Streamer discharges in High magnetic fields F. Manders 1 , P
... same Hall angle with the local, radial directed electric field • Field enhancement after streamer formation indeed leads to a new propagation direction •Photoionization does not play a mayor role in the direction where the discharge is growing, otherwise the discharge would go straight ahead in a ma ...
... same Hall angle with the local, radial directed electric field • Field enhancement after streamer formation indeed leads to a new propagation direction •Photoionization does not play a mayor role in the direction where the discharge is growing, otherwise the discharge would go straight ahead in a ma ...
Waves & Oscillations Physics 42200 Spring 2015 Semester
... • But geometric optics could not explain – Polarization – Diffraction – Interference ...
... • But geometric optics could not explain – Polarization – Diffraction – Interference ...
F = BIL (f=force, b=magnetic field, i=current, l
... -The source of a magnetic field is moving charge, and the effect of a magnetic field is to exert a force on other moving charge placed in the field -The magnetic field is a vector quantity -We denote the magnetic field by the symbol B and represent it graphically by field lines -These lines are draw ...
... -The source of a magnetic field is moving charge, and the effect of a magnetic field is to exert a force on other moving charge placed in the field -The magnetic field is a vector quantity -We denote the magnetic field by the symbol B and represent it graphically by field lines -These lines are draw ...
Outline
... 1. force due to one charge 2. force due to several charges D. electric field 1. definition 2. field due to one charge 3. field due to many charges E. motion of charged particles 4. Electrical Energy A. review of work concept B. calculating work done by an electric field C. electric potential 1. defi ...
... 1. force due to one charge 2. force due to several charges D. electric field 1. definition 2. field due to one charge 3. field due to many charges E. motion of charged particles 4. Electrical Energy A. review of work concept B. calculating work done by an electric field C. electric potential 1. defi ...
Physics 202 Exam 1.doc
... Answer ‘e’ is to be used as ‘none of the above’, ‘cannot be answered’, etc You may not have a cell phone or any electronic device (other than a non-programmable calculator with one memory and two pencils. You may not have any paper even blank or notes at your seat. You are to take your test question ...
... Answer ‘e’ is to be used as ‘none of the above’, ‘cannot be answered’, etc You may not have a cell phone or any electronic device (other than a non-programmable calculator with one memory and two pencils. You may not have any paper even blank or notes at your seat. You are to take your test question ...
ATAR Year 12 sample course outline - SCSA
... Wave particle duality and the quantum theory • light exhibits many wave properties • a wave model explains reflection, refraction, dispersion, diffraction and interference; a transverse wave model is required to explain polarisation • electromagnetic waves are transverse waves made up of mutually pe ...
... Wave particle duality and the quantum theory • light exhibits many wave properties • a wave model explains reflection, refraction, dispersion, diffraction and interference; a transverse wave model is required to explain polarisation • electromagnetic waves are transverse waves made up of mutually pe ...
The Measurement of a Magnetic Field in Fundamental Units
... In this lab, we wish to determine B, the magnetic field of the solenoid; thus we transpose the equation as follows: B = F/IL. I and L are easily measured, but finding F doesn’t seem quite so straightforward. However, if we set things up right, we can treat the magnetic force much like a force produc ...
... In this lab, we wish to determine B, the magnetic field of the solenoid; thus we transpose the equation as follows: B = F/IL. I and L are easily measured, but finding F doesn’t seem quite so straightforward. However, if we set things up right, we can treat the magnetic force much like a force produc ...
Magnetic monopole
A magnetic monopole is a hypothetical elementary particle in particle physics that is an isolated magnet with only one magnetic pole (a north pole without a south pole or vice versa). In more technical terms, a magnetic monopole would have a net ""magnetic charge"". Modern interest in the concept stems from particle theories, notably the grand unified and superstring theories, which predict their existence.Magnetism in bar magnets and electromagnets does not arise from magnetic monopoles. There is no conclusive experimental evidence that magnetic monopoles exist at all in our universe.Some condensed matter systems contain effective (non-isolated) magnetic monopole quasi-particles, or contain phenomena that are mathematically analogous to magnetic monopoles.