Magnetism

1. Magnetism GLY 4200 Fall, 2012

2. Early Observations of Magnetism • Ancient Greeks, especially those near the city of Magnesia, and Chinese, observed natural stones that attracted iron • The naturally magnetic stones are called lodestone • The Chinese discovered a steel needle stroked by a lodestone became magnetic, and, if suspended, pointed N-S

3. What is Magnetism? • Although discovered relatively early in man’s history, and exploited, the causes of magnetism were not understood

4. Orbiting Electrons • Moving electrical currents generate magnetic forces • This includes electrons orbiting and spinning around a nucleus • Each orbiting electron possesses a magnetic moment equal to 1 Bohr magnetron (μB), or 0.927 x 10-23 Am2 (Amps meter2)

5. Isolated Ions • Net magnetic moment is equal to the sum of: • Orbital contributions • Spin contributions • Filled orbitals give a net contribution of zero to the magnetic moment since the two electrons orbit and spin oppositely

6. Net Magnetic Moments • Generated only in atoms or ions with incomplete electronic shells • Most important subshells likely to be incompletely filled are the 3d (first transition row) and the 4f (rare earth elements) • The second and third transition rows (4d and 5d electrons) also produce magnetic moments but the elements, and hence the minerals, are rare

7. Three d Electrons • Three d electrons have large spin and relatively low orbital contributions to magnetic moments • In compounds the orbital contribution is affected by, and largely negated by, bonding to other ions • Since the 4s electrons are outside the 3d, the 3d electrons are partially shielded and the orbital contribution will not be entirely negated

8. Spin Contribution • Spin contribution is largely responsible for the 3d electrons contribution to the magnetic moment and is proportional to the number of unpaired d electrons

9. Four f Electrons • In 4f electron containing elements, the electrons are well-shielded by outer electrons • The 4f electrons are not involved in bonding and both orbital and spin effects contribute to the total magnetic moment

10. Magnetic Susceptibility • An aggregate of ions or atoms may behave much differently than an individual ion • Magnetic Susceptibility is the ratio of induced magnetization to the strength of the external magnetic field causing the induced magnetization • Magnetic susceptibility may be grouped into different classes of behavior

11. Diamagnetism • Minerals possessing ions with totally paired electron spins • No transition elements are present, and the net magnetic moment is zero • In a strong magnetic field diamagnetic materials exhibit a small negative magnetic susceptibility, which means they are weakly repelled from the magnet

12. Paramagnetism • Transition metals ions are present but the magnetic moments are randomly distributed • Net field is zero, although an external field will produce some alignment of dipoles, which disappears when the external field is removed • Alignment of the magnetic dipoles produces a small positive magnetic susceptibility and these minerals are attracted to a magnet in a strong magnetic field • Example: olivine (Mg, Fe)2SiO4

13. Ferromagnetism • Adjacent moments are aligned • After an external field is applied the dipoles interact and the field remains locked in • The magnetism is due to unbalanced electron spin in the inner orbits of the elements concerned • The ionic spacing in ferromagnetic crystals is such that very large forces, called exchange forces, cause the alignment of all atoms to give highly magnetic domains

14. Making a Magnet • In unmagnetized metal these domains are randomly oriented • After a strong magnetic field is applied the domains align and the material remains a strong magnet after the external field is removed • Examples of ferromagnetic materials are the metals cobalt and nickel, and alloys such as alnicol

15. Curie Temperature • Upon heating the domains may become randomly aligned once again • This transition to a paramagnetic state is called the Curie temperature, after Pierre Curie, who was instrumental in elucidating the behavior of paramagnetic materials • In metallic iron the Curie temperature is 770 ̊C

16. Antiferromagnetism • Alternate atoms have oppositely directed moments • Magnetic susceptibility is low but increases with increasing T up to the Néel temperature • Above this temperature the susceptibility falls and the material is paramagnetic • Examples include Cr metal, and compounds like MnO, MnS, and FeO

17. Louis E.F. Néel • The Néel temperature is named after L.E.F. Néel, who discovered the phenomenon of the transition from antiferromagnetism to paramagnetism in 1930 • Born 1904, died 2000 • Nobel prize in physics, 1970

18. Ferrimagnetism • Adjacent atoms have antiparallel alignment, but the magnitude of the magnetic moments of different ions is different • Cancellation is incomplete and strong magnetism may exist • Alternatively, the number of magnetic moments aligned in one direction may be different than in another direction • Ferrimagnetic materials may have magnetism similar to that of ferromagnetic materials

19. Incorrect Identification • Some minerals have been incorrectly described in the literature as being ferromagnetic when in fact they are ferrimagnetic • Examples include ilmenite FeTiO3, magnetite (Fe3O4 or Fe2+Fe23+O4) and pyrrhotite (Fe1-xS, x = 0.0 → 0.2) • Curie temperature for magnetite is 85 ̊ C, much lower than for metallic iron

20. Magnetic Separation • Magnetic separation, based on the differing magnetic susceptibilities of different minerals, is used in processing minerals since many minerals, especially those containing iron, are attracted to or repelled from a magnet in a strong magnetic field • Magnetic separation is used in both laboratory and commercial scales for mineral separation • Picture: Frantz laboratory magnetic mineral separator

21. Aerial Remote Sensing of Magnetism • An airplane flies over an area towing a magnetometer, which measures local perturbations of the earth's magnetic field • These aircraft fly low (100 to 300 meters) and use highly sensitive magnetometers

22. Diagram of Magnetometer Tow • Catalina aircraft fitted with a magnetometer

23. Sulfide Ore Bodies • Many sulfide ore bodies are associated with magnetite and, although the magnetite itself may have no economic value, the sulfides often are valuable • This method is rapid and relatively cheap, especially in areas of rough terrain • Any positive magnetic anomalies must be verified by subsequent geophysical and geochemical exploration

24. Paleomagnetism • Ferrimagnetic minerals are permanently magnetized • Study of natural remnant magnetism of rocks yields a record of the earth’s magnetic field through time • This reveals polarity reversals, and can aid in the study of plate motions

25. Polarity Reversal Record • Paleomagnetic record of 0-4 MYBP