Positive temperature coefficient of resistivity effects of semiconducting (Bi(1/2)Na(1/2)) TiO_3-CaTiO_3-BaTiO_3 ceramics sintered in air atmosphere

Y^3＋-doped （Bi 1/2 Na 1/2） TiO 3-CaTiO 3-BaTiO 3 （BNCBT） positive temperature coefficient of resistivity （PTCR） ceramics sintered in air atmosphere were investigated in this study. （Bi 1/2 Na 1/2） TiO 3 （BNT） component can remarkably increase the onset temperature T c of PTCR ceramics with the expense of the resistivity R 25 increase. CaTiO 3 （9–27 mol%） component can decrease the resistivity, and adjust the effects of BNT phase on the T c point. For the sample containing 3 mol% CaTiO 3 , T c raises from 122 ℃ to 153 ℃ when only 0.6 mol% BNT added, while for the ones with higher CaTiO 3 content （9–27 mol%）, T c is only increased by a rate of 8–9℃/1.0 mol% BNT. The effects of BNT and CaTiO 3 components on R25/Rmin （negative temperature coefficient effect） are also discussed.

Mn掺杂对SrBiFeO陶瓷NTC特性的影响

以Bi2O3,Fe2O3,MnO2和SrCO3为主要原料,采用传统固相法制备出具有负温度系数(NTC)特性的SrBiFeMnO陶瓷。研究了该陶瓷的物相结构、断面形貌及电性能。结果表明:试样的室温电阻率ρ25和热敏电阻特性常数B25/85随着x(Mn)的增加均呈现先增大后减小的趋势。在25～200℃的测试温区内,x(Mn)为0.1时,掺杂的SrBiFeO陶瓷材料的电阻率-温度特性呈现良好的线性关系;x(Mn)为0.5时,掺杂SrBiFeO陶瓷材料具有较好的NTC特性,其ρ25为145Ω.cm,B25/85为2950K。

新型高B值NTC热敏材料的制备及其性能研究

以AlN,SiO2和Al2O3为主要原料,采用固相法制备出一种新型高材料常数B值负温度系数(NTC)热敏电阻材料。借助XRD、SEM、粒度分析和阻温特性测试仪等,研究了所制备NTC热敏电阻材料的相组成、微观结构及其电学性能,并简要讨论了SEM与粒度分析结果产生差异及材料常数B值较传统NTC热敏电阻材料B值大的内部机制。结果表明:所制备材料由亚微米级且分布均匀的颗粒组成。同时该材料具有良好的负温度系数热敏特性,在350℃时的电阻率ρ350为1 340 kΩ·m;在300～500℃,材料常数B为12 000～13 000 K,激活能ΔE为1.03～1.12 eV。

Epoxy Resin/Nano Ni@C Composites Exhibiting NTC Effect with Tunable Resistivity

Epoxy resin/Ni@C nanoparticle composites with aligned microstructure were prepared by using a procedure of magnetic field assisted curing. The results show that the resistivity of composites exhibits negative temperature coefficient （NTC） effect above room temperature, and can be adjusted by varying the content filler and the magnitude of magnetic field applied. Hill＇s quantum tunneling model was modified to understand the electrical conduction mechanism in the composites. It shows that the NTC effect ascribes to the dominant thermal activated tunneling transport of electron across adjacent nanoparticles, as well as the low thermal expansivity of epoxy resin matrix.

Effects of La_2O_3 Doping on Aging Properties of Mn_(2.38)Ni_(0.5)Cu_(0.12)O_4 Type NTC Thermistor Materials

The effects of La_2O_3 doping on the phase structure.electric properties and aging properties of the samples were researched using XRD,SEM and electric property measurements.The results suggest that the aging value of Mn_(2.38)Ni_(0.5)Cu_(0.12)O_4 thermistor ceramic samples decreases from 10%to about 6%by only doping La_2O_3.The electrical stability of the sample has improved as well.Such doped material will broaden the production and application scope of Cu contained negative temperature coefficient thermal ceramics.

碳纤维增强木质复合材料的制备与电学性能研究

采用脲醛树脂作为粘合剂配合异氰酸酯制备了碳纤维增强木质复合材料(Carbon Fiber Enhanced Woodiness Composites,CFEWC)。在制备过程中,通过改变碳纤维和木质纤维的配比和两种纤维之间的复合形式,研究了复合材料样板的相关电学性能,并且从多个角度分析了样板电学性能变化的原因。实验结果表明:单贴面复合材料样板和双贴面复合材料样板都具有导电性,双贴面复合材料样板具有更良好的导电性。随着碳纤维含量比重的增大,CFEWC的导电性能逐渐提高,空穴导电和π电子的数量增加;随着温度的升高,CFEWC的表面电阻率呈现出非线性的负增长态势,更多的导电粒子获得能量被激发产生了NTC(Negative Temperature Coefficient)效应。

