An electron is projectd horizontally with a kinetic energy of 10 keV. A magnetic feld of strength `1.0X10^(-7)` T exists in the vertically upward direction. (a)will the electron deflect towards right or towards left of its motion? (b) calculate the sideways deflection of the electrion in travelling through 1m. make appropriate approximations.

A proton is projected with a speed of 3X10^6 ms ^(-1) horizontally from est to west. A uniform magnetic field vec B of strength 2.0X10^(-3) T exists in the vertically upward direction(a) find the force on the proton just after it is projected. (b) what is the acceleration produced?

A proton is projected with a speed of 3X10^6 ms ^(-1) horizontally from east to west. A uniform magnetic field vec B of strength 2.0X10^(-3) T exists in the vertically upward direction(a) find the force on the proton just after it is projected. (b) what is the acceleration produced?

A 10 g bullet having a charge of 4.00 muC is fired at a speed of 270 ms^(-1) in a horizontal direction. A vertical magnetic field of 500 muT exists in the space. Find the deflection of the bullet due to the magnetic field as it travels through 100m. make appropriate approximations.

An electron having kinetic energy 10eV is circulating in a path of radius 0.1 m in an external magnetic field of intensity 10^(-4) T. The speed of the electron will be

An alpha particle is projected vertically upward a speed of 3.0 X 10^4 km s^(-1) in a region where a magnetic field of magnitude 1.0 T exists in the direction south to north. Find the magnetic force that acts on the a particle.

A 10 m wide spaceraft moves through the interstellar space at a speed 3X10^7 ms^(-1) . A magnetic field B= 3 X 10^(-10) T exists in the space in a direction perpendicular to the plane of motion. Treating the spacecraft as a conductor, calculate the emf induced across its width.

L is a smooth conducting loop of radius l=1.0 m & fixed in a horizontal plane.A conducting rod of mass m=1.0 kg and length slightly greater than l higed at the centre of the loop can rotate in the horizontal plane such that the free end slides on the rim of the loop.There is a uniform magnetic field of strength B=1.0 T directed vertically downward.The rod is rotated with angular velocity omega_(0)=1.0 rad//s and left.The fixed end of the rod and the rim of the loop are connected through a battery of e.m.f E a resistance R=1 Omega , and initially uncharged capacitor of capacitance C=1.0 F in series.Find (i)the time dependence of e.m.f M such that the current I_(0)=1.0 A in the circuit is contant. (ii)energy supplied by the battery by the time rod stops.

L is a smooth conducting loop of radius l=1.0 m & fixed in a horizontal plane. A conducting rod of mass m=1.0 kg and length slightly greater than l hinged at the centre of the loop can rotate in the horizontal plane such that the free end slide on the rim of the loop. There is a uniform magnetic field of strength B=1.0 T directed vertically downward. The rod is rotated with angular velocity omega_(0)=1.0 rad//s and left. The fixed end of the rod and the rim of the loop are connected through a battery of emf . E, a resistor of resistance R =1.0 Omega , and intially uncharged capacitor of capacitance C=1.0 F in series. Find : (i) the time dependence of emf . E such that the current I_(0)=1.0A in the circuit is constant. (ii) energy supplied by the battery by the time rod stops.

An electron is moving vertically upwards in the uniform magnetic field of the earth. The velocity of the electron is 2.0 xx 10^(6) m/s and the horizontal component of the earth.s magnetic field is 0.32 xx 10^(-4)T. Obtain the magnitude and direction of the force on the electron.

The horizontal component of the earth's magnetic field at a place is 3.0 X 10^(-4) T and the dip is 53^@ . A metal rod of length 25cm is placed in the north - south direction and is moved at a constant speed of 10cm s^(-1) towards east. Calculate the emf induced in the rod.