Magnetic susceptibility

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In electromagnetism the magnetic susceptibility (latin: susceptibilis “receptiveness”) is the degree of magnetization of a material in response to an applied magnetic field.

Definition of volume susceptibility

See also Relative permeability.

The volume magnetic susceptibility, represented by the symbol <math>\ \chi_{v}</math> (often simply <math>\ \chi</math>, sometimes <math>\ \chi_m</math> — magnetic, to distinguish from the electric susceptibility), is defined by the relationship

<math>

\mathbf{M} = \chi_{v} \mathbf{H} </math>

where, in SI units,

M is the magnetization of the material (the magnetic dipole moment per unit volume), measured in amperes per meter, and
H is the magnetic field strength, also measured in amperes per meter.

The magnetic induction B is related to H by the relationship

<math>

\mathbf{B} \ = \ \mu_0(\mathbf{H} + \mathbf{M}) \ = \ \mu_0(1+\chi_{v}) \mathbf{H} \ = \ \mu \mathbf{H} </math>

where μ0 is the magnetic constant (see table of physical constants), and <math> \ (1+\chi_{v}) </math> is the relative permeability of the material. The magnetic susceptibility χv and the magnetic permeability μ are related by the following formula:

<math>\mu = \mu_0(1+\chi_v) \,</math> .

Sometimes [1] an auxiliary quantity, called intensity of magnetization and measured in tesla, is defined as

<math>\mathbf{I} = \mu_0 \mathbf{M} \,</math> .

This allows an alternative description of all magnetization phenomena in terms of the quantities I and B, as opposed to the commonly used M and H.

Conversion between SI and cgs units

Note that these definitions are according to SI conventions. However, many tables of magnetic susceptibility give cgs values that rely on a different definition of the permeability of free space. The cgs value of volume susceptibility is multiplied by 4π to give the SI volume susceptibility value:

<math>\chi_v^{SI}=4\pi\chi_v^{cgs}</math>

For example, the cgs volume magnetic susceptibility of water at 20°C is -7.19×10-7 which is -9.04×10-6 using the SI convention. sandip

Mass susceptibility and molar susceptibility

There are two other measures of susceptibility, the mass magnetic susceptibilitymass or χg, sometimes χm), measured in m3·kg-1 in SI or in cm3·g-1 in cgs and the molar magnetic susceptibilitymol) measired in m3·mol-1 (SI) or cm3·mol-1 (cgs) that are defined below, where ρ is the density in kg·m-3 (SI) or g·cm-3 (cgs) and M is molar mass in kg·mol-1 (SI) or g·mol-1 (cgs).

<math>\chi_{mass}=\chi_v/\rho</math>
<math>\chi_{mol}=M\chi_{mass}=M\chi_v/\rho</math>

Sign of susceptibility: diamagnetics and paramagnetics

If χ is positive, then (1+χv) > 1 (or, in cgs units, (1+4πχv) > 1) and the material is called paramagnetic. In this case, the magnetic field is strengthened by the presence of the material. Alternatively, if χ is negative, then (1+χv) < 1 (or, in cgs units, (1+4πχv) < 1), and the material is diamagnetic. As a result, the magnetic field is weakened in the presence of the material.

Experimental methods to determine susceptibility

Volume magnetic susceptibility is measured by the force change felt upon the application of a magnetic field gradient [2]. Early measurements were made using the Gouy balance where a sample is hung between the poles of an electromagnet. The change in weight when the electromagnet is turned on is proportional to the susceptibility. Today, high-end measurement systems use a superconductive magnet. An alternative is to measure the force change on a strong compact magnet upon insertion of the sample. This system, widely used today, is called the Evan's balance.[3] For liquid samples, the susceptibility can be measured from the dependence of the NMR frequency of the sample on its shape or orientation[4][5][6][7][8].

Tensor susceptibility

The magnetic susceptibility of most crystals is not a scalar. Magnetic response M is dependent upon the orientation of the sample and can occur in directions other than that of the applied field H. In these cases, volume susceptibility is defined as a tensor

<math> M_i=\chi_{ij}H_j </math>

where i and j refer to the directions (e.g., x, y and z in Cartesian coordinates) of the applied field and magnetization, respectively. The tensor is thus rank 2, dimension (3,3) describing the component of magnetization in the i-th direction from the external field applied in the j-th direction.

Differential susceptibility

In ferromagnetic crystals, the relationship between M and H is not linear. To accommodate this, a more general definition of differential susceptibility is used

<math>\chi^{d}_{ij} = \frac{\part M_i}{\part H_j}</math>

where <math>\chi^{d}_{ij}</math> is a tensor derived from partial derivatives of components of M with respect to components of H. When the coercivity of the material parallel to an applied field is the smaller of the two, the differential susceptibility is a function of the applied field and self interactions, such as the magnetic anisotropy. When the material is not saturated, the effect will be nonlinear and dependent upon the domain wall configuration of the material.

Susceptibility in the frequency domain

When the magnetic susceptibility is studied as a function of frequency, the permeability is a complex quantity and resonances can be seen. In particular, when an ac-field is applied perpendicular to the detection direction (called the "transverse susceptibility" regardless of the frequency), the effect has a peak at the ferromagnetic resonance frequency of the material with a given static applied field. Currently, this effect is called the microwave permeability or network ferromagnetic resonance in the literature. These results are sensitive to the domain wall configuration of the material and eddy currents.

