Микроволновая вольт-импедансная спектроскопия полупроводников

We have tested experimentally the proposed method of microwave volt-impedance spectroscopy of semiconductors. The method allows to determine the local values of the semiconductor electrophysical parameters. The studies were performed on a homogeneous single-crystal GaAs wafer with a concentric antenna system formed on its surface. The resolution is determined by the diameter of the antenna central disk, which was amounted a = 12, 27, 57 μm. A constant bias voltage of 0 ≤ U ≤ 5 V was applied between the contact pads of the antennas. The complex impedance spectrum Z (f, U) of each antenna was measured using a Cascade Microtech probe station in the frequency range f = 0.1 - 10 GHz. The electrophysical characteristics of the semiconductor were determined from Z(f, U) spectra by the inverse problem solving. We have established the n-type for our semiconductor and determined the electrical potential difference on the metal-semiconductor interface. We have found as well the electron concentration, mobility and conductivity. Measurements of the same parameters by Hall four-probe method (giving the surface averaging) showed good mutual agreement of the results for the homogeneous sample under study.

Electrical conductivity and dielectric behaviour of nanocrystalline La0.6Gd0.1Sr0.3Mn0.75Si0.25O3

A complex impedance spectrum for La0.6Gd0.1Sr0.3Mn0.75Si0.25O3 sample at different temperatures with electrical equivalent circuit.

Frequency and temperature dependence behaviour of impedance, modulus and conductivity of BaBi4Ti4O15 aurivillius ceramic

In this work, we report the dielectric, impedance, modulus and conductivity study of BaBi4Ti4O15 ceramic synthesized by solid state reaction. X-ray diffraction (XRD) pattern showed orthorhombic structure with space group A21am confirming it to be an m=4 member of the Aurivillius oxide. The frequency dependence dielectric study shows that the value of dielectric constant is high at lower frequencies and decreases with increase in frequency. Impedance spectroscopy analyses reveal a non-Debye relaxation phenomenon since relaxation frequency moves towards the positive side with increase in temperature. The shift in impedance peaks towards higher frequency side indicates conduction in material and favouring of the long rangemotion of mobile charge carriers. The Nyquist plot from complex impedance spectrum shows only one semicircular arc representing the grain effect in the electrical conduction. The modulus mechanism indicates the non-Debye type of conductivity relaxation in the material, which is supported by impedance data. Relaxation times extracted using imaginary part of complex impedance (Z??) and modulus (M??) were also found to follow Arrhenius law. The frequency dependent AC conductivity at different temperatures indicates that the conduction process is thermally activated. The variation of DC conductivity exhibits a negative temperature coefficient of resistance behaviour.

AFM Investigation of Avian Influenza Viruses

The present paper describes a direct label-free diagnostic method that uses atomic force microscopy (AFM) to identify avian influenza virus strains through their electrical properties. In this method, a single virus particle is sandwiched between a rigid, conductive substrate and a conductive AFM tip (radius ∼ 8nm). Electrical characterization is achieved by probing the complex impedance spectrum of the sandwiched virus while mechanical characterization is achieved through nanoindentation. A total of three virus strains (inactivated) with different combinations of glycoprotein subtypes (H2N2, H3N5 and H4N6) were tested. Results from the electrical characterization indicate that the impedance spectra of different virus strains are indeed different. While the average electrical capacitance of a virus particle is about 17pF, the variation from one strain to another can be as high as 70%. A COMSOL Multiphysics™ simulation was carried out to estimate the electrical properties of the glycoproteins on the virus particle by comparing the simulated capacitance to the experimentally obtained values. The result indicates that the electrical conductivity of the glycoproteins is in the range of 9 to 14 mS and the dielectric constant value is around 2. The present results strongly suggest the possibility of using AFM as a diagnostic tool for direct recognition of avian influenza virus strains.