Journal of Nuclear Energy Science & Power Generation TechnologyISSN: 2325-9809

All submissions of the EM system will be redirected to Online Manuscript Submission System. Authors are requested to submit articles directly to Online Manuscript Submission System of respective journal.

Research Article, J Nucl Ene Sci Power Generat Technol Vol: 11 Issue: 6

The Dependence of Charge Carriers on the Methods of Thermal Processing of Residence Time on Silicon, Legalized with Copper and Iridium

Maxmudov SHA1, Sulaymonov AA1, Rafikov AA1* and Mirzarayimov JZ2

1Department of Nuclear Physics, Institute of Nuclear Physics of the Academy of Sciences, Yangihayot, city Tashkent, Republic of Uzbekistan

2Department of Nuclear Physics, Namangan Institute of Engineering and Technology, Namangan, Uzbekistan

*Corresponding Author: Rafikov AA, Department of Electrical, Institute of Nuclear Physics of the Academy of Sciences, Yangihayot, city Tashkent, Republic of Uzbekistan, E-mail: rafikov@inp.uz

Received date: 27 April 2022, Manuscript No. JNPGT-22-59957

Editor assigned date: 02 May 2022, PreQC No. JNPGT-22-59957 (PQ);

Reviewed date: 16 May 2022, QC No. JNPGT-22-59957;

Revised date: 23 May 2022, Manuscript No. JNPGT-22-59957;

Published date: 30 May 2022, DOI: 10.4172/2325-9809.1000287

Citation: Maxmudov SHA, Sulaymonov AA, Rafikov AK, Mirzarayimov JZ (2022) The Dependence of Charge Carriers on the Methods of Thermal Processing of Residence Time on Silicon, Legalized with Copper and Iridium. J Nucl Ene Sci Power Generat Technol 11:6.

Abstract

In this work, we investigated the dependence of the concentration of centers of energy levels on the lifetime of charge carriers in silicon samples doped with copper and iridium, and the electro physical, photoelectric and recombination properties of the sample under the influence of thermal and radiation exposure.

Keywords: ?-Radiation; Charge life time; Temperature; Energy level; Copper; Iridium; Chemical; Quasi-chemistry; Fermi level; Cooling rate

Introduction

The recombination properties of silicon, which has thermal, radioactive, and mixed defects that form deep energy levels (CHES), have been studied in many experimental and theoretical researches. The results of some studies show that in n-type silicon, the compensatory forming defect leads to a decrease in the lifetime τ of non-basic charge carriers with increasing concentration of defective centers. However, in studies, it was observed that τ increases with increasing concentration of silicon-forming centers. in particular, the increase in τ in silicon is explained differently by various authors. For example, in Refs the increase in τ is explained by a decrease in the concentration of recombination centers in thermal and radiation treatment, while in the literature the formation of oxygen complexes with various defects is observed [1]. in studies, the increase in τ is explained by the formation of sticky surfaces of the charge carriers and an increase in the degree of non-homogeneity of the conductivity in the process of compensating the silicon charge carriers as a result of external influences [2-4].

in Silicon Doped with Copper, acceptor centers with deep surface energies E1=ES-(0.15-0.21) eV, E2=ES-(0.2-0.49) eV, E3=EV + 0.23 eV, and donor centers with E4=EV+(0.16–0.21) eV and centers with energy E1=ES-(0.15–0.21) and Es-0.49 eV were strongly correlated with the oxygen concentration in the sample. it was found that an increase in oxygen concentration of ~2 order leads to a 2-3-fold increase in the center concentration of E1=Es-(0.15-0.21), and a 3-4-fold decrease in the center concentration in the center with an energy of Es-0.49 eV. in the slowly cooled n-Si<Cu> samples, deep copperforming surfaces were observed. it has been studied in the study that the charge carriers τ depend on the concentration of copper centers in n-type silicon. The energy of the deep layers formed by silicon doped with iridium is E1=ES-(0.18 ± 0.02); Acceptors with E3=ES-(0.54 ± 0.02) eV and donor centers with E2=ES-(0.32 ± 0.02) eV were identified. No dependence of iridium centers on oxygen concentration was observed. it was observed that the concentration of centers in slow-cooled samples was 1.5 times higher than the concentration of fast-cooled samples. The dependence of τ on the concentration of iridium centers of n-type silicon has been studied in [5].

From the above, it can be concluded that there are currently no single theoretical views that explain the changing nature of the life times of non-basic charge carriers in silicon. The electro physical, photoelectric and recombination properties of the sample under the influence of thermal and radiation were studied as the dependence of the concentrations of the energy transfer center on the life of the charge carriers in samples of silicon doped with copper and iridium [6].

