Temperature Dependence Of Electrical Conductivity Research Articles

ВПЛИВ РЕНТГЕНІВСЬКОГО ОПРОМІНЮВАННЯ НА ЕЛЕКТРОПРОВІДНІСТЬ ПОЛІТИПІВ КРИСТАЛІВ β-TlInS2

It was investigated the influence of temperature changes on conductivity of a non-irradiated and X- ray radiated samples of e-TlInS2 crystals polytypies. Object of the study - irradiated and radiated samples of e-TlInS2 crystals polytypes. Purpose of the study - experimental investigation conductivity temperature dependences on the DC (direct current) e-TlInS2 crystals irradiated and X-ray radiated С- and 2С- polytypes. Method of the study - the temperature dependence of electrical conductivity on DC was experimentally investigated in temperature range Т = 100-300 K for the non-irradiated and X-ray radiated C- and 2C-polytypes of e-TlInS2 crystals. It is shown that the basic mechanism of transfer of charge in the temperatures interval T=130-165 K for both e-TlInS2 crystals polytypies is variable range hopping conduction and such temperature intervals are wider in case of the radiated samples. The densities of localized states near the Fermi level were calculated, for both non-irradiated and X-ray radiatied (dose 2.7х103 Gy) samples of e-TlInS2 crystals polytypies. It was discovered that irradiation by the indicated dose of X-ray radiation of the samples both crystals e-TlInS2 polytypies increase of their conductivity, almost on an order, and also is accompanied by disappearance for non-irradiated sample of C-polytype unusual for semiconductors temperatures change of conductivity in the interval T=196-214 K. KEYWORDS: POLYTYPES, X-RAYS RADIATION, CONDUCTIVITY, SEMICONDUCTORS, HOPPING CONDUCTIVITY

Reversible temperature-dependent photoluminescence in semiconductor quantum dots for the development of a smartphone-based optical thermometer.

Photoluminescence (PL) intensity-based non-contact optical temperature sensors are in great demand due to their non-contact nature, rapid response, sensitivity, as well as thermal and chemical stability at different environmental conditions. However, herein, reversible temperature dependent PL emission quenching properties of chemically synthesized Mn2+-doped ZnS QDs (MZQDs) have been advantageously utilized for achieving the development of a smartphone-based optical thermometer. The temperature dependent variations of PL have been studied by taking MZQDs in various forms, such as in aqueous dispersion, powder form, and a polymer-encapsulated thin film. The origin of the PL quenching of MZQD in the polymer film has been cross-verified through temperature-dependent electrical conductivity measurement and the movement of charge carriers has also been confirmed by the first-principles DFT simulation. Through thermal cycling experiments on QD-encapsulated polymer film and by utilizing an indigenously-developed Android App based on color coordinates, a novel smartphone-based colorimetric imaging method for the measurement of temperature has been demonstrated in this work. The synthesized smart QDs might be suitable candidates for temperature sensing and the colorimetric thermometer probe may be utilized in various photonics applications as a smart optical sensor for daily life applications.

Lithium-antimony co-doping induced morphology transition in spray deposited SnO2 thin films

Un-doped, Sb doped (ATO) and Li-Sb co-doped SnO2 (LATO) transparent conducting thin film electrodes have been deposited using facile spray pyrolysis method. X-ray diffraction study is carried out to confirm the crystal structure, phase purity, and textured growth of the films. Surface morphological transition from dendritic to cuboid shape is observed upon Li-Sb co-doping into the SnO2 system from the scanning microscopy measurements. The AFM analysis confirms that as Li doping concentration (1, 3, 5 wt.%) increases, the surface roughness of the films decreases. The UV-Vis transmittance spectra of the SnO2 film doped with 5 wt.% Li and 5 wt.% Sb (LATO5) shows maximum average transmittance of 87.9 % at 550 nm and the calculated direct band gap value is 4.06 eV. The LATO5 film exhibits high carrier concentration and high mobility of 7.54 × 1020 cm−3 and 7.221 cm2/Vs, respectively, due to co-dopant effect at the Sn sites of SnO2 lattice, resulting in enhanced electrical transport properties compared to un-doped SnO2 film. The LATO5 film also exhibits lowest sheet resistance of 32.38 Ω/□ and resistivity of 1.57 × 10−3 Ω cm. The temperature dependent electrical conductivity study is performed to understand the conduction mechanism of the film via estimation of activation energy from Arrhenius plots. The obtained results indicate that the Li-Sb co-doped SnO2 films are potential candidates for alternative transparent conducting electrode system.

