In a radiation field with electrical & magnetic field (E,, B,), we put an electron into this radiation field, the electron would experience the Lorentz force and thus be accelerated via Newton's second law: mã = f = -e(E, +ü x B.). Since B, - LE, the Lorentz force due to the magnetic component B, can be neglected for slow motion (i.e. v/c < 1). After the electron is accelerated, it will irradiate to generate a radiation field. Assuming E, = E0 Cos(wt +a). Please answer the following questions:
In a radiation field with electrical & magnetic field (E,, B,), we put an electron into this radiation field, the electron would experience the Lorentz force and thus be accelerated via Newton's second law: mã = f = -e(E, +ü x B.). Since B, - LE, the Lorentz force due to the magnetic component B, can be neglected for slow motion (i.e. v/c < 1). After the electron is accelerated, it will irradiate to generate a radiation field. Assuming E, = E0 Cos(wt +a). Please answer the following questions:
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![In a radiation field with electrical & magnetic field (E,, B.), we put an electron into this radiation field,
the electron would experience the Lorentz force and thus be accelerated via Newton's second law:
mã = } = -e(Ë, + ü x B.).
Since B, - LĒ, the Lorentz force due to the magnetic component B, can be neglected for slow
motion (i.e. v/c << 1). After the electron is accelerated, it will irradiate to generate a radiation field.
Assuming E, = E,o cos (wt + a). Please answer the following questions:
%3D
(a) What is the electric field irradiated from the accelerated electron?
Need detail and step by step answer
Short answer and incorrect answer gives u downvote](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Ff3f0a4d0-6d7a-4bc1-b474-7cb45aa3d5f5%2Ff34d6b4f-7d16-44cf-ac75-a753b2c7cab2%2Fzga3uzw_processed.jpeg&w=3840&q=75)
Transcribed Image Text:In a radiation field with electrical & magnetic field (E,, B.), we put an electron into this radiation field,
the electron would experience the Lorentz force and thus be accelerated via Newton's second law:
mã = } = -e(Ë, + ü x B.).
Since B, - LĒ, the Lorentz force due to the magnetic component B, can be neglected for slow
motion (i.e. v/c << 1). After the electron is accelerated, it will irradiate to generate a radiation field.
Assuming E, = E,o cos (wt + a). Please answer the following questions:
%3D
(a) What is the electric field irradiated from the accelerated electron?
Need detail and step by step answer
Short answer and incorrect answer gives u downvote
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