Influence of temperature and frequency on the electrical parameters of thermally evaporated metal-free phthalocyanine H<Subscript>2</Subscript>Pc thin films

The ac electrical properties of metal-free phthalocyanine (H₂PC) thin films have been studied in the frequency range from 10² to 2×10⁴ Hz and in the temperature range from 150 to 475 K. The ac conductivity σ was found to vary as ω^s with the index s≤1. Although these general values of s appear to be consistent with a hopping process, the present σ values do not increase monotonically with temperature. At low frequency, the capacitance and loss tangent were found to be constant over the entire frequency range, in good qualitative agreement with the equivalent circuit model consisting of an inherent capacitance in parallel with a resistive element. Moreover, at constant frequency, the two parameters increased with increasing temperature up to approximately 300 K. Above this temperature, another sharp decrease in both capacitance and loss tangent was obtained. This type of behavior was interpreted in terms of nomadic (delocalized) polarization, which leads to an increase in the dielectric constant. The drastic decrease of the capacitance and loss tangent observed above room temperature is thought to be related to the decrease in the dielectric constant, which results from the inability of the domains to hold the increases in free charge carrier concentration due to the increase of temperature. Received: 6 December 2001 / Accepted: 7 January 2002 / Published online: 19 July 2002 RID="*" ID="*"Corresponding author. Fax: +972-2/279-6960, E-mail: asaleh@science.alquds.edu     

DC conductivity and dielectric constant of cellulose nitrate detector

The temperature dependence of DC conductivity as well as the temperature and frequency dependence of dielectric constant of cellulose nitrate (CN) track detector was undertaken for better understanding of the track response of the detector. In the temperature range −100° to + 100°C, CN is found to be an insulating semiconductor with activation energies 0.04 eV, 0.78 eV and 1.24 eV. The transition of the activation processes takes place at (−10±1)°C and (60±1)°C. The high activation energy transition temperature coincides with the glass transition temperature of CN. The dielectric constant is found to increase with temperature and decrease with frequency. These results reveal the physical basis of the Ion Explosion Spike model of Fleischer et al. (1975). A possible explanation of the registration temperature effect is also given on the basis of these results.     

巨介电常数氧化物CaCu3Ti4O12的介电和阻抗特性

采用固相烧结法合成了单相巨介电常数氧化物CaCu₃Ti₄O₁₂（CCTO）.用阻抗分析仪分析了10—420 K温度范围内的介电频谱和阻抗谱特性,并结合ZVIEW软件进行了模拟.结果表明：温度高于室温时,频谱出现两个明显的弛豫台阶,低频弛豫介电常数随温度升高而显著增大,表现出热离子极化特点;温度低于室温时,频谱表现出类德拜弛豫,且高、低平台介电常数值基本不随温度变化,表现出界面极化特点和较好的温度稳定性.频谱中依次出现的介电弛豫对应于阻抗谱中 关键词： 3Ti₄O₁₂')" href="#">CaCu₃Ti₄O₁₂ 介电频谱 阻抗谱 Cole-Cole半圆弧     

Laser induced air breakdown using 0.355, 0.532, and 1.06 µm radiation

Studies of breakdown threshold intensity for air at various pressures in the range of 24–760 torr using 0.355, 0.532 and 1.06 μm radiation are reported. We observep ^−0.8 scaling ofI _th at 1.06 μm and a weak scaling ofp ^−0.4 at 0.532 and 0.355 μm radiation. Strong dependence of breakdown spot size on laser power but weak dependence on air pressure is observed.     

Dielectric behaviour of Cu---Cr ferrites

Samples of the system CuFe_2−xCr_xO₄ where x = 0.0, 0.2, 0.4, 0.6 and 0.8 were prepared. The dielectric constant and dielectric loss were measured at different frequencies and temperatures from room temperature to 600 K. The dielectric constant was measured using the phase detector technique (lock-in amplifier). The results showed that the dielectric loss decreases with increasing frequency and Cr substitution. The dielectric constant decreases with both increasing frequency and Cr substitution at room temperature. At moderate temperatures, the dielectric constant shows a dispersion peak ′_max, and this peak shifted to higher frequency with increasing temperature. The results are explained in the light of the fact that the dielectric polarization process is similar to that of conduction. The appearance of the dispersion peak is related to the contribution of two types of charge carriers.     