Field dependent conductivity and threshold switching in amorphous chalcogenides—Modeling and simulations of ovonic threshold switches and phase change memory devices

We model electrical conductivity in metastable amorphous Ge2Sb2Te5 (GST) using independent contributions from temperature and electric field to simulate phase change memory devices and ovonic threshold switches. 3D, 2D-rotational, and 2D finite element simulations of pillar cells capture threshold switching and show filamentary conduction in the on-state. The model can be tuned to capture switching fields from ∼5 to 40 MV/m at room temperature using the temperature dependent electrical conductivity measured for metastable amorphous GST; lower and higher fields are obtainable using different temperature dependent electrical conductivities. We use a 2D fixed out-of-plane-depth simulation to simulate an ovonic threshold switch in series with a Ge2Sb2Te5 phase change memory cell to emulate a crossbar memory element. The simulation reproduces the pre-switching current and voltage characteristics found experimentally for the switch + memory cell, the isolated switch, and the isolated memory cell.

Subzero temperature dependence of electrical conductivity for permafrost geophysics

Temperature dependence of the electrical conductivity of natural waters due to viscosity-based reduction in ionic mobility is well-established for unfrozen conditions. For cold regions, a model for the temperature dependence of electrolyte conductivity at subzero temperatures is required for geophysical studies of permafrost terrain, for which salinity and tension forces may result in freezing-point depression. Extension of the linear temperature model for unfrozen conditions has been applied to geophysical studies of permafrost, but has not been experimentally validated. The temperature dependence of electrical conductivity is measured at subzero temperatures, but above the depressed freezing point for NaCl solutions at a range of concentrations from seawater to brine. Measurements show near-linear dependence of electrical conductivity on temperature down to the lowest experimental temperature of ˗9 °C with no distinct change in behavior observed for subzero temperatures. Given the observed temperature dependence, the linear temperature-conductivity compensation equation is extended to ˗9 °C with a temperature compensation coefficient of 0.019 °C˗1 for a reference temperature of 20 °C with subzero prediction errors of 1–6%. This equation can be used to compensate for temperature dependence of electrical conductivity with reasonable accuracy for geophysical experiments in permafrost terrain. Subzero accuracy is improved by adopting a quadratic temperature compensation equation that accounts for an observed increase in nonlinear behavior at lower temperatures distant from the reference.

Enhanced Power Factor of PEDOT:PSS Films Post-treated Using a Combination of Ethylene Glycol and Metal Chlorides and Temperature Dependence of Electronic Transport (325–450 K)

We report temperature dependence of electrical conductivity and thermopower for poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) thin films post-treated using a combination of an...

New liquid-free proton conductive nanocomposite based on imidazole-functionalized cellulose nanofibers

The first successful attempt to synthesize a new proton conducting polymeric nanocomposite film based on pure cellulose nanofibers (CNF) as a polymer matrix functionalized on their surface with imidazole molecules (Im) as a dopant, was made. The 2CNF-Im nanomaterial contains on average one molecule of imidazole per 2 glucose units from cellulose chains. Water evaporation and thermal stability of 2CNF-Im were studied by thermogravimetric analysis (TGA and DTG) and differential scanning calorimetry (DSC). The temperature dependence of electrical conductivity was studied by the impedance spectroscopy. At 140 °C, the 2CNF-Im nanocomposite has a maximum conductivity of 7.0 × 10−3 S/m, i.e. four orders of magnitude higher than that of non-functionalized CNF matrix. The newly synthesized cellulose nanocomposite exhibits high electrical and thermal stability. In 2CNF-Im, the activation energy of the proton transport process is the lowest compared to the previously synthesized imidazole-functionalized composites based on other pure cellulose materials and equals 0.62 eV. The synthesized nanomaterial is liquid-free solid polymer electrolyte showing proton conductivity above the boiling point of water.

