A high-field domain is a band of elevated field orthogonal to the equi-current lines, and seen in photoconductive CdS and monochromatic light at the band edge as dark band was discovered by Böer,[1] using the Franz–Keldysh effect. Such domains must appear[1] whenever the conductivity decreases stronger than linearly. This can be caused by the field dependence of the carrier density, as observed in copper-doped CdS caused by Frenkel Poole excitation of holes, causing faster electron recombination, known as field quenching.[2] These high-field domains, now referred to as Böer domains, or by field dependence of the mobility,[3] caused by excitation of electrons into higher conduction bands with lower mobility as observed in GaAs, called the Gunn effect.[4][5] The high-field domains can be identified by periodical field oscillations between high (the domain) and low values, as shown in Fig. 1.[6]

Fig. 1 Periodic current oscillation in a Gunn diode.[6]

Many other crystals show such domains by typical current oscillations. The high-field domains in copper doped CdS can be easily observed by the Franz–Keldysh effect as stationary, adjacent to the cathode[7][8] or moving.[9][10] These are analyzed as another example below.

Theory: Stationary high-field domains can be analyzed from the transport- and Poisson equations:

  and  

The projection of any solution curves into an arbitrary nF plane can be filled with direction arrows at any point of this plane. Two auxiliary curves for which dn/dx = 0, called n2(F) and dF/dx = 0 called n1(F) divide this plane into four quadrants with the same type of directions. This is shown in Fig. 2(left) in a double logarithmic representation.[7] Any solution of an n-type semiconductor with blocking cathode must start at the boundary density nc that is below the density in the bulk, and approaches the singular point at which dn/dx = dF/dx = 0, that is in the bulk where both n(x) and F(x) are constant. The solution curve represents a Schottky-blocking contact as shown in Fig. 2(B), curve (a).[8]

(left)
(B)
Fig. 2 (left) Field of direction (B) Schottky solution, curve (a). With increased bias n2(F) shifts steadily up and to the right, and may start to cross the declining branch of n1(F), caused by field-quenching; this creates a second singular point (II). When this point coincides with the boundary density nc, a high-field domain solution (b) develops.[8]

When n(x) decreases at higher fields due to field-quenching cause by Poole-Frenkel excitation of holes from Coulomb attractive hole traps, that consequently enhances electron recombination through recombination centers, and thereby deforms the n1(x) curve at higher fields as shown in Fig. 2(B). When the bias is increased the current curve n2(x) is shifted upwards and to the right, and when it crosses n1(x) again, it produces a second singular point II. With further increased bias this singular point II reaches the value of the boundary density nc, and the solution curve changes from a monotonic increasing Schottky-solution, to a high-field domain, curve (b): that remains constant near the cathode, and then changes within a few Debye lengths to approach the constant value in the bulk, near the singular point I. The width of the domain increases with bias (Fig. 3a), while the current remains constant (Fig. 3c).[8] The domain is visible as dark part in the transmission picture through the CdS platelett, extending from the cathode as shown in Fig. 3a. The field in the domain can be obtained from the slope of the domain that increases with bias (Fig. 3b).[8]

Fig. 3 (a) High-Field Domain [dark region] shown as transmission near the band edge through the CdS platelett (b) Domain width vs. bias (c) current voltage characteristic[8] showing the constant branch as soon as the domain appears.

When, with further increased bias the domain fills the entire sample, then it flips to an anode adjacent high-field domain (Fig. 4b). The field at the cathode is now much higher than for the cathode adjacent domain (Fig. 4b and c), while the current still remains essentially constant (Fig. 4c).[7]

(c) domain width as function of bias (A) for cathode- (B) for anode-adjacent domain. (d) current-voltage characteristic showing saturation through the transition point at 2 kV bias
(b) Transmission picture of a CdS crystal with Franz–Keldysh effect darkening, 0-1,700 V bias cathode adjacent, 2,200 - 3,200V anode adjacent domain
(c)
Fig. 4 (a) Transmission picture of a CdS crystal with Franz–Keldysh effect darkening, that shows from 0 to -1,700 V bias the cathode adjacent domain, and from 2,200 to -3,200V the anode adjacent domain; the boundary of the domain is identified by a couple of arrows: (c) the domain width as function of bias (A) for cathode- (B) for anode-adjacent domain. (a) current-voltage characteristic (b) showing current saturation through the transition point at 2 kV bias.[7]

