Defect types include atom vacancies, adatoms, steps, and kinks that occur most frequently at surfaces due to the finite material size causing crystal discontinuity. What all types of defects have in common, whether surface or bulk defects, is that they produce dangling bonds that have specific electron energy levels different from those of the bulk. This difference occurs because these states cannot be described with periodic Bloch waves due to the change in electron potential energy caused by the missing ion cores just outside the surface. Hence, these are localized states that require separate solutions to the Schrödinger equation so that electron energies can be properly described. The break in periodicity results in a decrease in conductivity due to defect scattering.
A simpler and more qualitative way of determining dangling bond energy levels is with Harrison diagrams.[1] [2] Metals have non-directional bonding and a small Debye length which, due to their charged nature, makes dangling bonds inconsequential if they can even be considered to exist. Semiconductors are dielectrics so electrons can feel and become trapped at defect energy states. The energy levels of these states are determined by the atoms that make up the solid. Figure 1 shows the Harisson diagram for the elemental semiconductor Si. From left to right, s-orbital and p-orbital hybridization promotes sp3 bonding which, when multiple sp3 Si-Si dimers are combined to form a solid, defines the conduction and valence bands. If a vacancy were to exist, such as those on each atom at the solid/vacuum interface, it would result in at least one broken sp3 bond which has an energy equal to that of single self hybridized Si atoms as shown in Figure 1. This energy corresponds to roughly the middle of the bandgap of Si, ~0.55eV above the valence band. Certainly this is the most ideal case whereas the situation would be different if bond passivation (see below) and surface reconstruction, for example, were to occur. Experimentally, the energies of these states can be determined using absorption spectroscopy or X-ray photoelectron spectroscopy, for example, if instrument sensitivity and/or defect density are high enough.
Compound semiconductors, such as GaAs, have dangling bond states that are nearer to the band edges (see Figure 2). As bonding becomes increasingly more ionic, these states can even act as dopants. This is the cause of the well known difficulty of GaN p-type doping where N vacancies are abundant due to its high vapor pressure resulting in high Ga dangling bond density. These states are close to the conduction band edge and therefore act as donors. When p-type acceptor dopants are introduced, they are immediately compensated for by the N vacancies. With these shallow states, their treatment is often considered as an analogue to the hydrogen atom as follows for the case of either anion or cation vacancies (hole effective mass, m*, for cation and electron m* for anion vacancies). The binding energy, Ec-Edb, is
Ec-Edb=U+KE=
| 1 | |
| 2 |
U (1)
nλ=2\pir (2)
| KE= | p2 | = |
| 2m* |
| h2n2 | =- | |
| 8m*\pi2r2 |
| U | = | |
| 2 |
| q2 | |
| 8\pi\varepsilon\varepsilonrr |
(3)
| r= | 4\pi\hbar2n2\varepsilon\varepsilonr |
| q2m* |
(4)
Ec-Edb=
| U | |
| 2 |
=
| m*q4 | |
| 8h2(\varepsilon\varepsilonr)2 |
(5)
The dangling bond energy levels are eigenvalues of wavefunctions that describe electrons in the vicinity of the defects. In the typical consideration of carrier scattering, this corresponds to the final state in Fermi's golden rule of scattering frequency:
Sk'k=
| 2\pi | |
| \hbar |
|<f|H'|i>|2\delta(Ef-Ei) (6)
The value of Sk'k is primarily determined by the interaction parameter, H'. This term is different depending on whether shallow or deep states are considered. For shallow states, H' is the perturbation term of the redefined Hamiltonian H=Ho+H', with Ho having an eigenvalue energy of Ei. The matrix for this case is [3]
<f|H'|i>\equivMk'k=
| 1 | |
| V |
\intd\bar{r}H'ei\bar{r(\bar{k}-\bar{k}')}=
| 1 | |
| V |
\sum\bar{q
\nabla2V(\bar{r})=
| -e\delta(\bar{r | |
| )}{\varepsilon |
\varepsilonr}=-\sum\bar{q
H\bar{q
| 1 | |
| \tau |
=\sum\bar{k',\bar{k}}S\bar{k'\bar{k}}=n\sum\bar{k
| 1 | |
| \tau |
=
| ne4 | |
| 2\pi\sqrt{2m*(Ec-Edb) |
\hbar2\varepsilon\varepsilonr
Determination of the extent these dangling bonds have on electrical transport can be experimentally observed fairly readily. By sweeping the voltage across a conductor (Figure 3), the resistance, and with a defined geometry, the conductivity of the sample can be determined. As mentioned before, σ = ne2τ /m*, where τ can be determined knowing n and m* from the Fermi level position and material band structure. Unfortunately, this value contains effects from other scattering mechanisms such as due to phonons. This gains usefulness when the measurement is used alongside Eq (11) where the slope of a plot of 1/τ versus n makes Ec-Edb calculable and the intercept determines 1/τ from all but defect scattering processes. This requires the assumption that phonon scattering (among other, possibly negligible processes) is independent of defect concentration.
