If the motion of the particle is parallel to the direction of the field, then the force on the particle will be zero. This is an unstable condition, though. Even the slightest deviation from parallel will give a tiny force to the particle, which nudges it farther away from the parallel direction.
Yes. Whether the particle experiences a force, and how much, depends on the exact direction, in relation to the magnetic field lines.
Yes, a moving electron will create a magnetic field. Any moving charge will create a magnetic field around its path of travel. This is the basis for the electromagnetic force, which is one of the four fundamental forces in nature.
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.
No, the particle has the following forces f= qvB= - qv.B + qvxB, the first force is a scalar force when the particle is parallel to the field and teh second force is avector force when teh particle is perpendicular to the field. If the particle is not neither parallel or perpendicular to the field, both the scalar and vector forces will be experiencd.
A neutron, an antineutron, a neutrino, an antineutrino, and a photon would not be deflected by a magnetic field, as they all have no net electric charge. I do not find a reference to an antiphoton, but it makes sense that, if it existed, it would also not be affected by a magnetic field.
When a charged particle moves through a magnetic field it experiences the Lorentz force perpendicular to the magnetic fields lines and perpendicular to its direction of motion.The Lorentz equation quantifies the force.F=qE+qvXB, where the vector quantities are in bold. The X refers to the vector cross product operation.In this question, there is no electric field, so this says the force is proportional to the charge, velocity and field strength and the sine of the angle between the velocity and the field.
Yes, a moving electron will create a magnetic field. Any moving charge will create a magnetic field around its path of travel. This is the basis for the electromagnetic force, which is one of the four fundamental forces in nature.
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.
No, the particle has the following forces f= qvB= - qv.B + qvxB, the first force is a scalar force when the particle is parallel to the field and teh second force is avector force when teh particle is perpendicular to the field. If the particle is not neither parallel or perpendicular to the field, both the scalar and vector forces will be experiencd.
The charged particle that flows through circuits is an electron.
When a charged particle moves through a magnetic field it experiences the Lorentz force perpendicular to the magnetic fields lines and perpendicular to its direction of motion.The Lorentz equation quantifies the force.F=qE+qvXB, where the vector quantities are in bold. The X refers to the vector cross product operation.In this question, there is no electric field, so this says the force is proportional to the charge, velocity and field strength and the sine of the angle between the velocity and the field.
That's going to depend on which pole of the magnet is sticking out towards the beta stream (there are two choices), and also on the direction in which the electrons are flowing past the magnet (there are two choices).
A neutron, an antineutron, a neutrino, an antineutrino, and a photon would not be deflected by a magnetic field, as they all have no net electric charge. I do not find a reference to an antiphoton, but it makes sense that, if it existed, it would also not be affected by a magnetic field.
When a charged particle moves through a magnetic field it experiences a force from that field. When an electrical conductor moves through a magnetic field the electrons, which are negatively charged, being moving, creating an electric current.
When a charged particle moves through a magnetic field it experiences the Lorentz force perpendicular to the magnetic fields lines and perpendicular to its direction of motion.The Lorentz equation quantifies the force.F=qE+qvXB, where the vector quantities are in bold. The X refers to the vector cross product operation.In this question, there is no electric field, so this says the force is proportional to the charge, velocity and field strength and the sine of the angle between the velocity and the field.
The electromagnet can be defined as a magnet created when electric current passes through a conducting medium. Whenever any charged particle moves it creates a magnetic field around its path of travel.
A neutal atom could become a positively charged particle through the loss of an electron.
An electron is a charged particle and as such it is surrounded by an electric field. A magnet is in general not charged so it will not form an electric field. It will, however, form a magnetic field. In case your question is what an electric field is made of, then the answer is (virtual) photons, which are the mediators for the electromagnetic force.