直流马达软启动电路研究

文中提出了三种直流马达软启动方案:负温度系数热敏电阻软启动、继电器延时软启动、MOSFET线性放大软启动,并分析了各方案的原理和特性,给出了实验结果。原理分析和实验结果表明三种方案都可以有效抑制马达的启动电流,能实现直流马达的软启动。通过对比,给出了三种方案各自的应用场合。

具有核壳结构材料的薄膜热敏电阻

分别采用巯基丙酸包覆的银(Ag/MPA)和十二胺包覆的硫化银(Ag2S/DDA)纳米粒子通过涂布和煅烧两步法在低温下获得了Ag2S-Ag核壳结构薄膜热敏电阻(NTCR)和Ag2S薄膜NTCR。使用扫描电子显微镜(SEM)对Ag2S-Ag核壳结构薄膜形貌进行了表征,使用X射线衍射光谱仪(XRD)与透射电子显微镜(TEM)对薄膜粒子组成、结晶度及结构进行了测试分析,研究了不同制备条件下的Ag2S-Ag核壳结构薄膜NTCR的热敏电阻系数(NTC)特性,根据ASTM D3359附着力测试标准分析了薄膜对基底的附着力。结果表明,所制备器件膜厚均匀且表面平整,器件的膜厚为1.64μm,热敏系数B、零功率电阻温度系数αT和电子活化能Ea值分别为2 707 K,-32 234×10-6K-1和5.533×10-3e V,附着力测试评价达5 A。与Ag2S薄膜NTCR相比,Ag2S-Ag核壳结构薄膜NTCR具有更优的NTC特性,膜厚可控,具有高灵敏度及环境适应性。

A Comparison Study of Sinterability and Electrical Properties for Microwave and Conventional Sintered Mn_(0.43)Ni_(0.9)CuFe_(0.67)O_4 Ceramics

In this paper, a quaternary system of Mn0.43Ni0.9CuFe0.67O4 negative temperature coefficient （NTC） thermistor ceramic prepared by solid/solid reaction was sintered by microwave and conventional method, respectively. To characterize the sinterability of the samples, the densification parameter, porosity and grain size distribution of the bulk were determined. The crystal structure, phase compositions, morphology and impedance of the samples were analyzed by X-ray diffraction （XRD）, scanning electron microscopy （SEM）, energy-dispersive spectroscopy （EDS） and impedance analysis. The experimental results confirmed that the sinterability and electrical properties of ceramics were homogenously improved by microwave sintering.

Analysis on First-stage Ignition of n-Heptane at Low Temperatures with a Lumped Skeletal Mechanism

Two-stage ignition exists in the low-temperature combustion process of n-heptane and the first-stage ignition also shows a negative temperature coefficient(NTC) phenomenon. To study key reactions and understand chemical principles affecting the first-stage ignition of n-heptane, a lumped skeletal mechanism with 62 species is obtained based on the detailed NUIGMech1.0 mechanism using the directed relation graph method assisted by sensitivity analysis and isomer lumping. The lumped mechanism shows good performance on ignition delay time under wide conditions. The study revealed that the temperature after the first-stage ignition is higher and a larger amount of fuel is consumed at lower initial temperatures. The temperature at the first-stage ignition is relatively insensitive to the initial temperature. Further sensitivity analysis and reaction path analysis carried out based on the lumped mechanism show that the decomposition of RO_(2) to produce alkene and HO_(2) is the most important reaction to inhibit the first-stage ignitions. The chain branching explosion closely related to the first-stage ignition will be terminated when the rate constant for the RO_(2) decomposition is larger than that of the isomerization of RO_(2) to produce QOOH. The NTC behavior as well as other characteristics of the first-stage ignition can be rationalized from the competition between these two reactions.

Evaluation of structure,dielectric and electrical properties of(Li/Ta/Sb)modified(Na,K)NbO_(3) lead-free ceramics with excess Na concentration

Polycrystalline perovskite structured Li_(0.04)(Na_(0.54+x) K_(0.46))_(0.96)(Nb_(0.81)Ta_(0.15)Sb_(0.04))O_(3) ceramics with x¼0:00,0.005 and 0.01 mole excess Na concentration were prepared by solid state sintering method.The present study relates the role of excess Na addition with the stoichiometry,density,structure,dielectric and ferroelectric properties of the samples.X-ray diffraction(XRD)pattern exhibits single phase orthorhombic structure.The characteristic Raman modes were observed due to translational modes of cations and vibrational modes of NbO_(6) octahedra and no structural phase transition were observed.This confirms the formation of single phase perovskite structure and is consistent with XRD results.The dielectric permittivity increases about two times,while dielectric loss decreases by four times for χ=0.01 composition.The electrical measurements carried by Complex Impedance spectroscopic analysis suggest negative temperature coefficient of resistance(NTCR)behavior.