A Study of Electrical Characteristics of Crystals of Homogeneously Doped LiNbO3:Zn,Mg in the Temperature Range of 450–900 K

In a series of initially polydomain crystals of LiNbO3:Zn,Mg obtained by the homogeneous doping of the crystals in the concentration ranges of around 1 ± 0.02 mol % MgO and 3.0–4.6 mol % ZnO, abrupt increases in temperature dependences of electrical conductivity σ(T) and dielectric constant e(T) with the manifestation of low-frequency dielectric dispersion are observed near T* ≈ 800 K. At T > T*, these crystals exhibit the activation enthalpy (Ha ≈ 1.76–2.07 eV) and transport enthalpy (Hm ≈ 1.55–2.01 eV) values that are unusually high for cationic conductors, while both values at T T*).

Mixed-conduction mechanism of Cr2Ge2Te6 film enabling positive temperature dependence of electrical conductivity and seebeck coefficient

A Cr2Ge2Te6 (CrGT) film is known to be a phase change material showing low-energy phase change between amorphous and crystalline phases. A crystalline Cr2Ge2Te6 (CrGT) film obtained from an amorphous phase via metastable crystalline phase has been reported to possess different local structure from the CrGT bulk material. The bulk CrGT is known to show a band conduction, while the conduction mechanism of the CrGT film has not been clear yet. In this study, the conduction mechanism of the CrGT film was discussed based on the temperature dependence of the conductivity (σ), Seebeck coefficient (S), and Hall properties. It was found that the CrGT film shows a variable range hopping conduction below 170 ​K, while it shows a mixed-conduction of band-like conduction and nearest-neighbor hopping conduction above 300 ​K. Such the mixed-conduction mechanism was found to cause the positive temperature dependence of the σ and S in the CrGT film. Furthermore, the thermal conductivity of the CrGT film was measured to be 0.16 ​W/mK, which is much lower than that of the bulk material. The mixed-conduction mechanism and the low thermal conductivity introduced by nanostructuring through sputtering method is suggested to promising strategy to enhance the thermoelectric properties of the CrGT material.

Transition of charge transport phenomena from 3D to 1D hopping at low temperatures in polyaniline/graphene composites

Here, we present the charge transport properties of polyaniline/graphene composites prepared by a chemical oxidation method in the presence of four different loading concentrations (2, 4, 6, and 8 wt. %) of graphene. The synthesized materials are characterized for surface and chemical bonding analyses through field-emission scanning electron microscopy and Fourier transform infrared spectroscopy techniques, respectively. The change in the chemical structure of the prepared composites with graphene loading concentrations revealed the possible increment in electrical conductivity. The room-temperature dc conductivity of the prepared composites was found to increase from ∼22 to 217 S/cm with an increase in the loading concentration of graphene from 2 to 8 wt. %. The temperature-dependent electrical conduction behavior of the prepared samples is investigated under Mott's variable-range hopping conduction mechanism. It is found that all composite samples follow three-dimensional (3D) hopping in the higher temperature region (>44 K), which transforms into one-dimensional (1D) hopping at lower temperatures (<44 K). A decrease in hopping distance (1.07–0.96 nm) and an increase in density of states (3.20 × 1021–4.95 × 1021 cm−3 eV−1) in three dimensions with an increase in the graphene loading concentration from 2 to 8 wt. % suggest the requirement of lower hopping energy (61.3–55.5 meV) for conduction. The estimated hopping parameters also revealed a nonadiabatic small-polaron hopping conduction mechanism that is followed by the charge carriers in the present samples for both one- and three-dimensional variable range hoppings.

