2.1

Description of samples

Test switches made of semi-isolating GaP single crystals (SI GaP) marked with labels GaP-1 and GaP-2 were used in the studies. On the polished surface of the SI GaP plates, two ohmic contacts were made by applying gold at a distance of 2 mm from each other, to which two electrodes from electrolytic copper were attached. SI GaP plates were in the form of chips with an area of 1 x 1 cm² and a thickness of 0.5 mm. Before attaching the electrodes, the surface of the material was mechanically and chemically cleaned. The electrodes were made in the form of strips 0.3 mm thick, 10 mm wide and 15 mm long, with 0.2 mm thick, 2 mm wide and 100 mm long leads. Both electrodes and leads were covered with a layer of silver. To ensure protection against external factors and reduce the speed of surface recombination of excess charge carriers, after connecting the electrodes, the switches were coated with a 200 nm SiO₂ layer and then embedded in a transparent resin. Figure 2 illustrates the appearance of the test switches, ready for measurement.

Figure 2.

Photo of investigated PCSS switches made of semi-insulating gallium phosphide.

2.2

Dark current measurements

The measurements carried out are a continuation of the research described in [11]. In the blocking state, the METREL MI 3210 TeraOhm XA meter was used to measure switch parameters. It served as a source of DC voltage and a meter of resistance and current. It allows current measurements in the range from 0.1 nA to 5 mA at voltages from 50 V to 10 kV. For each sample, for every measured value starting from a voltage of 500 V with a step of 500 V, a series of three measurements were made. The obtained results of current measurements depending on the voltage and resistance as a function of electric field strength are presented in figures 3 and 4 respectively.

Figure 3.

Current-voltage characteristics of test switches made of semi-insulating gallium phosphide measured at 300 K.

Figure 4.

Dependence of switch resistance on the electric field strength in the active area, determined on the basis of dark current intensity measurements at a temperature of 300 K.

Analyzing the characteristics shown in figures 3 and 4, it can be seen that the current conducted through the GaP-1 sample is 2 orders of magnitude larger than in the case of GaP-2, and the difference of samples resistance values is also in range of 2 orders of magnitude. The dark current of the GaP-2 sample in the whole tested range has a linear course, while the sample resistance decreases linearly in the range from 7.7 to 35.55 kV/cm (corresponding to voltages from 3.46 to 7.11 kV). GaP-2 measurement results in the range from 2.58 to 7.7 kV/cm can be explained by the inaccuracy of the measuring device occurring at low system voltages. In the voltage range from 516 V to 8.65 kV, corresponding to the electric field strength from 2.58 to 43.23 kV/cm, linear characteristics of dark current waveforms and blocking resistance for the GaP-1 sample were obtained. In the voltage range from 8.65 to 10.2 kV (43.23 to 51 kV/cm) there is a significant increase in the value of dark current from 1373 to 2480 nA and a decrease in resistance from 6.3 to 4.11 GΩ. Despite the non-linearity of the characteristic curves in the voltage range shown and the corresponding electric field strengths, the GaP-1 sample shows a blocking resistance of more than 1 GΩ, which is a satisfactory result.

The conductivity in the blocking state σ_o is expressed by the formula:

In which d is the width of the semiconductor area between the electrodes, R - the resistance determined in the measurements and s is the cross-sectional area of the active region of the sample. The conductivity of the samples varied from 1.96·10^-7 to 4.87·10^-7 Ω^-1cm^-1 for GaP-1 and from 4.51·10^-9 to 6.92·10^-9 Ω^-1·cm^-1 for GaP-2. Figure 5 shows the calculated conductivity values of the tested samples in the blocking state.

Figure 5.

Conductivity of test switches with SI GaP in a blocking state depending on the electric field strength at 300 K

2.3

Photocurrent measurements

Measurements in the conduction state were made in a system consisting of the METREL MI 3210 TeraOhm XA meter, which was a voltage source, and connected in series studied PCSS switch and resistor with known resistance. Voltage drops on the switch and resistor, as well as the response of the system to the impulse switching the sample into the conduction state were recorded using an oscilloscope. The optical switching pulse, with a width of ~ 5 ns, was generated by a tunable laser, and the laser beam was emitted with a frequency of 10 Hz. Time courses of voltage drop across the resistor were recorded after averaging 128 waveforms caused by the optical pulse. The schematic diagram of the constructed measurement system is shown in figure 6.

