Demonstration of Properties of Diamagnetic and Paramagnetic Substances

Experiment number : 1953

  • Goal of experiment

    This experiment shows the behaviour of a diamagnetic and a paramagnetic substance in an outer magnetic field.

  • Theory

    According to their magnetic properties, there are three basic kinds of substances: diamagnetic, paramagnetic and ferromagnetic. Magnetic properties depend on the structure of the electron cloud of the atom and on the structure of atoms in the substance. Paramagnetic and ferromagnetic substances consist of the same kind of atoms, but they are arranged differently. We can characterise magnetic properties of a substance with a so called relative permeability \(\mu_\mathrm{r}\) of the given material. Because the relative permeability of diamagnetic and paramagnetic substances differs only very slightly from 1, often a so called magnetic susceptibility \(\chi_\mathrm{m}\) can be found as the difference between magnetic permeability and 1:

    \[\mu_\mathrm{r}=1+\chi_\mathrm{m}\]

    Relative permeability and magnetic susceptibility are dimensionless quantities.

    Diamagnetic substances have relative permeability slightly smaller than one (that is, their susceptibility is negative), which means they slightly weaken surrounding magnetic field. If we put a magnet close to a diamagnetic substance, it will be slightly repelled. Diamagnetic substances are for example water, bismuth, graphite, copper or mercury.

    Paramagnetic substances have relative permeability slightly greater than one, which means they slightly strengthen the outer magnetic field. If we put a magnet close to a paramagnetic substance, it will be slightly attracted. Paramagnetic substances are for example copper sulphate, aluminium, platinum, chrome and others.


    We can use scales to measure attractive or repulsive forces between the magnet and the metal sample. The change of deflection on the scales translates to an attractive or a repulsive force.

  • Tools

    • neodymium magnet
    • scales sensitive to at least 0.01 g
    • sample of bismuth
    • sample of chrome or another paramagnetic material
    • nonmagnetic stand (plastic cup on Fig. 1)

    Fig. 1: Equipment
  • Metals used in this experiment

    A suitable diamagnetic material is bismuth - a silver-grey metal available in small chunks or little needles (Fig. 2). Magnetic susceptibility of bismuth is −170·10-6.

    Fig. 2: Sample of bismuth

    "Reconstructive chirurgical splint" (Fig 3) was chosen for the paramagnetic material. It is made out of non-ferromagnetic stainless steel and paramagnetic chrome. Chrome alone can be used as well. Magnetic susceptibility of chrome is +320·10-6.

    Fig. 3: Chrom chirurgical splint
  • Procedure

    1. We try how high above the scales we must put the magnet so it does not affect the plate on the scales. Then we put a sufficiently high stand on the scales (so that a magnet lying on it does not affect the scales, usually about 25 cm is enough).
    2. We place our sample of bismuth on the stand and reset the scales.
    3. We near the neodymium magnet from above and watch the display of the scales
    4. We repeat points 2 and 3 with our paramagnetic sample (a piece of chrome).
  • Sample result

    A possible execution of the experiment can be seen in the video below:

  • Technical notes

    • If the scales cannot display negative values, we do not reset them at the beginning of our measurement, but we measure the difference of values at the beginning and after nearing the magnet.
    • The force measured is very small, in order of single mN for samples the size of few tens of grams. That is why we need to use scales sensitive to at least 0.01 g, or better 0.001 g.
    • Because the force between the magnet and the sample is very small, it is advised to use a strong magnet and put it very close to the sample, but so that it does not touch the sample.
Type of experiment: Qualitative
Difficulty level: From Upper secondary level
Necessary tools: Specific tools and equipment required
Preparation time: 3–10 minutes
Duration of experiment: Under 3 minutes
Experiment is video recorded
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