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Abstract
This minireview is dedicated to the 85th birthday of Prof. L.V. Keldysh, from whom we have learned so much. In this paper, we study the potential and electron density depth profiles in surface accumulation layers in crystals with a large and nonlinear dielectric response such as SrTiO_{3} (STO) in the cases of planar, spherical, and cylindrical geometries. The electron gas can be created by applying an induction D_{0} to the STO surface. We describe the lattice dielectric response of STO using the Landau–Ginzburg free energy expansion and employ the Thomas–Fermi (TF) approximation for the electron gas. For the planar geometry, we arrive at the electron density profile n(x) ∝ (x + d)^{–12/7}, where d ∝ D_{0} ^{–12/7}. We extend our results to overlapping electron gases in GTO/STO/GTO heterojunctions and electron gases created by spillout from NSTO (heavily ntype doped STO) layers into STO. Generalization of our approach to a spherical donor cluster creating a big TF atom with electrons in STO brings us to the problem of supercharged nuclei. It is known that for an atom with a nuclear charge Ze where Z > 170, electrons collapse onto the nucleus, resulting in a net charge Zn < Z. Here, instead of relativistic physics, the collapse is caused by the nonlinear dielectric response. Electrons collapse into the charged spherical donor cluster with radius R when its total charge number Z exceeds the critical value Z_{c} ≈ R/a, where a is the lattice constant. The net charge eZ_{n} grows with Z until Z exceeds Z* ≈ (R/a)^{9/7}. After this point, the charge number of the compact core Z_{n} remains ≈ Z*, with the rest Z* electrons forming a sparse TF atom with it. We extend our studies of collapse to the case of long cylindrical clusters as well.
Original language  English (US) 

Pages (fromto)  456471 
Number of pages  16 
Journal  Journal of Experimental and Theoretical Physics 
Volume  122 
Issue number  3 
DOIs  
State  Published  2016 
Bibliographical note
Publisher Copyright:© 2016, Pleiades Publishing, Inc.
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MRSEC IRG2: Sustainable Nanocrystal Materials
Kortshagen, U. R., Aydil, E. S., Campbell, S. A., Francis, L. F., Haynes, C. L., Hogan, C., Mkhoyan, A., Shklovskii, B. I. & Wang, X.
9/1/98 → …
Project: Research project
