Abstract
The direction and impact parameter dependence of electronic stopping power, along with its velocity threshold behavior, is investigated in a prototypical small band gap semiconductor. We calculate the electronic stopping power of H in Ge, a semiconductor with relatively low packing density, using time-evolving time-dependent density-functional theory. The calculations are carried out in channeling conditions with different impact parameters and in different crystal directions, for projectile velocities ranging from 0.05 to 0.6 atomic units. The satisfactory comparison with available experiments supports the results and conclusions beyond experimental reach. The calculated electronic stopping power is found to be different in different crystal directions; however, strong impact parameter dependence is observed only in one of these directions. The distinct velocity threshold observed in experiments is well reproduced, and its non-trivial relation with the band gap follows a perturbation theory argument surprisingly well. This simple model is also successful in explaining why different density functionals give the same threshold even with substantially different band gaps.
Highlights
The study of fast-moving charged particles shooting through solid materials started with Rutherford’s famous experiment of showering a gold foil with α particles to substantiate the nuclear model of the atom [1]
In an experiment with a polycrystalline sample the projectile gets channeled along different crystal directions
We have systematically studied the different aspects of the electronic stopping power (ESP) of H in bulk Ge, a representative narrow-bandgap semiconductor for which good experimental results are available
Summary
The study of fast-moving charged particles shooting through solid materials started with Rutherford’s famous experiment of showering a gold foil with α particles to substantiate the nuclear model of the atom [1]. Such fastmoving particles strongly perturb the target material. The perturbed state of the medium relaxes to either its original state or a new state with structural defects, depending on the nature of the interaction The study of such defects, generally referred to as “radiation damage,” is of great interest from the point of view of applications ranging from nuclear engineering [2] to biological soft matter for medical applications [3] and materials engineering for space electronics [4,5]. It is traditional to differentiate between these two distinct dissipation channels; the loss of energy to electronic excitations is known as the electronic stopping power Se, and the loss of energy to the nuclear motion is known as the nuclear stopping power Sn
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