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Published On: Oct 29, 2003 10:25 PM
Total entries in this category:
Published On: Oct 29, 2003 10:25 PM
Attracted and Replused? Now you've got to pick just one!
East, West, North, and... North?
There's something weird going on.
Electricity and magnetism are really the same thing. Magnets moving beside a
wire make electricity; electricity going through a coil of wire wrapped around a
metal core makes magnetism. Permanent electricity exists as single charged
particles like electrons and protons. Yet permanent magnets always have two
poles: north and south. No matter how you break apart a bar magnet, the pieces
will always exhibit two magnetic poles; you never end up with a single magnetic
pole or so-called monopole . So if electricity and magnetism are the same
thing, how come we see electrons every time we scuff our feet on the carpet and
touch a doorknob, but we never see a magnetic
monopole?
Maybe we've never seen magnetic monopoles because we've never looked in the right place: so-called momentum space. Belle Dume of Physics Web picks up the story :
Paul Dirac first put forward the idea of the magnetic monopole - a particle that carries an isolated north or south magnetic pole - in 1931, but all experimental searches for these elusive particles have proved fruitless. However, a group of physicists from Japan, China and Switzerland are now claiming that they have found indirect evidence for monopoles. The team observed an anomalous Hall effect in a ferromagnetic crystal that they say can only be explained by the existence of magnetic monopoles (Z Fang et al. 2003 Science 302 92).
The lack of symmetry between electric and magnetic fields is one of the oldest puzzles in physics. Why is it possible to isolate positive and negative electric charges, but not north and south magnetic poles? Dirac linked the existence of magnetic monopoles with the quantization of electric charge - another puzzle that is still not fully understood - but they have never been detected in an experiment.
Magnetic monopoles are also predicted by some theories that seek to unify the electroweak and strong interactions. However, the monopole masses that are predicted by these so-called grand unified theories are much too large - about 10^16 giga-electronvolts - to be detected in experiments.
Instead of searching for magnetic monopoles in real space, Yoshinori Tokura of the National Institute of Advanced Industrial Science and Technology (AIST) in Tsukuba and co-workers turned to momentum space - the mathematical space in which condensed matter physicists construct Fermi surfaces, Brillouin zones and so on. The team was motivated by recent theoretical work which suggested that the behaviour of magnetic monopoles in momentum space is closely related to the anomalous Hall effect .
Tokura and co-workers placed a high-quality crystal made of strontium, ruthenium and oxygen in a magnetic field that pointed in the z direction, and then measured the transverse resistivity - the resistivity in the y direction - as a current flowed in the x direction. They found that the resistivity did not change linearly with temperature, as expected, but varied non-monotonously and even changed sign.
The researchers also measured the transverse optical conductivity of a thin film of the crystal using a technique known as high-resolution Kerr microscopy and found a sharp peak at low energies. According to Tokura and co-workers, this peak can only be explained by the presence of monopoles in the band structure of the crystal.
The Japan-China-Switzerland team believe that both of these anomalous effects are "fingerprints" for the existence of magnetic monopoles. The team now plans to study materials that show even larger anomalous effects. "The laws of electromagnetism are the starting point for every area of physics," says team member Kei Takahashi of the University of Geneva. "From this view point, we have proved that we can investigate most physics subjects - including particle physics and cosmology - in experiments on solid crystals."
Maybe we've never seen magnetic monopoles because we've never looked in the right place: so-called momentum space. Belle Dume of Physics Web picks up the story :
Paul Dirac first put forward the idea of the magnetic monopole - a particle that carries an isolated north or south magnetic pole - in 1931, but all experimental searches for these elusive particles have proved fruitless. However, a group of physicists from Japan, China and Switzerland are now claiming that they have found indirect evidence for monopoles. The team observed an anomalous Hall effect in a ferromagnetic crystal that they say can only be explained by the existence of magnetic monopoles (Z Fang et al. 2003 Science 302 92).
The lack of symmetry between electric and magnetic fields is one of the oldest puzzles in physics. Why is it possible to isolate positive and negative electric charges, but not north and south magnetic poles? Dirac linked the existence of magnetic monopoles with the quantization of electric charge - another puzzle that is still not fully understood - but they have never been detected in an experiment.
Magnetic monopoles are also predicted by some theories that seek to unify the electroweak and strong interactions. However, the monopole masses that are predicted by these so-called grand unified theories are much too large - about 10^16 giga-electronvolts - to be detected in experiments.
Instead of searching for magnetic monopoles in real space, Yoshinori Tokura of the National Institute of Advanced Industrial Science and Technology (AIST) in Tsukuba and co-workers turned to momentum space - the mathematical space in which condensed matter physicists construct Fermi surfaces, Brillouin zones and so on. The team was motivated by recent theoretical work which suggested that the behaviour of magnetic monopoles in momentum space is closely related to the anomalous Hall effect .
Tokura and co-workers placed a high-quality crystal made of strontium, ruthenium and oxygen in a magnetic field that pointed in the z direction, and then measured the transverse resistivity - the resistivity in the y direction - as a current flowed in the x direction. They found that the resistivity did not change linearly with temperature, as expected, but varied non-monotonously and even changed sign.
The researchers also measured the transverse optical conductivity of a thin film of the crystal using a technique known as high-resolution Kerr microscopy and found a sharp peak at low energies. According to Tokura and co-workers, this peak can only be explained by the presence of monopoles in the band structure of the crystal.
The Japan-China-Switzerland team believe that both of these anomalous effects are "fingerprints" for the existence of magnetic monopoles. The team now plans to study materials that show even larger anomalous effects. "The laws of electromagnetism are the starting point for every area of physics," says team member Kei Takahashi of the University of Geneva. "From this view point, we have proved that we can investigate most physics subjects - including particle physics and cosmology - in experiments on solid crystals."
Posted: Mon - October 6, 2003 at 06:20 PM