High-field domains to determine the work function of blocking contacts

Since the high field domain starts at the electron density given by the work-function at the cathode and pulls the Schottky barrier open to a constant field in the domain, this work function can be determined precisely, and it can be used as a tool to determine the changes of the work function, as it varies depending on external parameters. As an example, it can be shown that it depends on the optical excitation in a photoconductor (See Fig. 5).[11]

Fig. 5 (a) Work function as function of the light intensity for different cathode metals.[11]

High-field domains as tools to measure the electron density in the field quenched branch and of the electron mobility as a function of the temperature

Fig. 6 Shadow band within a photoconductor changes conductivity and field within the Band and thereby the boundary density at the right side of the band, i.e., it acts as a pseudo-cathode[8] with the high-field domain starting at the anode-side of the pseudo-cathode.

The high-field domain is determined by the boundary density at the cathode and the field within the domain. A shadow band in front of the cathode acts as a pseudo-cathode, as it reduces the electron density within the shadow (Fig. 6).[8] This can be used as an experimental tool to change the boundary density as a function of the light intensity within the shadow.

This permits to measure directly the electron density in the field-quenched range, using different pseudo-electron densities, causing a shift of the singular point, and measuring the domain field.[8]

The electron Hall mobility can be measured by placing the CdS platelett in a magnet and applying a bias sufficient to create a high-field domain. When the domain is extended to include the Hall electrodes one can determine the Hall mobility within the domain. Different fields in the high-field domain are achieved by using different samples or different cathode metals.[12]

Stationary domains to explain efficiency improvement of CdTe solar cells with a thin CdS cover layer

The application of a 200Å thick copper doped layer of CdS on top of a typically 2 μm thick CdTe solar cell, increases the open-circuit voltage substantially, so that it can reach the theoretical limit of the band gap of the CdTe-emitter when extrapolated to 0 K. This improvement can be explained by limiting the field in the CdS side of the junction when it reaches the critical value for a high-field domain to appear and thereby limits the maximum junction field to the domain field of typical 50 kV/cm.[13] This field is below a field in which electron leaking from the CdS into CdTe occurs, resulting in an increase of the open-circuit voltage and thereby an increase of the solar cell conversion efficiency.[14]

Moving high-field domains in copper-doped CdS with a small circular cathode

The domains started from the cathode, separates and, with increasing bias increases its radius. When the anode is reached the ring disappeared and a new domain grows from the cathode. The process repeated itself with a period of 10 sec (Fig. 7).[1][15]

Fig. 7: Ring of a high-field domain, made visible using the Franz–Keldysh effect, circling the cathode and expanding in time 3 sec between (a), (b), and (c).[15]

Such undeformed moving domains in crystals with slit electrodes are bands parallel to the electrodes, and seen by the oscillating field, when plotted in a x,F,t diagram give the optical impression of bifurcation (Fig. 8).[6]

Fig. 8 Calculated high-field domains in Ge with the field as function of the time in a three-dimensional rendering.[6]

Such moving high-field domains are measured in p-Ge with (a) local voltage (b) field- and (c) carrier density oscillation (Fig. 9).[16]

Fig. 9 Measured High-Field Domain in Ge (a) local voltage (b) local field (c) Electron Density, all as function of the distance between the two electrodes. In all figures the time is the family parameter and the scale each graph of the figure is identified by a bar at the lower left.[16]

Undeformed moving high-field domains and domains with deformation (Chaos) are observed in many other crystals,[17] and also in nanocrystals[18] or superlatices.[19] However, because of the small size they can only be analyzed by the changing shape of the current-voltage characteristics.

