LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034
... 02. Give the geometry of a Nicol prism 03. Define specific rotatory power of an optically active substance 04. State Gauss’s law in differential form 05. Three capacitors of capacitance values 1 F, 2 F and 3 F are arranged in series. What is the effective capacitance? 06. Define the ampere, the u ...
... 02. Give the geometry of a Nicol prism 03. Define specific rotatory power of an optically active substance 04. State Gauss’s law in differential form 05. Three capacitors of capacitance values 1 F, 2 F and 3 F are arranged in series. What is the effective capacitance? 06. Define the ampere, the u ...
![[2011 question paper]](http://s1.studyres.com/store/data/008881811_1-8ef23f7493d56bc511a2c01dcc81fc96-300x300.png)
[2011 question paper]
... Hint: Express ψ(x, t = 0) in terms of energy eigenstates and evolve them forward in time. 3. Consider propagation of a plane electromagnetic wave with wave vector k and angular frequency ω in a region containing free electrons of number density ne . (a) Write down the equation of motion of an electr ...
... Hint: Express ψ(x, t = 0) in terms of energy eigenstates and evolve them forward in time. 3. Consider propagation of a plane electromagnetic wave with wave vector k and angular frequency ω in a region containing free electrons of number density ne . (a) Write down the equation of motion of an electr ...
Electric Fields ch 26
... For electric fields of multiple point charges, find the electric field from each point separately and then add them up (add as vectors with direction) Electric Field Lines help visualize the e-field. E field lines are closer where the field is stronger E field lines begin on a positive charg ...
... For electric fields of multiple point charges, find the electric field from each point separately and then add them up (add as vectors with direction) Electric Field Lines help visualize the e-field. E field lines are closer where the field is stronger E field lines begin on a positive charg ...
Biot-Savart law
... In which the magnetic flux density (or magnetic induction) in free space is: and where the free space permeability is ...
... In which the magnetic flux density (or magnetic induction) in free space is: and where the free space permeability is ...
Chapter 29 Magnetic Fields
... a) Electric - charge created just by sitting b) Magnetic – current ultimately charged at source, but charge must be moving right hand current 2) Field Lines a) Electric – lines start and end b) Magnetic – circular loop lines ...
... a) Electric - charge created just by sitting b) Magnetic – current ultimately charged at source, but charge must be moving right hand current 2) Field Lines a) Electric – lines start and end b) Magnetic – circular loop lines ...
Chapter TM30
... Gauss’s law (electrical): The total electric flux through any closed surface equals the net charge inside that surface divided by o This relates an electric field to the charge distribution that creates it Gauss’s law (magnetism): The total magnetic flux through any closed surface is zero This says ...
... Gauss’s law (electrical): The total electric flux through any closed surface equals the net charge inside that surface divided by o This relates an electric field to the charge distribution that creates it Gauss’s law (magnetism): The total magnetic flux through any closed surface is zero This says ...
Slide 1
... Electrons spinning around atoms are moving electric charges. Usually, opposite direction spinning electrons pair up, and cancel the magnetic field. ...
... Electrons spinning around atoms are moving electric charges. Usually, opposite direction spinning electrons pair up, and cancel the magnetic field. ...
A. the rate of change of the magnetic field B. the rate of
... the rate of change of the magnetic field the rate of change of the electric field the rate of change of the magnetic flux the rate of change of the electric flux zero ...
... the rate of change of the magnetic field the rate of change of the electric field the rate of change of the magnetic flux the rate of change of the electric flux zero ...
111 Quizz 1 ``solve``
... 5 ) Positive charge +Q is uniformly distributed on the upper half of a semicircular insulating rod, and negative charge –Q is uniformly distributed on the lower half. The direction of the electric field at point P, the center of curvature of the rod, is a. Upward. b. Downward. c. Points to the left. ...
... 5 ) Positive charge +Q is uniformly distributed on the upper half of a semicircular insulating rod, and negative charge –Q is uniformly distributed on the lower half. The direction of the electric field at point P, the center of curvature of the rod, is a. Upward. b. Downward. c. Points to the left. ...
