Modeling of an interface between two solids Ashcroft and Mermin Ch. 18 Sze Ch Review Chapter by Tersoff
The Work Function of a Metal A.If there are no interface dipoles Negative value of E f reflects the attractive force of the positive ions
The Work Function of a Metal B.Surface dipole – additional component due to dipole field
Evaluation of a Single Monolayer Maximum Dipole Energy in GaAs a
Two metals Same chemical potential after contact is established – if electrons are free, by the definition of chemical potential.
Measurement of the Contact Potential by the Kelvin Probe Method A
Ideal Insulator ε=1 No charge redistribution due to an electric field – no dipole at the interface. Afinity rule exact
The Neutrality Level Concept Surface neutrality level – Bardeen 1947 Cowley and Sze 1965 Bulk neutrality layer - Tejedor and Flores 1977, Tersoff 1984
Cowley and Sze’s analysis E0E0
E0E0
Silicon Barrier with Metals
Other Semiconductors
Summary
The bulk neutrality level Epitaxial interfaces are almost defect free Yet, the affinity rule is not obeyed The bulk neutrality level plays a role analogous to the Fermi level in metals No Charge transfer if both neutrality layers coincide
The bulk neutrality level -Tersoff
limits metal Ideal insulator
Evaluation of α – consider bulk material- Tersoff’s thought experiment ECEC EVEV
freeze all charges - introduce dipole – ECEC EVEV ΔE 0
relax charges (not the fixed dipole) - fixed dipole is screened like in a plate capacitor ECEC EVEV ΔE =ΔE 0 /ε
Compare to previous definitions ECEC EVEV ΔE =ΔE 0 /ε hence
Conclusion: in semiconductors neutrality levels are almost aligned
Microscopic origin of the dipole (the homogenous material thought experiment) States induced by tunneling – empty states are positively charged, filled states negatively charged.
The sum rule – the integrated density of states at any location is a constant EfEf A fraction of the states that tunneled from the right originate from the conduction band – DOS below Fermi level increased A fraction of the states that tunneled from the left originate from the valence band - DOS below Fermi level decreased
A heterojunction aligned at the - neutrality levels - total DOS bellow Fermi level remains unchanged EfEf A fraction of the states that tunneled from the left originate from the valence band A fraction of the states that tunneled from the left originate from the conduction band
Microscopic or macroscopic α ? Tersoff – but charge is located at bond distance Tejedor and Flores calculate
Calculation of neutrality level at 1D (Tersoff) Eb is a natural division between the valence and conduction bands
Calculation of neutrality level at 3D- Tersoff
Calculation of the neutrality level by Tersoff and comparison with barrier height
2011 comments by Tersoff A. I can't really say that my ideas have evolved much since then, since I moved on to other things. I don't remember what is in that chapter, but strictly speaking, both the interfacial properties and the bulk properties do matter. A metal-metal interface is the ideal example where bulk properties totally screen out interfacial effects. The smaller the dielectric constant, the more the interfacial details matter. The interface could also dominate if it is too non-bulk-like, e.g. non-stochiometric, or high density of defects. Q. I am accustomed to the way of thinking which relates band alignment between semiconductors as well as Schottky barriers to the properties of the interface. Thinking of bulk properties in this context is unusual to me, and I was intrigued to find out how your ideas have evolved over the years.
2011 comments by Tersoff Just from my very out-of-date memories, I don't remember silicides behaving any differently than other metals -- i.e. Schottky barriers roughly consistent with calculated neutrality levels, with small shifts reflecting the different metal workfunctions. There is much more opportunity for complications at III-V interfaces, especially for polar orientations like 001 and 111, because the chemistry might lead to a dipole at the interface, just as for polar surfaces. It's intriguing that such effects usually don't seem important -- different metals on (001) surfaces of III-V's show the trends expected from simple bulk arguments. This is convenient, but it isn't really understood.