When an electron is projected along the direction of uniform electric and magnetic fields, it experiences a force due to the electric field, which accelerates it in the direction of the field. The magnetic field, however, exerts a force that is perpendicular to both its velocity and the magnetic field, causing the electron to undergo circular motion. The net effect is that the electron will spiral along the direction of the fields, with its speed increasing due to the electric field while also being influenced by the magnetic field's perpendicular force. Ultimately, the electron's trajectory will be a helical path along the direction of the fields.
A uniform magnetic field is a field where the magnetic field strength and direction are consistent throughout the region. This means that the magnetic field lines are parallel and evenly spaced, creating a uniform magnetic force on objects placed within the field. Uniform magnetic fields are often used in scientific experiments and applications due to their predictable behavior.
Any change in motion (direction or speed) is a change in velocity.Velocity is a vector quantity which means that it has a magnitude and a direction.
-a definition of uniform electric charge-A dispersed colloidal particle can adsorb electically caharaged particles(ions) on its surface. The charged species adsorbed on the surface of a given kind of colloidal particle may be either positive or negative
A uniform magnetic field is a magnetic field that has the same strength and direction at all points in a given region of space. It has constant magnetic flux density and does not vary in magnitude or direction within the specified area. Uniform magnetic fields are often used in scientific experiments and applications to provide consistent and predictable conditions for studying magnetic effects.
When an electric dipole is held in a non-uniform electric field, the dipole experiences a net torque causing it to align itself in the direction of the field. The dipole will tend to orient itself with its positive end facing towards the direction of the field and its negative end facing away from it. This alignment leads to a potential energy change in the dipole, with the dipole experiencing a force due to the non-uniform field.
yes, there is a NET field .electric dipole experiences a net field .(not in uniform E.Field)
Yes, in a uniform electric field, the electric intensity is the same at any two points. This is because the electric field strength is constant in magnitude and direction throughout the entire region of the field.
When a charge enters a uniform electric field, it will experience a force in the direction of the field if it's positive and in the opposite direction if it's negative. This force will cause the charge to accelerate in the direction of the field lines. The magnitude and direction of the acceleration will depend on the charge of the particle and the strength of the electric field.
An electric field will exert a force on a proton due to its positive charge. The proton will experience a force in the direction of the electric field if the field is uniform, causing it to accelerate in that direction.
When an electron is projected along the direction of uniform electric and magnetic fields, it experiences a force due to the electric field, which accelerates it in the direction of the field. The magnetic field, however, exerts a force that is perpendicular to both its velocity and the magnetic field, causing the electron to undergo circular motion. The net effect is that the electron will spiral along the direction of the fields, with its speed increasing due to the electric field while also being influenced by the magnetic field's perpendicular force. Ultimately, the electron's trajectory will be a helical path along the direction of the fields.
In a region of uniform electric field, the electric potential is constant.
The distribution of the electric field through a cube is uniform, meaning it is the same strength and direction at every point inside the cube.
The potential difference in a uniform electric field affects the motion of a charged particle by determining the direction and speed of its movement. The greater the potential difference, the stronger the force on the charged particle, leading to faster motion in the direction of the field.
No, direction does not affect uniform motion. Uniform motion is characterized by constant speed and direction, so as long as the speed remains constant, changing direction will not impact the uniform motion.
A uniform electric field is caused by having a constant electric field strength and direction within a certain region. This can be created by placing two charged plates with opposite charges parallel to each other or by using other configurations of charged objects to establish a consistent electric field.
The work done in rotating an electric dipole in a uniform electric field from parallel position to anti-parallel position is zero. This is because the torque applied to rotate the dipole is perpendicular to the direction of the electric field, so the work done is zero.