Investigation of parameters of Schottky diodes based on chromium silicides

In this work, the parameters of Schottky diodes obtained by sputtering chromium on silicon and annealed at 900÷1100°C. were investigated. Experimental studies of Schottky contacts based on silicides have an all-microscopic analysis of the physical and chemical properties of the layers and an analysis of the electrical behavior of the system. The Schottky model assumes that surface states are located on the border between the transition layer and silicon. Using measurements of direct and inverse volt-amperage characteristics (VAC), values of the height of the effective Schottky barrier, the rate of change in the height of the barrier, as well as the value of the density of surface states, the thickness of the transition layer were obtained and the tunneling process was considered. The temperature dependencies of electrical conductivity are given and the course of the curve is analyzed. The obtained VAC is explained by the model of thermionic emission of the Schottky theory. Height of a barrier to contact chrome-silicon silicide which is equal to 0.65 eV is determined, and the factor of ideality was close to unit. The number of steps required by the charge carriers to overcome the potential barrier is determined. It is described that the current transfer mechanism is associated with the presence of surface states at the interface, as well as the occurrence of lattice mismatch and the difference in thermal coefficients. Diode illumination by LED confirms the effect of surface states on VAC. An increase in the surface states of photogenerated holes is shown. It has been shown that the existence of surface states affects the change in the height of the potential barrier, the amount of bending of the zones, and also determines that the predominant transfer mechanism is a tunneling multistage mechanism.

Thermodynamical analysis for mixed convective peristaltic motion of silver-water nanoliquid having temperature dependent electrical conductivity

The development of advanced-performance thermal frameworks for increased heat transport has proved to be of remarkable interest these days. Therefore, present attempt is intended to deal with entropy generation and heat transfer analysis for the peristaltic flow of an electrically conducting silver-water nanoliquid through a symmetric channel. System is supposed to be affected by an external magnetic field and electrical conductivity of nanofluid is considered to vary with temperature. Mixed convection, joule heating aspects along with thermal and velocity slip conditions are considered in analysis. Two phase model of nanofluids is adopted. Mathematical modeling for entropy generation is carried out via second law of thermodynamics. Making use of numerical solver NDSolve, graphical analysis for entropy generation, heat transfer, Bejan number and velocity is presented. Results reveal that by enhancing electrical conductivity parameter entropy generation increases. It is further deduced that entropy generation can be minimized by addition of silver nanoparticles. Bejan number increases by increasing Grashoff number. For large values of Hartman number temperature increases. Temperature of nanofluid increases by enhancing thermal slip parameter. Increase in Grashoff number provides better rate of heat transport at the boundary. Moreover, velocity decreases by enhancing velocity slip parameter.

Structural analysis and temperature dependent conductivity of LaxCu1-xO shrimp-like nanostructures synthesised via wet chemical precipitation

A series of well textured undoped and La-doped CuO (LaxCu1-xO, x = 0, 0.03, 0.06 and 0.10) nanostructures were synthesised via a low cost and facile wet chemical precipitation route. The structural, optical and temperature dependent electrical properties of the products were investigated and correlated. X-ray diffraction (XRD) showed formation of a pure phase of monoclinic CuO (undoped and 3–6 at.% La-dopped sample) and CuO-La2O2CO3 mixed phase in the higher doped sample (10 at.%). Scanning electron microscopy revealed shrimp like nanostructures of diverse sizes and aspect ratios for all the samples. The samples showed an optical absorption spectra with cut-off wavelengths lying in the visible spectral region. The temperature dependent electrical conductivity was measured and the trends depicted a typical semiconducting behaviour in all the samples. La doping of >3 at.% was associated with increased resistivity and premature levelling of the conductivity profiles at higher temperature. At 523 K, the electric field generated mobility and carrier concentration product values were observed to drop monotonously with doping. At room temperature the values were found to increase from 7.11 × 1014 (cm.s.V)−1 for the 0 at.% to peak at 2.16 × 1015 (cm.s.V)−1 for the 3 at.% and dropped to 8.95 × 1013 at 10 at.%. The conduction mechanism was explained on the basis of the hopping model.

