24-2: Electric potential energy
... 24-3: Electric Potential (V): is the potential energy per unit charge. V = U/q DV = DU/q = -W/q V = - W∞/q Note that the work you apply to a charge is the negative of the work that the field applies on the charge (when there is no change in kinetic energy). See the work energy theorem! DV = Wapplie ...
... 24-3: Electric Potential (V): is the potential energy per unit charge. V = U/q DV = DU/q = -W/q V = - W∞/q Note that the work you apply to a charge is the negative of the work that the field applies on the charge (when there is no change in kinetic energy). See the work energy theorem! DV = Wapplie ...
Midterm Exam No. 01 (Spring 2015)
... where a ≤ ρ, ρ′ < ∞. Here ρ< = Min(ρ, ρ′ ), ρ> = Max(ρ, ρ′ ), k is the Fourier variable for the z-coordinate and m is the Fourier variable for the angular coordinate φ. Evaluate gm (a, ρ′ ; k). Give a physical reasoning for your answer. ...
... where a ≤ ρ, ρ′ < ∞. Here ρ< = Min(ρ, ρ′ ), ρ> = Max(ρ, ρ′ ), k is the Fourier variable for the z-coordinate and m is the Fourier variable for the angular coordinate φ. Evaluate gm (a, ρ′ ; k). Give a physical reasoning for your answer. ...
23-5 Are Gauss` and Coulomb`s Laws Correct?
... This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their courses and assessing student learning. Dissemination or sale of any part of this work (including on the World Wide Web) will destroy the integrity of the work and is not permit ...
... This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their courses and assessing student learning. Dissemination or sale of any part of this work (including on the World Wide Web) will destroy the integrity of the work and is not permit ...
Lesson 16 - Magnetic Fields III
... We would have to work on the current loop in order rotate the loop so that its magnetic field was no longer aligned with the external magnetic field. If we release the current loop, the external magnetic field will do work on our current loop to realign the fields. Thus, magnetic potential energy wa ...
... We would have to work on the current loop in order rotate the loop so that its magnetic field was no longer aligned with the external magnetic field. If we release the current loop, the external magnetic field will do work on our current loop to realign the fields. Thus, magnetic potential energy wa ...
5: Comparing Laboratory and Human Exposures
... The factors that most affect electric induction are body shape, the orientation of the body relative to the field, and body grounding. The charge induced on the surface of the body is independent of both body size and the conductivity of body tissue. The conductivities of various body tissues do, ho ...
... The factors that most affect electric induction are body shape, the orientation of the body relative to the field, and body grounding. The charge induced on the surface of the body is independent of both body size and the conductivity of body tissue. The conductivities of various body tissues do, ho ...
Magnetic forces on Charges and Conductors
... 2. If an electron in an electron beam experiences a downward force of 2.0 x 10-14 N while travelling in a magnetic field of 8.3 x 10-2 T west, what is the direction and magnitude of the electron’s velocity? 3. A uniform 1.5 T magnetic filed points north. If an electron moves vertically downward (tow ...
... 2. If an electron in an electron beam experiences a downward force of 2.0 x 10-14 N while travelling in a magnetic field of 8.3 x 10-2 T west, what is the direction and magnitude of the electron’s velocity? 3. A uniform 1.5 T magnetic filed points north. If an electron moves vertically downward (tow ...
EM_Course_Module_5 - University of Illinois Urbana
... polarization, and magnetization. While these phenomena occur on the atomic or “microscopic” scale, it is sufficient for our purpose to characterize the material based on “macroscopic” scale observations, that is, observations averaged over volumes large compared with atomic dimensions. ...
... polarization, and magnetization. While these phenomena occur on the atomic or “microscopic” scale, it is sufficient for our purpose to characterize the material based on “macroscopic” scale observations, that is, observations averaged over volumes large compared with atomic dimensions. ...
Lab 4, part one
... Learning outcome: Ultimately, to understand how a changing electric field induces a magnetic field, and how a changing magnetic field induces an electric field, and how both are aspects of electromagnetic radiation. Electromagnetic radiation, as we’ve seen in previous exercises, is pervasive. Yet un ...
... Learning outcome: Ultimately, to understand how a changing electric field induces a magnetic field, and how a changing magnetic field induces an electric field, and how both are aspects of electromagnetic radiation. Electromagnetic radiation, as we’ve seen in previous exercises, is pervasive. Yet un ...
