SURFACE STATE AND INTERFACE EFFECTS ON CAPACITANCE-VOLTAGE RELATIONSHIP IN SCHOTTKY BARRIERS

In the presence of an interfacial layer and semiconductor surface states, a Schottky barrier height φb decreases with increasing electric field E at the surface of the semiconductor. If the semiconductor doping concentration Nd is uniform throughout the depletion region and if [(qNd/ε) (dφb/dE)-E] [(d2φ b/dE2) (dE/dV)] ≪1, where V is the applied voltage and ε is the semiconductor permittivity, the slope of the (capacitance) -2 vs voltage relationship is constant and can be interpreted to give Nd. The voltage intercept of the relationship yields an apparent barrier height φa related to the true barrier φb by φa=φb-E (dφb/dE) + (qN d/2ε) (dφb/dE)2, where q is the electron charge. From the measured variation of φa with N d and one absolute measure of φb at one value of Nd, φb(E), and dφb(E)/dE may be deduced. From dφb(E)/dE the surface state density as a function of energy in the bandgap and the minimum value of interface thickness divided by relative interface permittivity can be obtained. Using the data of Archer and Atalla for vacuum cleaved Au-Si diodes to illustrate our method, the surface state density is found to peak at a value of ∼2×1014 cm-2·eV-1 at about 0.83 below the conduction band and the minimum value of interface thickness divided by relative dielectric constant is found to be of the order of 5 Å. Criteria are given which show how Schottky diode capacitance-voltage data may be further used, in conjunction with photoelectric barrier measurements, to detect the presence of deep lying impurities or the penetration of surface state charge into the body of the semiconductor. © 1969 The American Institute of Physics.