Themes > Science > Physics > Nuclear Physics > Basic properties of the nucleus > Sizes

Since the force between nucleons is short range, the size of a nucleus is reasonably well-defined. Experiment shows that nuclei are roughly spherical with a radius

displaymath1527

where tex2html_wrap_inline1533 fm.

Thus, the density of a nucleus is approximately constant, and the volume of a nucleus is proportional to the number of nucleons contained in it.

The radius parameter tex2html_wrap_inline1535 can vary with the method used to measure it and is generally in the region 1.1 - 1.4 fm (with larger values corresponding to the electromagnetic radius).

Rutherford interpreted the initial scattering experiments that showed the existence of a massive, positively charged, compact nucleus in the atom. The Rutherford cross-section describes the scattering resulting from electrostatic forces:

displaymath1537

This was derived by classical considerations and associated a scattering angle with a unique impact parameter, in turn associated with a unique closest approach to the nucleus.

The potential due to the nuclear force is strongly attractive and short range. Adding it to the Coulomb potential results in deviations from Rutherford scattering at small distances of approach (large scattering angles). This leads to an approximate size for the nucleus.

Other methods exist for determining this. An atom can capture a tex2html_wrap_inline1539 meson ( tex2html_wrap_inline1541 Mev) which behaves as a heavy electron. X-rays are emitted as it cascades down to the 1s atomic orbital. The energy can be predicted by the usual Bohr formula, but in heavy atoms there are perturbations as the Bohr radius approaches the nuclear size.

Today, electron scattering is usually used to measure nuclear size. Energetic electrons ( tex2html_wrap_inline1545 MeV) are usually used for this. These are highly relativistic; the electron invariant mass tex2html_wrap_inline1547 is 0.511 MeV, so the Lorentz factor tex2html_wrap_inline1549 . The momentum p of the electron is related to its de Broglie wavelength tex2html_wrap_inline1553 :

displaymath1528

Hence

displaymath1529

Since tex2html_wrap_inline1555 MeV and tex2html_wrap_inline1557 MeV, resolutions of 1 fm or better require tex2html_wrap_inline1559 .

From many such electron scattering measurements, the nuclear density (nucleons per unit volume) can be parameterised as

displaymath1561

where the surface diffusivity tex2html_wrap_inline1563 fm and the radius parameter tex2html_wrap_inline1565 fm. The central density tex2html_wrap_inline1567

Note that this indicates that

  • The nuclear radius is proportional to tex2html_wrap_inline1569 , or the nuclear volume is proportional to A.
  • In other words, the density (at the centre) of all nuclei is (approximately) the same.
  • All nuclei have a surface region of decreasing density, about 2.5 fm thick.


Information provided by: http://www.phy.uct.ac.za