Figure 6.

Schematic diagram of the measurement system used to measure the test characteristics of SI GaP switch in the conduction state.

The GaP-1 sample was tested in the wavelength range from 410 to 710 nm, corresponding to photon energy in the range from 1.75 to 3.0 eV, with a laser beam energy of 190 μJ and an applied voltage of 10.2 kV. The maximum achieved values of the conducted current depending on the photon energy for the GaP-1 switch are shown in figure 7.

Figure 7.

Maximum photocurrent values achieved for the GaP-1 sample in the conduction state for a 10.2 kV system voltage at 300 K. Laser beam energy 60 μJ.

In figure 7, a 2.5 times increase in conducted photocurrent can be observed, from 0.2 to 0.5 mA, for photon energy in the range 2.18 to 2.25 eV. This increase is associated with approaching the absorption edge, occurring at energy close to 2.26 eV, the width of band gap of gallium phosphide. In conduction of current generated by photons with lower energy than that, participate only charge carriers generated using energy levels of deep defect centers in material. Only the charge carriers, generated through the energy levels of deep defect centers in the material, participate in the conductivity of the current generated with lower photon energy.

For the GaP-2 sample, a series of tests were carried out for two selected wavelengths of the laser beam in the range of applied voltages from 1 kV to 7 kV. The energy of the laser beam in the measurement series was 60 μJ. The wavelengths were 450 nm and 700 nm, which corresponds to photon energy of 2.76 and 1.77 eV, respectively. The maximum achieved values of the conducted current through the GaP-2 switch as a function of the applied voltage are shown in figure 8.

Figure 8.

Maximum photocurrent values for a GaP-2 sample at a given photon energy depending on the applied voltage measured in a conduction state at 300 K. Laser beam energy 60 μJ.

Following the obtained characteristics waveforms in figure 8, it can be seen that the photocurrent intensity increases linearly with the increase of the applied voltage for photon energy greater than the energy corresponding to the absorption edge (hv > E_g). For photons with energy of 2.76 eV, there is a linear increase in conducted current with increasing voltage. Photocurrent intensity at 1.04 kV and 7.11 kV voltages are 1.49 μA and 9.9 μA, respectively. Photocurrent intensity for 2.76 eV photon energy is about 4 times higher than at the same voltage values for 1.77 eV photon energy, 0.35 μA and 2.53 μA, respectively.

Conductivity in the conduction state was determined based on Ohm’s law and equation 1. Figures 9 and 10 show the results of conductivity calculations, respectively for the GaP-1 sample in the entire photon energy range tested, and for the GaP-2 sample, for the photon energy value 1.77 eV and 2.76 eV.

Figure 9.

Dependence of conductivity on photon energy for the GaP-1 sample in temperature 300K. OY axis presented on a logarithmic scale.

Figure 10.

Dependence of conductivity on the electric field strength for the GaP-2 sample in temperature 300K. The red results indicate photon energy equal to 2.76 eV, the blue results indicate photon energy 1.77 eV.

Figure 9 shows an increase in the conductivity of the GaP-1 sample by 3 orders of magnitude for photon energy in the range of 2.18 to 2.3 eV. The maximum value of the conductivity achieved was 0.042 Ω^-1cm^-1 for a wavelength of 540 nm and 530 nm, corresponding to the photon energy of 2.3 eV and 2.34 eV. Figure 10 shows that the difference in conductivity for 1.77 eV and 2.76 eV photons was within 1 order of magnitude. At an electric field strength of 35.55 kV/cm, values of 5.0·10^-7 and 1.98·10^-6 Ω^-1cm^-1 were achieved.