Enhanced aging and thermal shock performance of Mn_(1.95-x)Co_(0.21)Ni_(0.84)Sr_(x)O_(4) NTC ceramics

The Mn_(1.95-x)Co_(0.21)Ni_(0.84)Sr_(x)O_(4)(MCNS)(0≤x≤0.15)based negative temperature coefficient(NTC)materials are prepared by co-precipitation method.The replacement of Mn by Sr plays a critical role in controlling the lattice parameter,relative density,microstructure,and electrical properties.The lattice parameter and relative density increase with the increase of Sr content.A small amount of Sr restrains the grain growth and increases the bulk density.Moreover,the room resistivityρ25,material constant B25/50,activation energy Ea,and temperature coefficientαvalues of MCNS ceramics are influenced by the Sr content and ranged in 1535.0–2053.6Ω·cm,3654–3709 K,0.3149–0.3197 eV,and(–4.173%)–(–4.111%),respectively.The X-ray photoelectron spectroscopy(XPS)results explain the transformation of MCNS ceramics from n-to p-type semiconductors.The conduction could arise from the hopping polaron between Mn3+/Mn4+and Co^(2+)/Co^(3+) in the octahedral sites.The impedance data analysis also discusses the conduction mechanism of the MCNS ceramic,whereas grain resistance dominates the whole resistance of the samples.Furthermore,the aging coefficient(△R/R)of MCNS ceramics is found to be<0.2%,which indicates the stable distribution of cations in the spinel.Finally,the MCNS ceramics demonstrate excellent thermal durability with<1.3%of resistance shift after 100 thermal shock cycles.

Enhanced conductivity and stability of Co_(0.98)Cu_(x)Mn_(2.02−x)O_(4)ceramics with dual phases and twin structures

Semiconductor materials with heterogeneous interfaces and twin structures generally demonstrate a higher concentration of carriers and better electrical stability.A variety of Cu-doped Co_(0.98)Cu_(x)Mn_(2.02−x)O_(4)(0≤x≤0.5)negative temperature coefficient(NTC)ceramics with dual phases and twin structures were successfully prepared in this study.Rietveld refinement indicates that the content of a cubic spinel phase increases with increasing Cu content.The addition of Cu can promote grain growth and densification.Atomic-level structural characterization reveals the evolution of twin morphology from large lamellae with internal fine lamellae(LIT lamellae)to large lamellae without internal fine lamellae(L lamellae)and the distribution of twin boundary defects.First-principles calculations reveal that the dual phases and twin structures have lower oxygen-vacancy formation energy than those in the case of the pure tetragonal and cubic spinel,thereby enhancing the transmission of carriers.Additionally,the three-dimensional charge-density difference shows that metal ions at the interface lose electrons and dwell in high valence states,thereby enhancing electrical stability of the NTC ceramics.Furthermore,the additional Cu ions engage in electron-exchange interactions with Mn and Co ions,thereby reducing resistivity.In comparison to previous Cu-containing systems,the Co_(0.98)Cu_(x)Mn_(2.02−x)O_(4)series exhibit superior stability(aging value≤2.84%),tunable room-temperature resistivity(ρ),and material constant(B)value(17.5Ω·cm≤ρ≤7325Ω·cm,2836 K≤B≤4315 K).These discoveries lay a foundation for designing and developing new NTC ceramics with ultra-high performance.

Dielectric relaxation and modulus spectroscopy analysis of(Na_(0.47)K_(0.47)Li_(0.06))NbO_(3) ceramics

We have investigated the structure,dielectric and electrical properties of lead-free polycrystalline (Na_(0.47)K_(0.47)Li_(0.06))NbO_(3) ceramics as a function of temperature and frequency in order to understand the intrinsic contribution of grain/bulk and grain boundary effects toward the dielectric response as well as the electrical conduction mechanism in the samples fabricated by microwave sintering method.X-ray diffraction analysis exhibits perovskite structure with orthorhombic symmetry,which is well supported by the Raman spectroscopic analysis.A minor secondary impurity phase of tungsten bronze structure was observed for samples sintered at 1050℃,which gets weaker for samples sintered at 1150℃.Dielectric permittivity was enhanced by 50%,although there was a reduction in the dielectric loss by about 50%at Curie temperature(450℃)for samples sintered at 1150℃.Complex impedance spectroscopic analysis indicated non-Debye-type dielectric relaxation present in the samples,and this phenomenon followed thermally activated process related to hopping mechanism.Nyquist plot showed the negative temperature coefficient of resistance,characteristic of the samples.