In terms of ferromagnetic resonance, the effect of an ac-field applied along the direction of the magnetization is called parallel pumping.

Examples

Magnetic susceptibility of some materials
Material Temperature <math>\chi_{mol}</math> (molar susc.) <math>\chi_{mass}</math> (mass susc.) <math>\chi_{v}</math> (volume susc.) M (molar mass) <math>\rho</math> (density)
Units (oC) (SI) (cgs) (SI) (cgs) (SI) (cgs) (10-3 kg/mol) or (g/mol) (103 kg/m3) or (g/cm3)
vacuum Any 0 0 0 0 0 0 0
water [9] 20 -1.63*10-10 -1.3*10-5 -9.05*10-9 -7.2*10-7 -9.035*10-6 -7.19*10-7 18.02 0.998
bismuth [10] 20 -3.55*10-9 -2.82*10-4 -1.70*10-8 -1.35*10-6 -1.66*10-4 -1.32*10-5 208.98 9.78
Diamond [11] r.t. -6.9*10-11 -5.5*10-6 -5.8*10-9 -4.6*10-7 -2.0*10-5 -1.6*10-6 12.01 3.513
He [12] -2.38*10-11 -1.89*10-6 -5.93*10-9 -4.72*10-7 4.0026
Xe [12] -5.7*10-10 -4.54*10-5 -4.35*10-9 -3.46*10-7 131.29
O2 [12] 4.3*10-8 3.42*10-3 2.69*10-6 2.14*10-4 16.00
Al 2.2*10-10 1.7*10-5 7.9*10-9 6.3*10-7 26.98
Ag [13] -2.38*10-10 -1.89*10-5 -2.20*10-9 -1.75*10-7 107.87

Sources of confusion in published data

There are tables of magnetic susceptibility values published on-line that seem to have been uploaded from a substandard source,[14] which itself has probably borrowed heavily from the CRC Handbook of Chemistry and Physics. Some of the data (e.g. for Al, Bi, and diamond) are apparently in cgs Molar Susceptibility units, whereas that for water is in Mass Susceptibility units (see discussion above). The susceptibility table in the CRC Handbook is known to suffer from similar errors, and even to contain sign errors. Effort should be made to trace the data in such tables to the original sources, and to double-check the proper usage of units. Use them at your own risk!

See also

Notes

  1. Magnetic properties of materials
  2. L N Mulay (1972). A Weissberger and B W Rossiter, ed. Techniques of Chemistry. 4. Wiley-Interscience: New York. pp. p.431.
  3. Magway Magnetic Susceptibility Balances
  4. J R Zimmerman, and M R Foster (1957). "Standardization of NMR high resolution spectra". J. Phys. Chem. 61: 282–289. doi:10.1021/j150549a006.
  5. Robert Engel, Donald Halpern, and Susan Bienenfeld (1973). "Determination of magnetic moments in solution by nuclear magnetic resonance spectrometry". Anal. Chem. 45: 367–369. doi:10.1021/ac60324a054.
  6. P W Kuchel, B E Chapman, W A Bubb, P E Hansen, C J Durrant, and M P Hertzberg (2003). "Magnetic susceptibility: solutions, emulsions, and cells". Concepts Magn. Reson. A 18: 56–71. doi:10.1002/cmr.a.10066.
  7. K Frei and H J Bernstein (1962). "Method for determining magnetic susceptibilities by NMR". J. Chem. Phys. 37: 1891–1892. doi:10.1063/1.1733393.
  8. R E Hoffman (2003). "Variations on the chemical shift of TMS". J. Magn. Reson. 163: 325–331. doi:10.1016/S1090-7807(03)00142-3.
  9. G P Arrighini, M Maestro, and R Moccia (1968). "Magnetic Properties of Polyatomic Molecules: Magnetic Susceptibility of H2O, NH3, CH4, H2O2". J. Chem. Phys. 49: 882–889. doi:10.1063/1.1670155.
  10. S Otake, M Momiuchi and N Matsuno (1980). "Temperature Dependence of the Magnetic Susceptibility of Bismuth". J. Phys. Soc. Jap. 49 (5): 1824–1828. doi:10.1143/JPSJ.49.1824. The tensor needs to be averaged over all orientations: <math>\chi=(1/3)\chi_{||}+(2/3)\chi_{\perp}</math> .
  11. J Heremans, C H Olk and D T Morelli (1994). "Magnetic Susceptibility of Carbon Structures". Phys. Rev. B. 49 (21): 15122–15125. doi:10.1103/PhysRevB.49.15122.
  12. 12.0 12.1 12.2 R E Glick (1961). "On the Diamagnetic Susceptibility of Gases". J. Phys. Chem. 65 (9): 1552–1555. doi:10.1021/j100905a020.
  13. C L Foiles (1976). "Comments on Magnetic Susceptibility of Silver". Phys. Rev. B. 13 (12): 5606–5609. doi:10.1103/PhysRevB.13.5606.
  14. Magnetic Properties Susceptibilities Chart from READE

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