Computational Modeling of Cardiac Ablation Incorporating Electrothermomechanical Interactions

AbstractThe application of radio frequency ablation (RFA) has been widely explored in treating various types of cardiac arrhythmias. Computational modeling provides a safe and viable alternative to ex vivo and in vivo experimental studies for quantifying the effects of different variables efficiently and reliably, apart from providing a priori estimates of the ablation volume attained during cardiac ablation procedures. In this contribution, we report a fully coupled electrothermomechanical model for a more accurate prediction of the treatment outcomes during the radio frequency cardiac ablation. A numerical model comprising of cardiac tissue and the cardiac chamber has been developed in which an electrode has been inserted perpendicular to the cardiac tissue to simulate actual clinical procedures. Temperature-dependent heat capacity, electrical and thermal conductivities, and blood perfusion rate have been considered to model more realistic scenarios. The effects of blood flow and contact force of the electrode tip on the treatment outcomes of a fully coupled model of RFA have been systematically investigated. The numerical study demonstrates that the predicted ablation volume of RFA is significantly dependent on the blood flow rate in the cardiac chamber and also on the tissue deformation induced due to electrode insertion depth of 1.5 mm or higher.

Abnormal temperature-dependent electrical conduction in ZnAl-layered double hydroxide nanostructures

Layered double hydroxides (LDHs) have recently emerged as promising materials for various device applications due to their controllable properties depending on the type or ratio of cations and anions constituting the crystal structure. Despite active research on the electrical, electrochemical, and photochemical applications of LDH nanostructures, their electrical conduction mechanism and the correlation between their temperature-dependent electrical and structural properties have rarely been investigated. Herein, we report on the abnormal temperature-dependent electrical property of the ZnAl-LDHs and verify its origin based on in-situ structural and chemical investigations. The electrical conductivity of the ZnAl-LDHs increased continually with increasing temperature from 25 to 55 °C, but then decreased drastically as the temperature was further raised to 115 °C. During cooling back to room temperature, the conductivity decreased gradually with decreasing temperature. The temperature-dependent chemical and structural investigations verified that the water content and composition of anions in the ZnAl-LDHs were changed by the temperature variation, which resulted in the abnormal electrical properties of the ZnAl-LDHs.

(Invited) Electrical Conductivity of Ceria-Based Oxide/Alkali Carbonate Eutectics Nanocomposites