Research Method

Samples of n- and p-type single crystal silicon (grown by the Chokhralsky method and in a crucible-free zonal solvent) with initial specific resistances of ~ 3 ÷ 10 Ohm cm were obtained. in this paper, the Hall coefficient method determined the specific resistance, mobility, concentration of the samples, and the lifetime of the charge carriers by the stationary photoconductivity method. Copper and iridium inserts were introduced by vacuum dusting and high temperature diffusion using VUP-4 equipment. For the measurement of deep energy levels, the DLTS operating on a Schottky diode used the nonstationary capacitance spectroscopy method [7-9].

Sample Preparation

Samples with n- and p-type silicon and pre-irradiated samples with a specific resistance of ~3 ÷ 10 Ohm . cm were used as the initial sample. Alloying of silicon with copper and iridium was carried out at 1050-1150 °C and then cooled at 30-40 grad/min (type i) and 250-300 grad/min (type ii). Simples n-Si<P> and P-Si<B> heat-treated without the same copper and iridium mixture and n-Si<P,P> and p-Si<Β,P> previously doped with neutrons, were tested in parallel. in n-Si and r-Si, the ohmic contacts were welded by heating the alloy SN + in (50% + 50%) to ~120 °C, while the Schottky diodes were prepared by vacuum dusting silver Ag and tin Sb on a silicon surface using a VUP-4 device [10-13].

Obtained Results

The results from the study of the effect of copper and iridium on the lifetime of non-basic charge carriers in silicon type i (fast-cooled, 250 grad/min) and type ii (slow-cooled, 30 grad/min) are presented. in Table 1, it was found that the lifetime of the charge carriers was significantly increased when heated to 1120 °C to doped with neutron and controlled n-type i-type silicon (n-Si<P,P> and n-Si<P>). it was found that the lifetime of charge carriers in n-Si<P, P, Cu>samples was 10 times longer than in n-Si<P>, n-Si<P,P> and n-Si<P, Cu>. When normal and to silicon doped with neutron when entered with iridium at temperatures of 1050 °C, 1100 °C, 1150 °C (n-Si<P,ir>, n-Si<P,P,ir>), the lifetimes of the charge carriers in them were almost indistinguishable. it was found that the lifetime of charged carriers on n-Si<P,P,Cu> increased 10 times comparing with n-Si<P>, n-Si<P,P>.

Type samples Tdif.=1120 °C Tdif.=1170 °C
i type
T.CEK.
ii type
T.CEK.
i type
T.CEK.
ii type
T.CEK.
n-Si<P> 1.10-6 5,4.10-7 7.10-7 4,3.10-7
n-Si<P,P> 3.10-6 2,4.10-7 3.7.10-7 2,3.10-7
n-Si<P,Cu> 1,6.10-6 3,8.10-6 5,3.10-6 4,6.10-6
n-Si<P,P,Cu> 2,8.10-6 5,1.10-6 7,2.10-6 7,8.10-6
n-Si<P,ir> 4,7.10-5 6,7.10-5 7,6.10-5 8,8.10-5

Table 1: Non-basic charge carriers in type i and ii n-type alloys silicon doped with copper and iridium.

in Table 2, it is detected that the lifetime of the charge carriers was significantly increased when the doped with neutron and controlled p-type i and ii (n-Si<P,P> and n-Si<P>) silicon samples were heated to 1100 °C and 1150 °C. it was found that the lifetime of charge carriers in p-Si<B,P,Cu> samples increased by ∼10 times compared to p-Si<B>, p-Si<B,P> and p-Si<B,Cu>. When ordinary and - silicon doped with neutron was doped with iridium at temperatures of 1050 °C, 1100 °C, 1150 °C (p-Si<B,ir>, p-Si<B,P,ir>), the lifetime of the charge carriers in them was almost the same, but it was found that the lifetime of the relatively charged carriers heated by p-Si<B,P> and p-Si<B> increased ~ 100 times.

Type samples Tdif.=1100 °C Tdif.=1150 °C
i type
T, CEK
ii type T, CEK i type T, CEK ii type T, CEK
p-Si<P> 1,18.10-6 1,3.10-6 10-6 1,6.10-6
p-Si<B,P> 1,3.10-6 1,6.10-7 1,7.10-6 2.3.10-6
p-Si<B,Cu> 3.10-6 3.10-6 4,8.10-6 4,7.10-6
p-Si<B,P,Cu> 6,4.10-6 6,2.10-6 7,6.10-6 8,8.10-6
p-Si<B,ir> 4,2.10-5 5,8.10-5 6.6.10-5 8.8.10-5
p-Si<B,P,ir> 4,8.10-5 6,2.10-5 7.2.10-5 9.3.10-5
         

Table 2: Primary non-charge carriers residence times in p-type silicon samples of type i and ii legalized by copper and iridium.

