Radiation Energy = hc/r = WQc/r = VQ = WI, where W is the magnetic Field in Webers and Q is the Photon Charge and V is the Voltage and I is the current and h is Planck's Constant h=WQ.
The electric force and magnetic force are related in electromagnetic interactions. When an electric charge moves, it creates a magnetic field. Similarly, a changing magnetic field can induce an electric current. This relationship is described by Maxwell's equations, which show how electric and magnetic fields interact and influence each other in electromagnetic phenomena.
Electric charges are at the heart of electromagnetic waves. When an electric charge accelerates or changes its motion, it produces a changing electric field, which in turn generates a changing magnetic field. These interacting electric and magnetic fields propagate through space as electromagnetic waves, carrying energy and information.
Electric and magnetic fields are related through electromagnetic interactions, where changes in one field can induce changes in the other. This relationship is described by Maxwell's equations in electromagnetism.
Electromagnetic radiation is one way that energy can be transfered across a distance. EM radiation can be thought of as packets of wave, each called a photon. A photon has a certain amount of energy, which can be found using the formula "E = hf", where 'f' is the frequency of the light, and 'h' is plancks constant (h = 6.626×10−34 Js).
Changing electric fields create magnetic fields, and changing magnetic fields create electric fields. This relationship is described by Maxwell's equations. The two fields are interdependent and can propagate through space as electromagnetic waves.
A pulsar is a rapidly spinning neutron star that releases regular pulses of electromagnetic radiation from its magnetic field
The magnetic field is related to the Poynting flux in a charging capacitor through electromagnetic induction. As the capacitor charges, the changing electric field produces a magnetic field, which in turn affects the flow of energy in the form of electromagnetic waves known as the Poynting flux.
Motion-induced electric fields and motional emf are related in the context of electromagnetic induction because both phenomena involve the generation of an electric field due to a changing magnetic field. When a conductor moves through a magnetic field, it experiences a motional emf, which is the voltage induced in the conductor. This motional emf is caused by the motion-induced electric fields that are generated in the conductor as a result of the changing magnetic field. In essence, motion-induced electric fields lead to the generation of motional emf through electromagnetic induction.
it is related by blood
The H field represents the magnetic field in electromagnetic fields, while the E field represents the electric field. The H field is related to the flow of magnetic energy, while the E field is related to the flow of electric energy. Both fields are essential components of electromagnetic waves and interact with each other to propagate energy through space.
Moving electric charges create both electric and magnetic fields. The electric field is produced by the charge itself, while the magnetic field is generated by the motion of the charge. When a charged particle moves, it creates a magnetic field around it perpendicular to its direction of motion, as described by the right-hand rule.
The two are related because an Electric current produces Magnetic Fields