A charged particle is accelerated in magnetic field if it has a velocity. F = Q v x B, where v x B is cross-product of speed and magnetic flux vectors. According to Newton F = ma where you can find the acceleration if you know the mass.
if charge particle is in motion ,then it has magnetic field
Yes, a magnetic field is generated by moving electric charges. When charged particles such as electrons are in motion, they create a magnetic field that can exert forces on other charged particles. This relationship is described by the magnetic field's direction being perpendicular to both the direction of motion of the charged particles and the electric field.
electromagnetic fields. These fields are generated by powerful magnets which create a strong magnetic field. The particles are then guided in circular paths, and as they pass through the electromagnetic field pulses, they gain energy and accelerate. This process is repeated multiple times to achieve the desired energy for the particles.
The magnetic field force acts on charged particles in space by exerting a Lorentz force, which is perpendicular to both the velocity of the charged particle and the magnetic field direction. This interaction can cause charged particles, such as electrons, to spiral along magnetic field lines, influencing their trajectories. In regions with strong magnetic fields, like near planets or stars, this can lead to phenomena such as auroras or the trapping of particles in radiation belts. However, uncharged objects are not directly affected by magnetic fields.
Charged particles from outer space are more likely to strike Earth at the poles due to the Earth's magnetic field shaping their paths. The magnetic field lines converge at the magnetic poles, directing charged particles towards these regions. This results in a higher concentration of cosmic ray impacts at the poles compared to the equator.
When magnetic fields and electric fields interact, they can affect the motion of charged particles. The magnetic field can cause the charged particles to move in a curved path, while the electric field can accelerate or decelerate the particles. This interaction is important in various phenomena, such as the motion of charged particles in a particle accelerator or the behavior of charged particles in a magnetic field.
The shape of a magnetic field affects the path and motion of charged particles within it. Charged particles tend to move in curved paths within a magnetic field, following the field lines. The strength and direction of the magnetic field determine how the charged particles will behave within it.
The magnetic field variable affects the behavior of charged particles in a magnetic field by exerting a force on them. This force causes the charged particles to move in a curved path perpendicular to both the magnetic field and the direction of their initial velocity.
if charge particle is in motion ,then it has magnetic field
No, a static magnetic field cannot do positive work on charged particles. Magnetic fields can only do work on moving charged particles by changing their directions of motion or causing them to spiral. Static magnetic fields do not affect stationary charged particles.
The strength of the magnetic field affects the movement of charged particles within it. A stronger magnetic field will cause the charged particles to move in a more curved path, while a weaker magnetic field will result in less curvature in their movement.
Yes, a magnetic field is generated by moving electric charges. When charged particles such as electrons are in motion, they create a magnetic field that can exert forces on other charged particles. This relationship is described by the magnetic field's direction being perpendicular to both the direction of motion of the charged particles and the electric field.
Charged particles from the sun become trapped in the Van Allen radiation belts due to the Earth's magnetic field. The magnetic field bends the charged particles' trajectories, causing them to spiral along the field lines and get trapped in the region around the Earth's magnetic poles.
A charged particle naturally changes direction in a magnetic field. This is because any charged particle produces a magnetic field when it is moving. And if the charged particle is moving through a magnetic field, the two fields (in this case the Earth's and the one created by the moving particle) interact to deflect the particle. The particle will be deflected "to the side" or laterally, and positively charged particles will be deflected in the opposite direction of negatively charged one.
A changing magnetic field can cause charged particles to experience a force, known as the Lorentz force. This force can make the particles move in a curved path or accelerate them. This phenomenon is the basis for many important processes in physics, such as electromagnetic induction and the operation of devices like electric motors and generators.
Magnetism is a force that results from the movement of charged particles. When charged particles, such as electrons, move, they create a magnetic field. This magnetic field can attract or repel other charged particles, leading to the phenomenon of magnetism.
A cyclotron is a type of particle accelerator that uses a magnetic field to accelerate charged particles in a spiral path. It operates based on the principle of using an alternating electric field to accelerate the particles as they spiral outward due to the magnetic field. This allows the particles to gain energy and reach high speeds for various applications in research and medicine.