Nuclear reaction analysis

Nuclear reaction analysis (NRA) is a nuclear method in materials science to obtain concentration vs. depth distributions for certain target chemical elements in a solid thin film.

If irradiated with select projectile nuclei at kinetic energies E_kin these target elements can undergo a nuclear reaction under resonance conditions for a sharply defined resonance energy. The reaction product is usually a nucleus in an excited state which immediately decays, emitting ionizing radiation.

To obtain depth information the initial kinetic energy of the projectile nucleus (which has to exceed the resonance energy) and its stopping power (energy loss per distance traveled) in the sample has to be known. To contribute to the nuclear reaction the projectile nuclei have to slow down in the sample to reach the resonance energy. Thus each initial kinetic energy corresponds to a depth in the sample where the reaction occurs (the higher the energy, the deeper the reaction).

For example, a commonly used reaction to profile hydrogen with an energetic ¹⁵N ion beam is

¹⁵N + ¹H → ¹²C + α + γ (4.965 MeV)

with a resonance when the incident ¹⁵N ion has an energy of 6.385 MeV. Since the ion loses energy in the material the ion beam must have an energy higher than the resonance energy to excite it (that is, to get gamma rays emitted).

This reaction is usually written "¹H(¹⁵N,αγ)¹²C". It is inelastic because the Q-value is not zero (in this case it is 4.965 MeV). Rutherford backscattering (RBS) reactions are elastic (Q = 0), and the interaction (scattering) cross-section σ given by the famous formula derived by Lord Rutherford in 1911. But non-Rutherford cross-sections (so-called EBS, elastic backscattering spectrometry) can also be resonant: for example, the ¹⁶O(α,α)¹⁶O reaction has a strong and very useful resonance at 3038.1 ± 1.3 keV.^[1]

In the ¹H(¹⁵N,αγ)¹²C reaction (or indeed the ¹⁵N(p,αγ)¹²C inverse reaction), the energetic emitted γ ray is characteristic of the reaction and the number that are detected at any incident energy is proportional to the concentration at the respective depth of hydrogen in the sample. The H concentration profile is then obtained by scanning the ¹⁵N incident beam energy.

Hydrogen is an element inaccessible to Rutherford backscattering spectrometry since nothing can backscatter from H (since all atoms are heavier than hydrogen!). But it is often analysed by elastic recoil detection.

NRA can also be used non-resonantly (of course, RBS is non-resonant). For example, deuterium can easily be profiled with a ³He beam without changing the incident energy by using the

³He + D = α + p + 18.353 MeV

reaction, usually written ²H(³He,p)α. The energy of the fast proton detected depends on the depth of the deuterium atom in the sample.^[2]

References

↑ Colaux, J. L.; Terwagne, G.; Jeynes, C. (2015). "On the traceably accurate voltage calibration of electrostatic accelerators". Nuclear Instruments & Methods B. 349: 173–183. doi:10.1016/j.nimb.2015.02.048.
↑ Payne, R. S.; Clough, A. S.; Murphy, P.; Mills, P. J. (1989). "Use of the d(3He,p)4He reaction to study polymer diffusion in polymer melts". Nuclear Instruments & Methods B. 42: 130–134. doi:10.1016/0168-583X(89)90018-9.

External links

Details of many known reactions are hosted by the IAEA at http://www-nds.iaea.org/ibandl/.

The energy released in nuclear reactions (the "Q value") can easily be calculated (from E=mc²): see http://nucleardata.nuclear.lu.se/database/masses/.

NRA at JSI Microanalytical center in Ljubljana, Slovenia

This article is issued from Wikipedia - version of the 9/24/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.