MAGNETISM Adapted from Mr. Dellibovi print handouts at 6 to a page for a 4 page student guide
Magnets- History and Interesting Facts Lodestones Natural Magnets Magnetite, Fe3O4 (an oxide of iron) Ancient civilizations (Greek 590 BCE, Chinese 2600 BCE) realized that these stones would cling to iron tools. A suspended, pivoting lodestone always pointed along the North-South axis Magnetite crystals have been found in living organisms Magnetotactic bacteria! Migratory Bird brains!! Other migratory animals: bees, fish Human brains!!! YOU HAVE ROCKS IN YOUR HEAD!!!!!
History of Permanent Magnets By 2nd Century AD, Chinese were able to make permanent magnets by repeatedly __________________________________________________________________________________________________________________. Retained strength of a magnet depends on ___________________________________. ________: loses magnetism quickly _________________ (paper clips, nails): gradual loss ________: retains power for a long time and is referred to as a “permanent magnet”
Magnetic Poles Magnets produce a force on other objects Poles are regions where the magnetic force is the strongest Like magnetic poles _______________. Opposite magnetic poles _____________. Most magnets have ______ poles (dipole), but can have three or more!
Monopole? (No, not Monopoly!) Monopole: piece of a magnet that is simply a north pole or a south pole Many have tried to isolate a monopole by breaking magnets in half. No matter how we break a magnet, the pieces are always dipoles! ________________________________________ Do not pass GO. Do not collect $200.
Magnetic Field Every magnet establishes in the space surrounding it, a magnetic field (B-field) Map field with a _____________________ Direction of field is direction in which the test-compass needle will point at that location. Draw field lines so that compass always points _______ to the field lines. Field lines point from N to S __________ the magnet Field lines point from S to N __________ the magnet Field lines form closed loops Field lines never _____________________ SI unit for B (magnetic field strength) is the tesla (T)
Magnetic Field Mapping with Test-Compass Field Lines Form Closed Loops Field Mapped by Iron Filings
Earth’s Magnetism Magnetic field has reversed direction ~300 times in the past 170 million years Magnetic poles wander! Magnetic & geographic poles not the same. Magnetic declination: 11.5° What’s strange about this picture? ____________________________________________________________
Diagramming 3-D Magnetic Fields Not everybody is an artist. Use 2-D images to draw 3-D field vectors. If field points perpendicularly into the page or board, use If field points perpendicularly out of the page or board, use Otherwise, draw the lines neatly. Don’t forget, field lines are vectors!
Magnetism on an Atomic Level Charge ________________ (or electric __________) produces magnetic force Electrons function as a subatomic dipole Electron “spin” Electrons existing in pairs: B-fields cancel Electron “orbit” around nucleus Random “orbits” of electrons: B-fields cancel
Diamagnetism Even “non magnetic” materials respond to an applied B-field Applied B-field changes orbital motion of electrons Produces a field that _____________ applied field ______________ by applied field Diamagnetic materials have no _____________ atomic dipoles Occurs for ______ substances, but may be swamped by other magnetic effects
Paramagnetism Paramagnetic materials are ___________ when placed in a strong B-field. Composed of atoms with ____________ atomic dipoles Atomic dipoles do not interact w/ one another Atomic dipoles oriented randomly Material has no dipole as a whole A strong B-field re-orients these atomic dipoles in _____________ as applied field
Ferromagnetism Naturally “magnetic”: magnetite, iron, nickel, cobalt, steel, Alnico, other alloys Strongly attracted to poles of a magnet Easily magnetized Atomic dipoles ____________ with dipoles of adjacent atoms Dipoles align spontaneously, w/o an applied field Many atomic dipoles cooperatively align Creates regions of __________ orientations (_____________)
Magnetic Domains Domain: region where many atomic dipoles _________ Usually aligned randomly and effects cancel BUT… Place ferromagnetic material in strong B-field Entire domains realign with applied field Size & shape of domains remains the same Causes irreversible re-orientation of domains Creates permanent magnets
Reorientation of Domains Electrons in domains align with applied field Substance is Permanently Magnetized Domains are not aligned
Electrodynamics: The Study of Electromagnetism Magnetism is caused by charge in motion. Charges at rest have just an electric field But, when they move, they generate both an electric field and a magnetic field Can look at individual charges or electric current in a wire Direction of current determines direction of the magnetic field. Use right hand rules for analysis.
First Right Hand Rule: thumb points in direction of _________, fingers curl in direction of ____________ . Note compass readings. Use for: ___________________
Magnetic field of a long straight wire B: magnetic field strength (teslas) I: current (amperes) r: radius from wire μo: ____________________________________ μo = The shape of this magnetic field is: _________________ _____________________________________________
1st Right Hand Rule- Thumb points in the direction of the current, fingers curl in the direction of the created magnetic field – up through the coils and around the outside. Use for ________________________________________________ Fig 19.20b, p.682 Slide 19
Magnetic field of loops of wire (or a coil) carrying current where n is the NUMBER of loops (in this example n=8) How is this equation different from the mag field of a straight wire? The strength of the field is more in a loop than in the straight wire and a single loop.
2ND Right Hand Rule Gives the direction of the FORCE exerted on a current (or charge) by an external magnetic field Point thumb of RH in direction of current (or motion of positive charge) Point fingers through in direction of magnetic field Palm pushes in direction of ___________
2ND Right Hand Rule Fingers point to B, the direction of magnetic field lines. Thumb points to v, which is direction of velocity of positive charge Deflecting force is shown by direction of palm pushing.
2ND Right Hand Rule
Magnetic Force on a Moving Charge F = Bqv·sin Θ B: field strength in _____________ q: charge in _________________ v: charge velocity in ____________ Θ: angle between __________
Magnetic Force on a Current-Carrying Wire F = B·I·L B: field strength in _______________ I: current in ______________ L: length of current-carrying wire in __________