Improving Melt Flow Behavior via Melt Vibration

A self‐made melt vibration extrusion device was used to study the melt flow behavior in a vibration field. A pulse pressure was superimposed on the flowing melt during extrusion, called vibration assisted extrusion (VAE); conventional extrusion (CE) was studied for comparison. A die (L/D=17.5) was attached to the device to study melt flow behavior of an amorphous polymer (polystyrene) and semi‐crystalline polymers (high density and linear low polyethylene). Results show that the melt vibration technique is an effective processing tool to improve polymer melt flow behavior for both crystalline and amorphous polymers. Increasing with vibration frequency for extrusion at constant vibration pressure amplitude, the viscosity decreases sharply, and also with increasing vibration pressure amplitude at a constant vibration frequency. The effect of vibration field on melt flow behavior depends greatly on the melt temperature, with the largest change in viscosity obtained at low temperature. Increasing with vibration frequency at constant pressure vibration amplitude, the maximum decrease percentages of viscosities are 82.9, 66.7, and 48.9%, for HDPE, LLDPE, and PS, respectively; increasing with pressure vibration amplitude at a constant vibration frequency, the maximum decrease percentage of viscosities are 99.0, 94.3, and 99.0%, for HDPE, LLDPE, and PS, respectively.     

Melt Vibration Improved Melt Flow Behavior and Mechanical Properties of High Density Polyethylene

A pulse pressure was superimposed on the melt flow resulting in melt vibration. With application of the melt vibration technology, the melt flow behavior and mechanical properties of high‐density polyethylene were studied. For vibration‐assisted extrusion (VAE) at constant vibration pressure amplitude, the viscosity decreases sharply with increasing vibration frequency, and also does so when increasing vibration pressure amplitude for VAE at constant vibration frequency. The effect of vibration field on melt rheological behavior is also related to the melt temperature; a large decease in viscosity is obtained at low melt temperature. Compared with the mechanical properties obtained by conventional injection molding (CIM), the mechanical properties for vibration‐assisted injection molding (VAIM) samples were improved by changing the vibration frequency and vibration pressure amplitude. Injected at constant low vibration pressure amplitude, the VAIM sample prepared at high vibration frequency shows large elongation at break; injected at constant low vibration frequency, the VAIM sample prepared at high vibration pressure amplitude shows greatly improved yield strength. The above two VAIM processing routes produce different VAIM samples with different fracture behaviors; a distinct layered structure for VAIM samples was observed by SEM.     

Structural and magnetic properties of Mg substituted NiCuZn Nano Ferrites

The present paper examines the effect of magnesium substitution on structural and magnetic properties of NiCuZn nano ferrites synthesised by sol-gel method. The prepared samples were characterised by using X-ray Diffraction (XRD), Fourier transform infrared spectroscopy (FT-IR), Field Emission Scanning Electron Microscopy (FE-SEM) and Vibration sample magnetometer (VSM) techniques. The phase identification, unit cell parameter and crystallite size was determined using XRD analysis. The lattice constant reduced with increasing Mg content. Room temperature saturation magnetisation and coercivity showed reverse trend with increasing Mg content. Curie temperature (T_c) obtained from the thermo magnetic curves increases with Mg concentration. The initial permeability (μ_i) decreased with increasing Mg content. This is due to reduced magnetisation, grain size and increased magneto-crystalline anisotropy constant. Simultaneously, there is an upward shift of domain wall relaxation frequency with increasing Mg content. Also the permeability is observed to be constant up to 30 MHz frequency range showing compositional stability and quality of the material. The prepared samples were suitable for applications in Multilayer Chip Inductors due to their invariable permeability up to 30 MHz frequency and high thermal stability along with low sintering temperature.     

Submillimeter Wave ESR Measurement for Cr3+ in Ruby Crystal Using a Gyrotron as a Radiation Source

Fine structure constant of ruby has been measured using an ESR spectrometer with a pulse magnetic for high fields and a gyrotron as a radiation source in a millimeter to submillimeter wave range. The measurement was carried out at room temperature. The Zeeman energy in this frequency range is large enough compared with the fine structure constant. The higher order term in the effective spin Hamiltonian can explain the dependence of fine structure constant on the frequency. The observed fine structure constants depend on the field intensity.     