2.4

Determination of time constants

Time constants were determined for the recorded waveforms of voltage drop. They affect the switch off time and are related to the parameters of defect centers. The inverse of the time constant of these e_T waveforms, determining the rate of thermal emission of charge carriers from defect centers, is described by the Arrhenius equation.

In equation (2) E_a means the activation energy of the centers, A is the product of material constant γ and capture cross section for electrons σ, T is the temperature on an absolute scale, while K_B is the Boltzmann constant.

These waveforms can be described by the sum of exponential functions and expressed by the equation in the form:

A single term of the sum represents course associated with one type of defect centers in the switch material. The coefficient a is related to the concentration of charge carriers emitted from a given defect center. The coefficient b is related to the parameters of the defect center. The methods of obtaining and analyzing defect centers parameters based on Arrhenius plot, were the subject of earlier studies presented in detail in [12, 13].

The recorded course of non-stationary photoconductivity illustrating the response of the system to the impulse switching the GaP-1 sample into the conduction state for 2.25 eV photon energy at 10.2 kV is shown in figure 11. Figure 12 shows the response of a GaP-2 sample to an optical pulse of 2.76 eV photon energy 7.11 kV.

Figure 11.

The obtained photocurrent waveform in the switch as a function of time at a temperature of 300 K, at a beam energy of 190 μJ. Supply voltage 10.2 kV. The moment of switching pulse is at the point t = 0.

Figure 12.

The obtained photocurrent waveform in the switch as a function of time at a temperature of 300 K, at a beam energy of 60 μJ. Supply voltage 7.11 kV. The moment of switching pulse is at the point t = 0.

Figures 13 and 14 show fragments of recorded waveforms of photocurrent flowing through the sample from the time the maximum was reached until the switch returned to the blocking state. For the GaP-1 sample, the results of measurements for 10.2 kV voltage and 2.25 eV photon energy (550 nm) are presented, while for the GaP-2 sample the results for 7.11 kV voltage and 2.76 eV (450 nm) photon energy are illustrated.

Figure 13.

Determined time constants of the photocurrent pulse for the GaP-1 switch in the conduction state when excited with 2.25 eV (550 nm) photons at 10.2 kV. The original pulse waveform is marked in black, the numerically determined sum of time constants in red, as green, blue and purple are marked in order time constants i1, i2 and i3

Figure 14.

Determined time constants of the photocurrent pulse for the GaP-2 switch in the conduction state with 2.76 eV (450 nm) photon energy at 7.11 kV. The original pulse waveform is marked in black, the numerically determined sum of time constants in red, as green, blue and purple are marked in order time constants i1, i2 and i3

From the characteristics presented in figures 13 and 14 it follows that the first time constant i1 has the greatest impact on the shape and time of the sample entering the blocking state. The second and third time constants (i2 and i3) affect only the maximum current value and reach values close to zero after a short period of time, on the order of 100 ns. Figure 15 presents the impact of photon energy on photocurrent time constant waveforms for the GaP-1 switch. Figure 16 shows a comparison of the determined time constants for the GaP-2 switch for different applied voltages.

Figure 15.

Determined time constants of photocurrent waveforms for the GaP-1 switch in the conduction state with photon energy 2.3, 2.25 and 2.18 eV at 10.2 kV. The time constants i1, i2 and i3 for individual photon energies are marked in order with green, blue and purple colors.

Figure 16.

Determined time constants of the photocurrent pulse waveforms for the GaP-2 switch in the conduction state at 2.76 eV (450 nm) photon energy. The time constants i1, i2 and i3 for 3.06 and 7.11 kV are marked in order with green, blue and purple color

Based on the characteristics presented in figure 15, we can observe that as the photon energy increases, the amplitude of the exponential photocurrent waveform of the time constant i1 increases. For photon energy smaller than the width of the band gap of gallium phosphide, we can observe a significant decrease in the amplitude of photocurrent waveforms with time constants i1 and i2. At the same time, the decay time of individual photocurrent waveforms does not change. Analyzing figure 16, we can conclude that the maximum values of individual time constants increase as the applied voltage increases.