The relative current change, concentration, and carrier mobility in silicon samples doped nickel and at pulse hydrostatic pressure
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Materials Today1
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2. Experimental section
In this paper we consider the change in the concentration and mobility of charge carriers in silicon samples with deep levels under pulsed hydrostatic pressure. Pulsed hydrostatic pressure is a sharp increasing in the hydrostatic pressure of the liquid due to a sharp decreasing in its volume. As well as the contribution of thermal and vibrational- relaxation effects in the pulse hydrostatic pressure (PHP). For our experiments we made silicon samples with Ni alloy with a resistivity ~ 10 3 ohm cm and with different types of conductivity. Doping of silicon single crystals with nickel impurities was made from a layer of Diffuser deposited on the silicon surface by vacuum spraying on a VUP-5 unit. Nickel diffusion was carried out in a horizontal SOUL-4 furnace in the temperature range T = 900÷1200 o С within two hours. As a Diffuser, Ni was used with a purity of 99.999%. After diffusion annealing, in order to remove the near-surface layer, 50-60 μm each was ground on each side of the samples. The electrical parameters of the samples (electrical conductivity, concentration and mobility of the current carriers) were determined by the Hall Effect of measurements [3]. For measuring the resistivity of the samples was used four-probe method [3]. 2.1 Results and discussion As shown by the experimental results, the nature of the change in the concentration of current carriers in samples of silicon with deep levels coincides with the nature of the change in the current of these samples at a pulsed hydrostatic pressure. Fig. 1 shows the relative changes in current (1, 1 ‘) concentrations (2, 2’) and the mobility (3) of charge carriers in the highly compensated n-Si resistivity of ~ 10 3 ohmcm. It is evident that under the influence of pulse pressure, carrier density, increasing, reaching a maximum value, further reduced and is not changed, equal to its static value Figure 1. In this variation of the current flowing through the sample n-Si pulsed hydrostatic pressure occurs due to a change in the concentration and mobility of the current carriers. We also investigated contributions of changes in the concentration and mobility of charge carriers in the overall change in the flowing current through the sample. As shown by the results of experiments, the current flowing through the sample changes relative to the original value by 55 percent due to a change in concentration and by 10 percent due to mobility of the charge carriers. In the samples (p–Si of greater than n–Si levels are closer to the valence band than to the conduction band. At pulse pressure, additional transitions from the 444 O.O. Mamatkarimov et al. / Materials Today: Proceedings 17 (2019) 442–445 valence band to the deep levels of nickel occur in the samples of p-Si p–Si 10%) at IHP. Fig. 1 The relative changes in current (1, 1’) the concentration (2, 2’) and the mobility (3) of charge carriers in the samples n-Si 3 ohmcm at a hydrostatic pressure pulse amplitude P = 510 8 Pa. dP/dt = 210 8 Pa/s. To study the mechanism of manifestation strain effect in Si current change when the temperature changes by an electrical heater (1a, b the curves 1’, 2’). In this case the test samples were directly under the influence of hydrostatic pressure. As can be seen from the figures the temperature of the changes in the concentration of 50% of the dynamic concentration changes. According to our assumption of the remaining 50% accounted for by changes in the vibrational-relaxation effects stimulated pulse hydrostatic pressure. It also shows that both the n- Si concentration p-Si Download 0.58 Mb. Do'stlaringiz bilan baham: 
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