Currently, the problem of global warming and exhaustion of fossil fuel has become a big problem on the global scale, therefore a highly efficient electric power generating device that does not emit greenhouse gases such as carbon dioxide is required. Especially, since high temperature fuel cell such as solid oxide fuel cell (SOFC) or molten carbonate fuel cell (MCFC) operate at high temperature, these have the advantages that efficiency is high and expensive noble metal catalysts are unnecessary for the electrode. However, the operation at high temperature leads to degeneration of the cell component, which makes it unsuitable for long lifetime. Thus, attempts to lower the operating temperature have been made.1 Ceria-based oxide doped with trivalent Sm and Gd (SDC or GDC) was noticed, it achieves sufficient oxygen ion conductivity even in the middle temperature range of 773-973 K. However, with only ceria-based oxide, it indicates electron conductivity, which makes open circuit voltage lower. Adding carbonate makes composite indicated good electron insulator, ceria-based oxide/molten carbonate composite electrolyte is one of the candidate of middle temperature fuel cells. In the composite material, the molten carbonate is impregnated in the oxide and the interfacial layer is formed between solid oxide and carbonate due to solid-liquid interaction.In this study, we applied nano-ordered SDC powder prepared by the complex polymerization method to composite of SDC/molten carbonate eutectics.2 The ionic conductivity using the ac impedance measurement, the thermal properties and spectral properties of carbonate was measured in order to discuss the influence of the solid phase to the ionic conduction near the solid phase.Ceria and SDC were prepared by the Pechini method using citric acid and ethylene glycol mixed with predetermined amounts of Ce(NO3)3 and Sm (NO3)3 aqueous solution. Obtained Sm3+ doped CeO2 samples indicate Sm ratios of 10 and 20 mol% (SDC10 and SDC20). As the liquid (melt) phase, alkali carbonates were dehydrated in CO2 at 473 K for 48 hours, and the prepared eutectics; (Li0.52Na0.48)2CO3 (LN) and (Li0.43Na0.32K0.25)2CO3 (LNK) were used. Oxide and eutectics were mixed so as to obtain predetermined liquid phase volume fraction to obtain CeO2-eutectics or SDCs- eutectics. The mixed sample was pressed at 60 MPa for 30 minutes and fired at eutectic temperature or higher to prepare pellets for AC impedance measurement in the temperature range of 623-773K in 25 Hz -1 MHz. The eutectic point of the bulk LN is seen at 771 K, and the eutectic point is shifted to lower temperature by mixing with oxide. When the liquid phase volume fraction is around 60-90 vol%, no remarkable change in the eutectic point of LN was confirmed. However, the significant decrease in the eutectic point was confirmed from the region of 60 vol% or less in any oxides. The endothermic peak associated with melting decreased as the amount of liquid phase decreased, and finally disappeared below 30 vol% or less. On the other hand, when compared with past results using CeO2 (1.5 m2 g-1) having a small specific surface area as solid phase, the melting enthalpy was confirmed even when the liquid phase was 5 vol%.The temperature dependences of electrical conductivity in ceria-based oxide/LN and LNK coexisting system are shown in Fig.1. For using LN eutectics, the transition point due to melting of the eutectic molten salt was observed at around 720 K at the liquid phase of 25 vol% or more. The conductivity at the liquid phase volume fraction of 45 vol% is smaller than the value of 15-35 vol% in the region below the transition point. As the liquid phase amount increases, the bulk molten salt crystallizes, from which, it is considered that the crystallized molten salt inhibited the electrical conduction pathway. In addition, at 15 vol%, the conductivity did not change remarkably even before and after the transition point, and there was no melting enthalpy change at 25 vol% or less, so from these results, the molten salt existing at the solid interface is in molten state even below the transition point. For LNK system, the effect of solid phase is more effective than that for LN systems. The activation energy of conductivity increased with decreasing apparent average thickness. This phenomenon was remarkable where an abrupt increase was observed below the apparent average thickness of 1 nm. B. Singh et al., J. Power Sources, 339, 103(2017).P. Ramos-Alvarez, et al., J. Mater. Sci., 52, 519 (2017). Figure 1

Structural and electrical characterization studies for ternary composite of polypyrrole

In this work, temperature dependence of alternate current (AC) and direct current (DC) conductivities of optimized polypyrrole/silver-tantalum oxide (PPy/Ag–Ta2O5), a ternary conducting polymer composite is comparatively studied with those of PPy and PPy/Ag. For the purpose, silver (Ag) nanoparticles were encapsulated with polypyrrole (PPy) by in situ oxidative polymerization to form core–shell structured PPy/Ag composite for which Ag nanoparticles were extracted from green tea. The PPy/Ag composite was then mechanically mixed with tantalum pentoxide (Ta2O5) to form PPy/Ag-Ta2O5 ternary composite. Increase in depth of delocalization band of PPy in ternary composite as compared to those of PPy/Ag composite and PPy, indicating its increased AC conductivity confirmed from the comparative FTIR analyses. Interaction between PPy/Ag composite and Ta2O5 in the ternary composite was confirmed from XRD studies. The formation of core–shell structured PPy/Ag composite and Ta2O5 particles embedded in such PPy/Ag composite to form PPy/Ag–Ta2O5 ternary composite confirmed from TEM and Raman studies. The frequency- and temperature-dependent electrical conductivity studies revealed increase in AC conductivity of the ternary composite as compared to those of PPy/Ag composite and pure PPy attributed mainly to interfacial effects. The charge transport in these samples predicted to be due to correlated barrier hopping of charges was confirmed by calculating their respective AC and DC activation energies.