Analysis of the relationship between temperature dependence of the libration mode and dielectric relaxation in NaNO2

The behavior of the low frequency dielectric constant of NaNO₂ as function of frequency and temperature is consistently correlated to the temperature behavior of the frequencies and linewidths of the phonons of B₁ symmetry in the crystal. The frequency of the librational ‘soft’ mode closely related to the ferroelectric-paraelectric phase transition does not go to zero but tends to a hard core value at the transition temperature. The behavior of the dielectric constant as function of temperature and frequency is explained by assuming a dielectric relaxation mechanism proposed by Mason and not by Cochran's soft phonon model.     

金红石相纳米块材TiO2的介电特性

研究了不同制备压力下成型的以金红石相为主的纳米二氧化钛介电常数的频率谱和温度谱。在频率谱上发现,当频率ω<0.1kHz时,随着测量频率的下降,介电常数迅速升高,低频下的介电常数比高频区的介电常数高1—2个数量级。并且随着样品加压压力的提高,介电常数升高,在与之相对应的介电损耗谱上,随着样品加压压力的提高,损耗值下降,损耗峰向低频区位移。对1.0GPa压力下成型的样品,其介电常数随测量温度的升高,分别在50℃和300℃出现两个峰值。经分析得出,影响金红石相纳米二氧化钛介电行为的微观机制主要为晶粒内部的电子松弛极化和界面中的电偶极矩的转向极化,50℃峰对应于电于松弛极化,而300℃峰则对应于电偶极矩的转向极化。 关键词：     

Electromechanical and pyroelectric properties in CoZn ferrite transducer

The system Co_0.6Zn_0.4Fe₂O₄ ferrite was prepared by the usual ceramic method. The resonant frequency and antiresonance of vibrating disc have been studied as a function of temperature. The decrease of resonant frequency with rising temperature was attributed to increase the interaction of domains with the applied AC field. The decrease of the ultrasonic wave velocity with the increase of temperature was ascribed to thermal lattice vibration, which facilitate the domains to interact at lower frequency of the applied AC field. The electromechanical coupling factor of the radial mode was fairly constant with rising temperature. The pyroelectric voltage measured at the transducer electric terminals increases with the increase of temperature. Ferrite transducer is useful for ultrasonic generation to be used in technology.     

Investigation of electrical properties (ac and dc) of organic zinc phthalocyanine,ZnPc, semiconductor thin films

We report measurements on the electrical properties of thermally evaporated zinc phthalocyanine, ZnPc, semiconductor thin films. Aluminum and gold metal electrodes were used and both proved to act as ohmic contacts. A relative permittivity, ε_r, of 1.56 was estimated from the dependence of capacitance on film thickness. The room temperature current density–voltage measurements indicated an ohmic conduction at low voltages, while a space–charge-limited conduction at higher voltages. An average value of a thermally generated hole concentration of the order 10¹³ m⁻³ was estimated at room temperature.The ac conductivity, capacitance and loss tangent were measured over a wide range of temperature (from 170 to 430 K) and frequency (between 0.1 and 20 kHz). The ac conductivity of ZnPc films was observed to be proportional to ω^s, where ω is the angular frequency, and the index s is a temperature and frequency-dependent constant. At low temperatures and for higher frequencies the ac conduction was due to hopping. The capacitance, as well as the loss tangent, was found to be dependent on both temperature and frequency, but was constant for all frequencies at low temperatures. Such dependences were accounted for the equivalent-circuit model consisting of inherent capacitance in parallel with a temperature dependent resistive element.     

Mutual inductance bridge for magnetic relaxation measurements at low temperatures

An apparatus using a mutual inductance bridge has been designed to measure real and imaginary parts of the magnetic ac susceptibility simultaneously in the frequency range from 1 Hz to 230 kHz at helium temperatures. From 230 kHz up to 3 MHz the real part can be determined. The susceptibility as a function of temperature or external magnetic field at constant frequency may be measured. In addition, frequency sweeps can be performed with temperature and magnetic field held constant. The experiment is controlled by an on-line computer.     

Frequency and temperature amplitude dependence of complex heat capacity in the melting region of polymers

Amplitude and frequency dependence of reversible melting of polycaprolactone (PCL) and an ethylene octene copolymer (EOM) were studied using temperature-modulated differential scanning calorimetry (TMDSC) (2?10^?1 Hz <f < 0.05 Hz) and shear spectroscopy (dynamic mechanical analysis, DMA) (5?10^?4 Hz < f < 100 Hz). It was found that the excess heat capacity of PCL is constant for temperature amplitudes in the range 5 mK < A_T < 2 K. The excess heat capacity decreases with frequency of temperature perturbation and tends to zero at about 0.1 Hz and 100 Hz for PCL and EOM, respectively. The constant excess heat capacity and the frequency dependence support the idea that reversible melting is related to a relaxation process on the surface of the polymer crystals. The occurrence of such a relaxation process was shown by shear modulus measurements in the same frequency and temperature region. The relaxation process is, in the melting region, much slower than main relaxation (glass transition). At low temperatures, a crossover can be seen, indicating the independence of both processes because of spatial separation. The main relaxation is related to the melt, while the other is related to the crystal surface.     

