User:John R. Brews/Sandbox: Difference between revisions
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Although this approach has some application to those paramagnetic and ferrimagnetic materials that are ionic solids with localized moments, it doesn't work for ferromagnetic materials because most are metals with itinerant electrons.<ref name=Spaldin0> | Although this approach has some application to those paramagnetic and ferrimagnetic materials that are ionic solids with localized moments, it doesn't work for ferromagnetic materials because most are metals with itinerant electrons.<ref name=Spaldin0> | ||
Chapter 9 of reference cited above: {{cite book |title=Magnetic materials: fundamentals and applications |author=Nicola A Spaldin |chapter=Chapter 9: Ferrimagnetism |pages=pp. 113 ''ff''|isbn=0521886694 |year=2010 |edition=2nd ed |publisher=Cambridge University Press |url=http://www.google.com/search?tbs=bks:1&tbo=p&q=ferrimagnets++next+section+%22molecular+field%22+inauthor:Spaldin&num=10}} | |||
</ref> | </ref> | ||
<references/> | <references/> |
Revision as of 13:56, 15 December 2010
Interacting atoms
The outline of paramagnetism above ignores all interactions between atoms, and makes them all act individually. A natural question is: if the torque aligning atoms is due to the magnetic field in the atom's vicinity, shouldn't the field include the effect of the neighboring atoms upon the field?
Such a modified theory was proposed by Pierre-Ernest Weiss by introducing the notion of a molecular field, a magnetic field contribution that was proportional to the magnetization in the vicinity of an atom:[1]
where HW is the "Weiss field" and γ is the "molecular field constant". This contribution is added to the applied magnetic field HA to obtain the total field H:
Given a method to determine M from H, we then find:
an implicit determination of M for any given HA. In particular, if we adopt the Brillouin approach based upon BJ as a function of
all that is needed is to replace H with the modified H above that includes the Weiss field.
Although this approach has some application to those paramagnetic and ferrimagnetic materials that are ionic solids with localized moments, it doesn't work for ferromagnetic materials because most are metals with itinerant electrons.[2]
- ↑ Nicola A Spaldin (2010). “§5.2 The Curie-Weiss law”, Magnetic materials: fundamentals and applications, 2nd ed. Cambridge University Press, p. 53. ISBN 0521886694.
- ↑ Chapter 9 of reference cited above: Nicola A Spaldin (2010). “Chapter 9: Ferrimagnetism”, Magnetic materials: fundamentals and applications, 2nd ed. Cambridge University Press, pp. 113 ff. ISBN 0521886694.