Electrical properties of solution cast films of polystyrene/polyaniline-multiwalled carbon nanotube nanocomposites

Self-standing films of camphor sulphonic acid doped polyaniline (PANI) and polystyrene (PS) with different multiwalled carbon nanotube (MWNT) loadings are successfully prepared by solution casting method. The presence of MWNT is characterized by X-ray diffraction and Raman spectroscopy. Raman modes confirm the presence of PANI and MWNTs. Transmission electron microscope images confirm the presence and dispersion of MWNTs in the film. The temperature-dependent electrical conductivity of the films is measured in the temperature range 10–300 K for different loadings of MWNTs. The nanocomposite films show a very low percolation threshold with nearly three order enhancement of electrical conductivity with MWNT loadings. The electrical conductivity variation with temperature follows the fluctuation induced tunnelling model. The films show two order increases in mobility with 1.45 wt% MWNT loadings. Hall Effect study confirms that the PANI-PS blend films switched from p-type to n-type behaviour with the addition of MWNT.

Electrical Properties of Compact Drop-Casted Cu2SnS3 Films

We investigated temperature-dependent electrical conduction of Cu2SnS3 (CTS) thin films in the range of 77–500 K synthesized by drop-casting molecular ink. The films were directly formed by drop-casted molecular ink, consisting of a Cu+2-Sn+2-thiourea complex dissolved in a mixture of ethylene glycol–isopropyl alcohol and annealed. The CTS films have a smooth layer with a compact structure, as revealed by cross-sectional scanning electron microscopy. The films are p-type and show a band gap of 1.18 eV. The electrical conductivity and Hall mobility of the films were found to be 1.1 S/cm and 6.72 cm2 V−1 s−1, respectively. Data from temperature-dependent measurements show hopping and thermally activated conduction below and above 300 K, with an activation energy of ∼ 10 and 90 meV, respectively. Our results suggest that the drop-casted CTS films can be used as an absorber layer in thin film solar cells at an affordable cost.

An experimentally verified three-dimensional non-stationary fluid model of unloaded atmospheric pressure inductively coupled plasmas

A three-dimensional non-stationary numerical model of spectrochemical and technological inductively coupled plasma (ICP) systems is presented in the paper. The model considers the ICP as a gaseous media (with temperature-dependent electric conductivity) interacting with electromagnetic field generated by inductive coil. The model is based on simultaneous solution of the Maxwell’s and gas flow equations together with the energy equation coupled-together by corresponding source terms and material properties to take into account inductive current forming within the carrier gas and subsequent Joule heating, the Lorentz force and how does it affect the gas flow pattern. It allows calculation of temporal evolution of three-dimensional distributions of electromagnetic fields, pressure, gas velocity and temperature within a plasma torch and a condensation chamber used for powder processing. The model is applicable for simulation of atmospheric pressure electrodeless plasmas under local thermodynamic equilibrium that consist of pure gases and their mixtures. Such operating conditions are typical for ICPs that are used for elemental analysis and technological powder processing. Special attention is paid to experimental verification of the model. The simulation results are cross-verified for both types of ICPs (spectrochemical and technological one) using high-speed optical and schlieren visualization of gas flows. The discrepancy between calculations and experimental data does not exceed 10%.