Litcius/Paper detail

Study of the ionization efficiency for nuclear recoils in pure crystals

Youssef Sarkis, A. A. Aguilar-Arevalo, Juan Carlos D’Olivo

2020Physical review. D/Physical review. D.26 citationsDOIOpen Access PDF

Abstract

We study the basic integral equation in Lindhard's theory describing the energy given to atomic motion by nuclear recoils in a pure material when the atomic binding energy is taken into account. The numerical solution, which depends only on the slope of the velocity-proportional electronic stopping power and the binding energy, leads to an estimation of the ionization efficiency which is in good agreement with the available experimental measurements for Si and Ge. In this model, the quenching factor for nuclear recoils features a cutoff at an energy equal to twice the assumed binding energy. We argue that the model is a reasonable approximation for Ge even for energies close to the cutoff, while for Si is valid up to recoil energies greater than $\ensuremath{\sim}500\text{ }\text{ }\mathrm{eV}$.

Topics & Concepts

CutoffBinding energyIonizationStopping powerPhysicsRecoilAtomic physicsQuenching (fluorescence)Energy (signal processing)Atomic numberNuclear physicsIonQuantum mechanicsFluorescenceGraphene research and applicationsElectron and X-Ray Spectroscopy TechniquesParticle Detector Development and Performance