The results obtained for the doped sample silicon with doped i-type and n-type pre-neutrons were almost indistinguishable, i.e., T was not observed to depend on the concentration of copper and iridium centers. An insignificant increase in τ was found to be due to an increase in the concentration of Thermo-Defects (TD) in silicon.

The difference in the values of in the doped type i and type ii samples was explained by the decrease in the concentration of TD. To prove this, doped and previously silicon doped with neutron was heated isochronically at 120–700 °C (heating duration ~20 min.) And then cooled at a rate of 20 grad/min. it was observed that the residence time of non-basic charge carriers by isochron heating of n-type silicon samples previously silicon doped with neutron under the same conditions with the doped sample depended on the cooling rate (Figure 1). The increase in in this case may be related to the decay of the recombination centers formed by the controlled and uncontrolled compounds in the study of silicon.

Figure 1: n-type silicon samples depend on the cooling rate of non basic charge carriers residence time by isochron heating.

  • n-Si<P, R>NDS
  • Silicon doped with copper n-Si<0050,Cu>
  • n-Si<P,R,Cu> is preceded by a copper introduction to a silicon doped with neutron
  • n-Si<P,R,ir> temperature dependence of the lifetime of non-basic charge carriers when iridium is introduced into a previously silicon doped with neutron

When the permeability of the doped material is not homogeneous T is determined by the following formula. (1)

equation

Here σ is the minimum cross section of the charge carriers on the localized layers: ≥10-22÷10-23 CM-2, - change in the concentration of the pits: Δp <5.1014 CM-3, the thermal velocity of the ν-pits: ν~107 cm / s.

  • The conductivity of the doped material is homogeneous, if it does not have adhesive surfaces, the concentration of the mixture decreases, and the residence time of the charge carriers is determined by the following formula. (2)

equation

Where σ=10-14 CM-2 localized layers of surface charge carriers holding section:

v-pits thermal velocity: v~107 CM/C. Nn=NCu=1 ÷ 20.1013 cM-3 concentration of copper centers varying in diffusion temperature range. in this case decreases from τ - 10-6 to 5.10-8 seconds.

  • in the presence of sticky surfaces and recombination centers, their location relative to the Fermi level is shown in Figure 2. Recombination centers (1) and cleavage centers (2) are shown at levels [10].

Figure 2: Dependence of adhesion and recombination levels on Fermi level in darkness and Fermi quasi-level in light.

When illuminated, the Fermi quasi levels decreases as the electrons fall on the sticky centers as they move upward. However, if the adhesive levels are much higher than the Fermi level, the sample will not fill even when irradiated. Rather (Figure 2b) Level 3 is above the Fermi level in the dark and below when it is lit. The presence of 3 levels leads to a significant reduction in the life of the charge carriers, but when they are lit, they do not have sticky surfaces.

if the 2nd levels mentioned in (Figure 2b) are added (Figure 2c), a decrease in τ is not observed. The decrease in τ occurs only when the concentration of electrons captured by the 2 centers is the same.

Thus, based on the analysis of the three mechanisms considered, we conclude that the increase in the life of the charge carriers after high-temperature diffusion relative to the silicon obtained for the test results in the formation of sticky surfaces formed by copper + oxygen complexes. A similar situation is observed in iridium, but the sticky surfaces formed by iridium are not dependent on oxygen.

Figure 3 shows the probability of binding of 1/τ charge recombination to the dose of γ -radiation of the tested and doped samples. This figure shows that the change in the lifetime of the charge carriers depends on the dose of γ-radiation in the samples p-Si<P,B>, p-Si<P,B,Cu> and p-Si<P,B,ir>,the curves. The magnitude of the coefficient of radiation (radiation) Κτ of the change in residence time was determined.

Figure 3: p-Si<P,B > (1,2), p-Si<P,B,Cu> (4) and p-Si<P,B,ir> (3) T/T0 dose dependence of g-radiation in samples , thermal diffusion Τdif=1275 °C.

Figure 3: p-Si<P,B > (1,2), p-Si<P,B,Cu> (4) and p-Si<P,B,ir> (3) T/T0 dose dependence of g-radiation in samples , thermal diffusion Τdif=1275 °C.

in experiments, ΚT magnitude (Δ 1/T)/ΔF dose dependence was determined in the given areas. The change in the lifetime of the charge carriers in alloy and silicon at a dose of ~ 4 CM2 in the initial radiation phase was determined by the following formulas (Figure 4).