Böer domains

The high-field domains were renamed Böer domains at the 50th anniversary of their discovery.[20]

The Benefits of the High-Field Domains

Copper-doped photoconductive CdS shows high-field domains when at sufficient bias and with blocking contacts these domains remain attached to the contacts. The field within the domain is constant and the current is by drift only. With increased bias the domain width increases. When it reaches both electrodes the entire crystal becomes space-charge free (this is one more example at which an interaction vanishes: for the interaction of electrons with phonons, superconductivity results; from the interaction of photons with phonons, lasers can be produced). This gives the opportunity to measure the spectral distribution of defect levels free of interaction of the broadening electric field surrounding the defects. A first example is shown by the extremely sharp quenching spectrum of a CdS crystal that has been inverted to become p-type with a high-field-domain (Fig. 10)

Fig. 10 Electron-photo quenching signal (shown in red) in a p-type ultra-pure CdS crystal. The insert show the spectral distribution of the monochromator used that has no anomalies in the range of the signal.[21]

Another benefit of the high-field domain is the direct connection of any p-type emitter through a copper-doped thin CdS layer directly to an electron-blocking electrode through which the holes are extracted, and the open-circuit voltage is increased to approach the theoretical limit of the band gap or the emitter at 0K. Because in the CdS the hole current is now carried by drift only, we can finally draw the band model of a typical solar cell. e.g. the CdS/CdTe cell as given in Fig. 11. For the first time we can replace the estimate of the band connection of abrupt hetero-junctions from the difference of electron affinities by calculating it from the continuity of the majority carrier current, with the only small discontinuity left by the difference of the effective masses of the carriers at the different carrier bands.

Fig. 11 Band model of the CdS/CdTe solar cell in operating condition at AM1.[22]

References

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  1. ^ a b c Karl W. Böer, Z. Physik 155, 184 (1959)
  2. ^ Karl W. Böer and G. A. Dussel Phys. Rev. 154, 291 (1967)
  3. ^ Karl W. Böer Monatsber. d. Deutsch Akadem. d. Wissensch. 1, 325 (1959)
  4. ^ J.B.Gunn Solid State Commun. 1, 88 (1963)
  5. ^ H. Kroemer, Proceedings IEEE 52, 1230 (1961)
  6. ^ a b c d Cantapediera, I.R., et al. Phys. Rev. B48, 12278 (1993)
  7. ^ a b c d Karl W. Böer and P. Voss, Phys. Rev. 171, 899 (1968)
  8. ^ a b c d e f g h i Karl W. Böer and P. Voss, phys. status solidi 28, 355 (1968)
  9. ^ E. Schoell, Non-equilibrium Phase Transitions in Semiconductors, Springer, Berlin (1978)
  10. ^ M.P. Shaw, V.V. Mitin, and H.L. Grubin The Physics of Instabilities in Solid State Electerronic Devices Plenum Press New York (1987)
  11. ^ a b R. J. Stirn, K. W. Böer, and G. A. Dussel, Phys. Rev. B 7.4, 1443 (1973)
  12. ^ K. W. Böer and K. Bogus, Phys. Rev. 186, 793 (1968)
  13. ^ K. W. Böer, H. J. Hänsch and U Kümmel, Z. für Physik 155, 170 (1959)
  14. ^ Karl W.Böer, J. Appl.Phys. 107 (2010), 023701
  15. ^ a b K.W. Böer, Visualization of field and current inhomogeneities, Springer Verlag (2011)
  16. ^ a b Kahn, A. M. et al., Phys. Rev. B 43, 9742 (1991)
  17. ^ Eckehard Schoell, Non-linear SpatioTemporal Dynamics and Chaos in Semiconductors Cambridge University Press, (2001)
  18. ^ K.N. Akkeseev et al. Phys. Rev. B 52,7849 (1995)
  19. ^ L.L. Bonilla et al. Solid State E 140,161 (1996).
  20. ^ Klaus Thiessen, Phys. stat. sol. (2011) doi:10.1002/pssb.20146605
  21. ^ Böer, K. W. (2015), The importance of gold-electrode-adjacent stationary high-field Böer domains for the photoconductivity of CdS. Ann. Phys., 527: 378–395. doi:10.1002/andp.201500115
  22. ^ Böer, K. W., High-field domains in CdS adjacent to a junction of p-type solar cells. J. Appl. Phys. 119, 085703 (2016); https://dx.doi.org/10.1063/1.4942358