An electron is a spinning particle that creates a magnetic field. The spinning motion of the electron generates a magnetic dipole moment, resulting in the creation of a magnetic field around the electron.
Spinning electric charges generate a magnetic field. This phenomenon is described by a fundamental principle in physics known as electromagnetism, where the motion of electric charges creates magnetic effects.
No, a stationary charge particle cannot be accelerated in a magnetic field. In order to be affected by a magnetic field, the charged particle must be moving.
A magnetic field alters the direction a charged particle is traveling. This is true if the charged particle is moving "across" and not "along" the magnetic lines of force of the field through which it is moving. The particle is said to be deflected when it (the particle) passes through magnetic field lines. The reason for the observed deflection is because a charged particle that is moving creates a magnetic field, and this field will react with the magnetic field through which it is moving. The result will be lateral deflection, and positively charged particles will be deflected one way and negatively charged particles will be deflected the other.
Electrons are the subatomic particles that are responsible for causing magnetic properties in an atom. The movement of electrons within an atom creates a magnetic field.
An alpha particle is a positively charged particle, so it will experience a force perpendicular to both its velocity and the magnetic field direction. This force causes the alpha particle to move in a circular path due to the magnetic field's influence. The radius of the circle will depend on the velocity of the alpha particle and the strength of the magnetic field.
Spinning electric charges generate a magnetic field. This phenomenon is described by a fundamental principle in physics known as electromagnetism, where the motion of electric charges creates magnetic effects.
it creates mass
No, a stationary charge particle cannot be accelerated in a magnetic field. In order to be affected by a magnetic field, the charged particle must be moving.
A magnetic field alters the direction a charged particle is traveling. This is true if the charged particle is moving "across" and not "along" the magnetic lines of force of the field through which it is moving. The particle is said to be deflected when it (the particle) passes through magnetic field lines. The reason for the observed deflection is because a charged particle that is moving creates a magnetic field, and this field will react with the magnetic field through which it is moving. The result will be lateral deflection, and positively charged particles will be deflected one way and negatively charged particles will be deflected the other.
Electrons are the subatomic particles that are responsible for causing magnetic properties in an atom. The movement of electrons within an atom creates a magnetic field.
if charge particle is in motion ,then it has magnetic field
An alpha particle is a positively charged particle, so it will experience a force perpendicular to both its velocity and the magnetic field direction. This force causes the alpha particle to move in a circular path due to the magnetic field's influence. The radius of the circle will depend on the velocity of the alpha particle and the strength of the magnetic field.
The magnetic field can change the direction of a charged particle's movement, but it does not directly affect its speed.
The spinning proton magnetic field influences the behavior of particles in a magnetic field by aligning with or against the external magnetic field. This alignment affects the energy levels of the particles, leading to phenomena like nuclear magnetic resonance and the Zeeman effect.
The Earth's core consists of molten iron and nickel, which creates a dynamo effect generating a magnetic field. This flow of liquid metal creates convection currents that help sustain the Earth's magnetic field and keep the core spinning. The core will likely continue to spin due to the planet's internal heat and its rotation in space.
When a charged particle moves through a magnetic field, it experiences a force that causes it to change direction. This force is perpendicular to both the particle's velocity and the magnetic field, resulting in the particle moving in a curved path. This phenomenon is known as the Lorentz force and is responsible for the particle's trajectory being deflected in the presence of a magnetic field.
Magnetic force is the force exerted on a charged particle moving through a magnetic field. The strength and direction of the force depend on the charge of the particle, its velocity, and the strength and orientation of the magnetic field.