In a similar experiment, one can just lower the temperature of the conductor (Figure 3) so that phonon density decreases to negligible allowing defect dominant resistivity. With this case, σ = ne2τ /m* can be used to directly calculate τ for defect scattering.
Surface defects can always be "passivated" with atoms to purposefully occupy the corresponding energy levels so that conduction electrons cannot scatter into these states (effectively decreasing n in Eq (10)). For example, Si passivation at the channel/oxide interface of a MOSFET with hydrogen (Figure 4) is a typical procedure to help reduce the ~1010 cm−2 defect density by up to a factor of 12[4] thereby improving mobility and, hence, switching speeds. Removal of intermediary states which would otherwise reduce tunneling barriers also decreases gate leakage current and increases gate capacitance as well as transient response. The effect is that the Si sp3 bonding becomes fully satisfied. The obvious requirement here is the ability for the semiconductor to oxidize the passivating atom or, Ec-Edb + χ > EI, with the semiconductor electron affinity χ and atom ionization energy EI.
We now consider carrier scattering with lattice deformations termed phonons. Consider the volumetric displacement such a propagating wave produces,
\DeltaV0
\DeltaV0/V0=triangledownu(r,t)
u(r,t)\proptoexp\pm(iqr-i\omegat)
\DeltaECB=
| dECB | |
| dV0 |
\DeltaV0=V0
| dECB | |
| dV0 |
| \DeltaV0 | |
| V0 |
=ZDP ⋅ triangledownu(r,t) (12)
\Delta
| Tot | |
| E | |
| CB |
=\widehat{H}int=ZDP ⋅ triangledownu(r,t)\sqrt{Nq+
| 1 | |
| 2 |
\pm
| 1 | |
| 2 |
q\perpu(r,t)
<k'|\widehat{H}int|k>=\pmiqZDPu(r,t)\sqrt{Nq+
| 1 | |
| 2 |
\pm
| 1 | |
| 2 |
<k'|
|k>
Using Fermi's golden rule, the scattering rate for low energy acoustic phonons can be approximated. The interaction matrix for these phonons is
|<k'|\widehat{H}int|k>|2
| 2 | |
| =Z | |
| DP |
| \hbar\omegaq | |
| 2V\rhoc2 |
(Nq+
| 1 | |
| 2 |
\pm
| 1 | |
| 2 |
)\deltak', (15)
| Ac | ||
| S | = | |
| k'k |
| 2\pi | |
| \hbar |
| 2 | |
| Z | |
| DP |
| \hbar\omegaq | |
| 2V\rhoc2 |
(Nq+
| 1 | |
| 2 |
\pm
| 1 | |
| 2 |
)\deltak',\delta[E(k')-E(k)\pm\hbar\omegaq] (16)
| 1 | |
| \tau |
=\sumk'
| Ac | |
| S | |
| k'k |
=\sumk
| Ac | |
| S | |
| k\pmq,k |
| = | 2\pi |
| \hbar |
| 2 | |
| Z | |
| DP |
| \hbar\omegaq | ( | |
| 2V\rhoc2 |
| kT | |
| \hbar\omegaq |
)\sumk\deltak',\delta[E(k')-E(k)\pm\hbar\omegaq]
| = | 2\pi |
| \hbar |
| 2 | |
| Z | |
| DP |
| kT | |
| 2V\rhoc2 |
V x g(E)
| = | \sqrt2 |
| \pi |
| |||||||||||||||||
| \rho\hbar4c2 |
\sqrt{E-ECB
Typically, phonons in the optical branches of vibrational dispersion relationships have energies on the order of or greater than kT and, therefore, the approximations ħω<
| 1 | |
| \tau |
=\sumk'
| Op | ||
| S | = | |
| k'k |
| 2\pi | |
| \hbar |
| 2 | |
| Z | |
| DP |
| \hbar\omega | |
| 2V\rhoc2 |
(Nq+
| 1 | |
| 2 |
\pm
| 1 | |
| 2 |
)\sumk'\deltak',\delta[E(k')-E(k)\pm\hbar\omega]
| 2 | |
| =Z | |
| DP |
| \hbar\omega | |
| 8\pi2\hbar\rhoc2 |
(Nq+
| 1 | |
| 2 |
\pm
| 1 | |
| 2 |
)g(E\pm\hbar\omega) (18)