Frequency moments and energy shifts for dilute Mössbauer impurities in metallic solids

Theoretical evaluations of frequency moments and second order Doppler shifts have been made for dilute⁵⁷Fe impurities in the high temperature limit for a harmonic solid. The resonant energy shifts have been calculated from the Green’s function of the impure crystal containing both mass disordering and force constant change terms in the crystal Hamiltonian. High temperature frequency moments for the impurity in different metallic solids are obtained from Mc-Millan ratios using standard Mössbauerf-values at room temperature. The effect of mass disordering predominates over the force constant change term in the evaluations of second order Doppler shifts and hence the frequency moments for dilute⁵⁷Fe impurities. The variation of frequency moments for the impurity with mass modified Debye-temperature of the hosts is shown for a number of metallic solids.     

Temperature dependence of the dielectric constant and I.R. reflection spectrum of LiNBO3 by Raman scattering

The temperature and frequency dependence of the dielectric constant, ?_xx, and the reflection coefficient associated with LiNbO₃ in the far infrared (i.r.) was obtained from Raman scattering measurements. The Raman spectrum associated with the E symmetry vibrational mode was carefully studied in the temperature range of 77 to 1190 K. The first order scattering intensity was related to the imaginary part of the dielectric constant and the Kramers-Kronig relation was used to obtain the dielectric constant.     

Vibrations of an orthotropic elliptic plate of non-uniform thickness and temperature

An analysis is presented of the free vibrations of an orthotropic elliptic plate whose temperature and thickness spatial variations both are parabolic along a line through the plate centre. An approximate but quite convenient frequency equation is derived by using Galerkin's method with a two-term deflection function. The upper bounds of frequencies corresponding to the first two modes of vibrations of a clamped orthotropic elliptic plate for various values of aspect ratio, taper constant and temperature constant are obtained.     

Anomalous temperature dependence of phonon modes in Bi2Ti4O11 and modified Bi2Ti4O11

We have observed the anomalous temperature dependence of the phonon modes in the Raman spectra of Bi₂Ti₄O₁₁ and the modified Bi₂Ti₄O₁₁ with the dopant of PbO. The square of the lowest mode frequency in both substances decreases linearly with increasing temperature, while the damping constant increases reaching a peak value at the transition temperature. The mode frequency, however, does not tend to zero but stays finite and the damping constant decreases above the transition temperature. The mode is Raman-active both above and below the transition temperature.     

Dielectric relaxation in polyvinylidenefluoride–polysulfone blends

Dielectric properties of polymer blend of polyvinylidenefluoride (PVDF) and polysulfone (PSF) of different wt. % have been studied to understand the molecular motion and their relaxation behavior in the frequency range of 100 Hz to 10 kHz at different temperatures between 30 and 190 °C. The dielectric constant of the blend decreased with frequency and increased with the increasing temperature and PSF content in the blend. The magnitude of dielectric loss also increased with increase in temperature and PSF content. The observed characteristic has been consistently explained in terms of dipolar motions and the plasticization effect brought about by blending of PSF with PVDF. At constant frequency and temperature, the blend follows a linear relationship between logarithm of their dielectric constant and different ratios of blend. The appearance of a peak for each concentration in dielectric loss suggests the presence of relaxing dipoles in the blend. In addition of PSF with PVDF, the peak shifts toward higher frequency side suggesting the speed up the relaxation process. AC dielectric data is also combined with thermally stimulated depolarization current (TSDC) data which is generally studied for low-frequency dielectric properties of polymers blends so as to produce the results in a wide frequency range. The glass transition temperature (T_g) of the blend was studied by differential scanning calorimetric technique (DSC), the T_g was compared and correlated with TSDC peak. The blend samples were characterized by X-ray diffraction (XRD) and scanning electron microscopy (SEM) to study the formation of blend and micro structural properties of the materials. The shifting of peak toward lower diffraction angle side confirms the reduction in particle size with increasing amorphous content in the blend.