of 0.5 coulombs is accelerated through a potential of 2, 000 volts. It attains a kinetic energy equal to
- 1000 ergs
- 1000 joules
- 1000 kWh
- 500 ergs
Q. An electron (charge = 1.6×10−19 coulomb) is accelerated through a potential of 1, 00, 000 volts. The energy required by the electron is
- 1.6×10−24 joule
- 1.6×10−14 joule
- 0.53×10−14 joule
- 1.6×10−14 joule
Q. The potential at any point (x, y, z) in a space is given by V=x2yz. The work done in moving a charge 3C from point (1, 2, 3) to point (3, 4, 1) is
- 30 J
- 90 J
- 36 J
- 6 J
Q. An electron (charge = 1.6×10−19 coulomb) is accelerated through a potential of 1, 00, 000 volts. The energy required by the electron is
- 1.6×10−24 joule
- 1.6×10−14 joule
- 0.53×10−14 joule
- 1.6×10−14 joule
Q. An electron (charge = 1.6×10−19 coulomb) is accelerated through a potential of 1, 00, 000 volts. The energy required by the electron is
- 1.6×10−24 joule
- 1.6×10−14 joule
- 0.53×10−14 joule
- 1.6×10−14 joule
Q. A particle has a mass 400 times that of the electron and the charge is double that of an electron. It is accelerated by 5V of potential difference. Initially the particle was at rest, then its final kinetic energy will be
- 5 eV
- 10 eV
- 100 eV
- 2000 eV
Q. The potential at any point (x, y, z) in a space is given by V=x2yz. Find the work done in moving a charge 3C from point (1, 2, 3) to point (3, 4, 1)
- 30 J
- 90 J
- 36 J
- 6 J
Q. The potential at any point (x, y, z) in a space is given by V=x2yz. The work done in moving a charge 3C from point (1, 2, 3) to point (3, 4, 1) is
- 30 J
- 90 J
- 36 J
- 6 J
