DETERMINATION OF ACCEPTOR AND DONOR DOPANT CONCENTRATIONS

摘要

The concentrations of three acceptor and donor dopants of a semiconductor sample are determined by solving a system of three equations. A first equation is obtained by measuring the free charge carrier concentration of the sample at low temperature, and in then confronting these measurements with a mathematical model suitable for these temperatures. A second equation is obtained by measuring a mobility of the majority charge carriers and comparing it with its mathematical expression. A third equation between the dopant concentrations is established knowing the activation energy of the shallower majority dopant in the bandgap of the semiconductor material. When the activation energy of this majority dopant is equal to its maximum value, this third equation is derived from the electro-neutrality of the silicon at ambient temperature. When, the activation energy differs from its maximum value, the concentration of this majority dopant can be deduced directly from its activation energy.

主权项

1. A method for determining dopant concentrations in a semiconductor material sample, the sample comprising three dopants one of which is of majority type and one of minority type, two dopants of the same type having different activation energies, the method comprising the following steps:
measuring the free charge carrier concentration in the sample at first and second temperatures for which the dopant of majority type having the weakest activation energy is in an ionization state; confronting the measurements of the free charge carrier concentration with a mathematical model of the free charge carrier concentration versus the temperature in the ionization state; determining the value of the activation energy of the dopant of majority type having the weakest activation energy and establishing a first equation between the three dopant concentrations from parameters of the mathematical model; determining an experimental value of the mobility of the majority charge carriers in the sample; comparing the experimental value of the mobility of the majority charge carriers with a mathematical expression of the mobility so as to establish a second equation between the dopant concentrations; comparing the value of the activation energy of the dopant of majority type having the weakest activation energy with a threshold value of the activation energy for said dopant; determining the three dopant concentrations from said activation energy value, and from the first and second equations, when said activation energy value is lower than the threshold value; or determining the three dopant concentrations from the first and second equations, and from a third equation derived from the electro-neutrality in the semiconductor material at ambient temperature and from the free charge carrier concentration measured at ambient temperature, when said activation energy value is equal to the threshold value.