* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Magnetism – Part 3
Neutron magnetic moment wikipedia , lookup
Electric machine wikipedia , lookup
Hall effect wikipedia , lookup
Magnetic field wikipedia , lookup
Superconductivity wikipedia , lookup
Superconducting magnet wikipedia , lookup
Electromotive force wikipedia , lookup
Magnetic monopole wikipedia , lookup
Skin effect wikipedia , lookup
Magnetoreception wikipedia , lookup
Magnetohydrodynamics wikipedia , lookup
Electricity wikipedia , lookup
History of electrochemistry wikipedia , lookup
Scanning SQUID microscope wikipedia , lookup
Magnetochemistry wikipedia , lookup
Faraday paradox wikipedia , lookup
Friction-plate electromagnetic couplings wikipedia , lookup
Eddy current wikipedia , lookup
History of electromagnetic theory wikipedia , lookup
Multiferroics wikipedia , lookup
Electromagnet wikipedia , lookup
Force between magnets wikipedia , lookup
Lorentz force wikipedia , lookup
MAGNETISM – PART 3 CALENDAR Magnetism Monday – Recorded Lecture. Today – Brief review of the material + a few problems. Today, Friday we will continue with chapter 20 materials. There will be a Quiz on Magnetism on Friday. 2 ABOUT THOSE EXAMS - Magnetism Grades look pretty bad. I will review on Friday after I have a look at the papers. Each exam (both sections) had similar problems. A Kirchoff Law Problem – simple A combine either capacitors or resistors and calculate what was happening at one of them. A problem involving polarization – a thinker. A question on how much energy was required to bring three charges together. 3 THESE WERE THE HINTS I GAVE YOU! Magnetism Anything in the three chapters is fair game. Read the sections on charge and charge effects very carefully. We didn’t cover some of this in class. (Problem 2) Know the difference between Potential and Potential energy. Know how much work it takes to create a charge distribution. We did it in class. (Problem 1) Know how to add capacitors and resistors and how to solve simple circuit problems. (Problem 3) There WILL be a Kirchhoff's Law problem. (Problem 4) Coulomb’s Law and the addition of forces. Calculation of the potential (scalar) Be sure to understand all of the HW problems that were assigned – or not assigned! 4 Magnetism The force is perpendicular to the direction of motion. The force has a constant magnitude = Bqv This will produce circular motion as in PHY2053. 5 Magnetism 6 LOOK AT THE DIRECTION OF THE FORCE AND THE VELOCITY Magnetism 7 RECALL mv 2 qvB r mv r Bq Recall : v r or r v/ v Bq r m This is called the cyclotron angular frequency Magnetism v2 Centripeta l Accelerati on r mv 2 Centripeta l Force r The magnetic force is qvB 8 Magnetism Bq 2f m 1 mv T period f r Bq 9 OFF ANGLE Magnetism PITCH P v parallelT P 10 PROBLEM (a) the magnitude and direction of the magnetic field that will cause the electron to follow the semicircular path from A to B and Magnetism An electron at point A in the figure has a speed v0 of 1.4 x 106 m/s. Find (b) the time required for the electron to move from A to B. (c) What magnetic field would be needed if the particle were a proton instead of an electron? m=9.1E-31 Kg e=1.6E-19 C 11 FORCE ON A WIRE CARRYING A CURRENT IN A B FIELD F Bil Magnetism A straight vertical wire carries a current of 1.20 A downward in a region between the poles of a large electromagnet where the field strength is 0.588 T and is horizontal. What are the magnitude and direction of the magnetic force on a 1.00 cm section of this wire if the magnetic-field direction is (a) toward the east, (b) toward the south 13 • Novel applications have been devised to make use of the force that a magnetic field exerts on a conductor carrying current. Magnetism 14 CURRENT LOOP Loop will tend to rotate due to the torque the field applies to the loop. Magnetism What is force on the ends?? 15 THE LOOP (FROM THE TOP) OBSERVATION Force on Side 2 is out of the paper and that on the opposite side is into the paper. No net force tending to rotate the loop due to either of these forces. The net force on the loop is also zero, pivot Magnetism 16 THE OTHER SIDES t1=F1 (b/2)Sin(q) =(B i a) x (b/2)Sin(q) total torque on the loop is: 2t1 Total torque: t=(iaB) bSin(q) =iABSin(q) (A=Area) Magnetism 17 APPLICATION: THE MOTOR If the conductor is a loop, the torque can create an electric motor. Magnetism 19 Magnetism 20 Magnetism 21 Magnetism A circular coil of wire 8.6 cm in diameter has 15 turns and carries a current of 2.7 A. The coil is in a region where the magnetic field is 0.56 T. What orientation of the coil gives the maximum torque on the coil. What is this maximum torque? 22 ANOTHER APPLICATION THE GALVANOMETER Magnetism 23 Magnetism CURRENTS CAUSE MAGNETIC FIELDS 24 MAGNETIC FIELD OF LONG STRAIGHT CONDUCTOR – Magnetism • Placed over a compass, the wire would cause the compass needle to deflect. This was the classic demonstration done by Oersted as he demonstrated the effect. 25 RESULT Magnetism 0 I B 2r r Tm 0 4 10 (exact) A 7 26 FORCE BETWEEN TWO CURRENT CARRYING CONDUCTORS Magnetism First wire produces a magnetic field at the second wire position. The second wire therefore feels a force = Bil 27 TWO WIRES Magnetism B From First Wire 0 I1 B 2r 0 I1 F BI 2l I 2l 2r F 0 I1 I 2 l 2r 28 CURRENTS IN A LOOP – Magnetism 29 FIELD OF A CURRENT LOOP Magnetism B 0 NI 2R N turns of wire 30 Magnetism 31 B 0 nI SOLONOID Magnetism Total number N of Turns n L Length B=~0 outside 32 THE SOLENOID – Magnetism 0 NI B 2r B=0 outside 33 Magnetism 34