Nuclear orientation

Nuclear orientation, in nuclear physics, is the directional ordering of an assembly of nuclear spins with respect to some axis in space.^[1][2]

A nuclear level with spin in a magnetic field will divide into magnetic sub-levels with an energy spacing.^[3] The populations of these levels are determined by the Boltzmann distribution at a steady temperature and will essentially be equal. The exponential in the Boltzmann distribution should not be equal to 1 to obtain unequal populations. To achieve this, cooling to a temperature of around 10 millikelvin is needed. Typically, this is achieved by implanting the nuclei of interest into ferromagnetic hosts.

In the mid-1940s, Yevgeny Zavoisky developed electron paramagnetic resonance, eventually leading to the concept of nuclear orientation.^[4] In the early 1950s, Neville Robinson, Jim Daniels, and Michael Grace produced an example of nuclear orientation for the first time at the Clarendon Laboratory, University of Oxford.^[5] There is now a Nuclear Orientation Group at Oxford.^[3]

Bibliography

• K. S. Krane, Nuclear orientation and nuclear structure. Hyperfine Interactions, Volume 43, Numbers 1–4, pages 3–14, December, 1988. doi:10.1007/BF02398283
• B. Bleaney, Cross-relaxation and nuclear orientation in ytterbium vanadate. Proceedings: Mathematical, Physical and Engineering Sciences, Volume 455, Number 1988, pages 2835–2839, 8 August 1999. Published by The Royal Society.
• B. Bleaney, Dynamic nuclear polarization and nuclear orientation in terbium vanadate. Applied Magnetic Resonance, Volume 21, Number 1, pages 35–38, December, 1988. doi:10.1007/BF03162437

See also

• Nuclear magnetic resonance

References