Haynes–Shockley experiment explained

In semiconductor physics, the Haynes–Shockley experiment was an experiment that demonstrated that diffusion of minority carriers in a semiconductor could result in a current. The experiment was reported in a short paper by Haynes and Shockley in 1948,[1] with a more detailed version published by Shockley, Pearson, and Haynes in 1949.[2] [3] The experiment can be used to measure carrier mobility, carrier lifetime, and diffusion coefficient.

In the experiment, a piece of semiconductor gets a pulse of holes, for example, as induced by voltage or a short laser pulse.

Equations

To see the effect, we consider a n-type semiconductor with the length d. We are interested in determining the mobility of the carriers, diffusion constant and relaxation time. In the following, we reduce the problem to one dimension.

The equations for electron and hole currents are:

je=+\munnE+Dn

\partialn
\partialx

jp=+\muppE-Dp

\partialp
\partialx

where the js are the current densities of electrons (e) and holes (p), the μs the charge carrier mobilities, E is the electric field, n and p the number densities of charge carriers, the Ds are diffusion coefficients, and x is position. The first term of the equations is the drift current, and the second term is the diffusion current.

Derivation

We consider the continuity equation:

\partialn=
\partialt
-(n-n0)+
\taun
\partialje
\partialx
\partialp=
\partialt
-(p-p0)-
\taup
\partialjp
\partialx
Subscript 0s indicate equilibrium concentrations. The electrons and the holes recombine with the carrier lifetime τ.

We define

p1=p-p0,n1=n-n0

so the upper equations can be rewritten as:

\partialp1
\partialt

=Dp

\partial2p1
\partialx2

-\mupp

\partialE
\partialx

- \mupE

\partialp1-
\partialx
p1
\taup
\partialn1
\partialt

=Dn

\partial2n1
\partialx2

+\munn

\partialE
\partialx

+ \munE

\partialn1-
\partialx
n1
\taun

In a simple approximation, we can consider the electric field to be constant between the left and right electrodes and neglect ∂E/∂x. However, as electrons and holes diffuse at different speeds, the material has a local electric charge, inducing an inhomogeneous electric field which can be calculated with Gauss's law:

\partialE
\partialx

=

\rho=
\epsilon\epsilon0
e0((p-p0)-(n-n0))
\epsilon\epsilon0

=

e0(p1-n1)
\epsilon\epsilon0

where ε is permittivity, ε0 the permittivity of free space, ρ is charge density, and e0 elementary charge.

Next, change variables by the substitutions:

p1=nmean+\delta,n1=nmean-\delta,

and suppose δ to be much smaller than

nmean

. The two initial equations write:
\partialnmean
\partialt

=Dp

\partial2nmean
\partialx2

-\mupp

\partialE
\partialx

- \mupE

\partialnmean-
\partialx
nmean
\taup
\partialnmean
\partialt

=Dn

\partial2nmean
\partialx2

+\munn

\partialE
\partialx

+ \munE

\partialnmean-
\partialx
nmean
\taun

\mu=e\betaD

, where β is the inverse of the product of temperature and the Boltzmann constant, these two equations can be combined:
\partialnmean
\partialt

=D*

\partial2nmean
\partialx2

- \mu*E

\partialnmean-
\partialx
nmean
\tau*

,

where for D*, μ* and τ* holds:

*=DnDp(n+p)
pDp+nDn
D
,
*=\mun\mup(n-p)
p\mup+n\mun
\mu
and
1=
\tau*
p\mup\taup+n\mun\taun
\taup\taun(p\mup+n\mun)

.

Considering n >> p or p → 0 (that is a fair approximation for a semiconductor with only few holes injected), we see that D* → Dp, μ* → μp and 1/τ* → 1/τp. The semiconductor behaves as if there were only holes traveling in it.

The final equation for the carriers is:

nmean(x,t)=A

1
\sqrt{4\piD*t
} e^ e^

This can be interpreted as a Dirac delta function that is created immediately after the pulse. Holes then start to travel towards the electrode where we detect them. The signal then is Gaussian curve shaped.

Parameters μ, D and τ can be obtained from the shape of the signal.

*=d
Et0
\mu

D*=(\mu*E)2

(\deltat)2
16ln(2)t0

where d is the distance drifted in time t0, and δt the pulse width.

See also

External links

Notes and References

  1. Haynes . J. . Shockley . W. . 10.1103/PhysRev.75.691 . Investigation of Hole Injection in Transistor Action . Physical Review . 75 . 4 . 691 . 1949 . 1949PhRv...75..691H .
  2. Bell System Technical Journal . Hole injection in germanium – Quantitative studies and filamentary transistors . Shockley, W. and Pearson, G. L., and Haynes, J. R. . 28 . 344–366 . 1949 . 3 . 10.1002/j.1538-7305.1949.tb03641.x .
  3. Book: Electronic concepts: an introduction . Jerrold H. Krenz . Cambridge University Press . 2000 . 978-0-521-66282-6 . 137 .