Figure 4: Δ p-Si<P,B> (1, 2), p-Si<P,B,ir>(3, 4, 5, 6) and p-Si< P,B,Cu> (7 , 8, 9, 10) were rapidly cooled (2, 4, 6, 8, 10) and slowly cooled (1, 3, 5, 7, 9). γ-radiation dependence of diffused samples at different temperatures, 1, 2, 3, 7-1075°C, 4, 8 -1175 °C, 5, 9, -1275°C and 6, 10 -1285°C.

equation

Here T - and T0 are the pre- and post-irradiation lifetimes of the charge carriers, F – γ is the fluorescence of the charge, ΚT is the lifetime of the charge carriers, γ is the coefficient of variation of the radiation, the values of which are given in Table 3.

Samples ρ, Ω.cm Tdif.. °C Cooling speed, grad/min N, Cm-3 To, S KT, Cm2/s
Ngen. Nakt.
p-Si<B,P>
p-Si<B,P,ir>
p-Si<B,P,Cu>
10
10,1
9,8
1075 250 5.1017 5.1016 2.1013 1012 1,2.10x-7 5.10-5 4,6.10-6 9,5.10-12 5,4.10-12 7,8.10-12
p-Si<B,P >
p-Si<P, ir >
p-Si<P, Cu>
p-Si<B,P,ir>
p-Si<B,P,ir>
p-Si<B,P,Cu>
10
9,1
8
13
12,8
1175 250 9.1017 1014 8.1013 2.1014 2.1014 1,4.10-6 3,2.10-7 4,5.10-6 3,2.10-7 4,5.10-6 9,1.10-12 1,2.10-12 1,9.10-12 6,4.10-12 9,8.10-12
p-Si<B,P>
p-Si<P,ir>
p-Si<P,Cu>
p-Si<B,P,ir>
p-Si<B,P,Cu>
11
9,8
9,6
15,8
13,2
1275 250 1,2.1018 6.1013 1014 4.1014 3.1014 1,6.10-6 5,9.10-7 6,8.10-6 3,2.10-7 4,5.10-6 4,5.10-12 2,9.10-13 3,3.10-13 5,4.10-13 8,8.10-13
p-Si<B,ir>
p-Si<B,Cu>
p-Si<B,Cu>
p-Si<B,P,Cu>
25
16
3500
250
1285 250 1,8.1018 7.1014 4.1014 1,5.1015 8.1014 7,3.10-5 9,2.10-6 3,2.10-7 4,5.10-6 1,5.10-13 2,7.10-13 7,4.10-13 2,8.10-14

Table 3: Previous and next parameters of p-type doped and controlled silicon γ- radiation.

it can be seen from Table 3 that as the value of ΚT decreases with increasing copper and iridium concentrations in silicon with doped, the value of ΚT in silicon with doped becomes lower than in the sample under the test. This can be explained as follows: A scheme of quasi-chemical reactions that occur under the influence of thermal and radiation radiation in doped silicon is proposed (Figure 5).

Figure 5: Defect formation in doped silicon quasi-chemical node and interstitial mixed atoms Χs–, Χi –; MMM -clusters; various mixed atoms of silicon Sii; W – divacancy; MSi-cilicides; Mixtures that form M–CHES; (W+O+Cb) - K-center.

Conclusion

it was observed that the concentration of copper and iridium inclusions previously added to silicon doped with neutron was higher than that of ordinary silicon. This was explained by the vacancies created as a result of the radiation.

For the first time, it was found that the decay rate in n-Si<B,P,ir> and n-Si<B,P,Cu> samples was slower than in n-Si<P,ir> and n-Si<P,Cu>samples. This was explained by the magnification of the potential barrier between the high and low Ohm resistance areas.

it was found that the potential barrier of copper-enriched samples of silicon previously doped with neutrons were 5 times larger than that of copper-enriched samples of ordinary silicon. Thermostability was observed in the temperature range 250-300°C during type ii samples, and the increase in lifetime and stability of charge carriers after high-temperature diffusion relative to silicon doped with neutron was explained by the formation of adhesive surfaces formed by copper+oxygen complexes.

Thus, based on the obtained results, it will be possible to deepen the knowledge about the occurrence of electrophysical phenomena in doped silicon and the production of new thermostable semiconductor devices in agriculture.

References

international publisher, scitechnol, subscription journals, subscription, international, publisher, science

Track Your Manuscript

Awards Nomination

Media Partners