电荷密度波,charge density wave
1)charge density wave电荷密度波
1.The measurement result of the thermoelectric power(TEP) of a quasi\|two\|dimensional conductor NaMo 6O 17 , which exhibitscharge density wave properties, was reported.报道了在 10~300 K 温度范围内,对准二维电荷密度波导体 Na Mo6 O17紫青铜热电势的测量结果。
2.The Grüner′s equation is a classical model for studying thecharge density wave,where analytical solution can not be obtained.Grüner方程是研究电荷密度波的经典模型,它是一个非线性微分方程,没有解析解。
3.Based on a theoretical model for interchain coupled quasi-one-dimensional organic ferromagnet, thecharge density wave(CDW) and spin density wave(SDW) that exist in the system are investigated.基于考虑链间耦合的准一维有机铁磁体的理论模型 ,对存在于系统内的电荷密度波 ( CDW)和自旋密度波 ( SDW)进行了研究 。
英文短句/例句
1.Charge Density Wave and the Analysis on Grüner s Equation;电荷密度波与Grüner方程的向量场分析
2.THE LOW FREQUENCY PINNING OF CDW IN W DOPED THALLIUM BLUE BRONZE Tl 0.3 Mo 0.99 W 0.01 O 3钨掺杂铊蓝青铜中电荷密度波的低频钉扎
3.Low-Temperature Electronic Transport Property of Quasi-One-Dimensional Charge-Density-Wave Conductor Rb_(0.3)MoO_3;准一维电荷密度波导体Rb_(0.3)MoO_3的低温电输运性质
4.By the charge density we mean the per unit volume.所谓的电荷密度是指单位体积的电荷。
5.They measured the strength of electrical charges moving in waves from the brain.它们可以测量脑电波的电荷强度。
6.Partial Discharge Measuring Based on Change of the Charge Density in Oil;基于油中电荷密度变化的局部放电测量
7.ζ Potentials and Pore Surface Charge Densities of the Porous Polymer Membranes (PMP-013MF Membrane);高分子MF膜的微孔表面ζ电位和电荷密度
8.Probability Density Function of Voltage Sag Sensitivity and Its Application敏感负荷电压凹陷敏感度概率密度函数及应用
9.220/20kV power supply scheme in high load density urban areas城市高负荷密度地区220/20kV供电方案研究
10.Density Functional Theory on the Charged Hard-sphere Fluid Confined in Parallel Plates平行硬壁间荷电硬球流体的密度泛函理论研究
11.Their antistatic performances were determined using methods of electrification voltage by friction and surface density of charge.采用摩擦起电电压法和电荷面密度法,对其进行了抗静电性能测试。
12.Ultrasonic welding of integrated circuits is of highest accurate.超声波焊接的集成电路,精密度极高。
13.Study of Charged Particle Rapidity Density and Charge Fluctuations as a Signature of QGP Formation;带电粒子快度密度与电荷起伏作为QGP信号的研究
14.Discussion of the Wall Current Contribution in the Rectangular Waveguide under TE_(10) Mode矩形波导中TE_(10)波面壁电流密度分布讨论
15.Research of Low Harmonic Power in High Power-density Electric-drive System;高功率密度电驱动系统低谐波电源技术研究
16.It was concluded that: ① the charge density decreases steadily from the end near the frontal electrode to the bomb tail;其结论是 :弹体电荷密度自靠近前电极的一端至弹尾逐步衰减 ;
17.Study on Preparation of Cationic/Amphoteric Polyelctrotyles with High Charge Density by Hofmann Reaction;Hofmann反应法制备高电荷密度阳离子型/两性型聚电解质的研究
18.The relation between the surface charge density of a charged ellipsoidal conductor and its principal radii带电导体椭球的面电荷密度与主曲率半径的关系
相关短句/例句
charge density-waves(CDW)电荷密度波(CDW)
3)charge density电荷密度
1.The method of synthesis of P-DADMAC,the factors such as dosage of initiator,reaction temperature,reaction time and nitrogen feeding,the relationship between relative molecular weight andcharge density,the effect of pH value on thecharge density were studied.探讨了引发剂用量、反应温度、反应时间、通氮气时间等因素对P-DADMAC相对分子质量的影响,以及相对分子质量和溶液pH值对电荷密度的影响;研究了P-DADMAC对浆料的助留助滤作用,以及作为阴离子杂质捕捉剂时与CPAM的协同作用。
2.The calculation of charge population,bond length and difference electric-charge density between Fe and Al atoms show that the bond between Fe and Al will be enhanced after doping th.结果表明:元素Zn、Mn、Ni都会优先替换界面处的Fe原子,使得界面结合能增加,体系更稳定,有利于界面的结合;跨界面的Fe原子与Al原子之间的电荷布居、键长以及差分电荷密度图的计算表明:掺杂后有利于跨界面的Fe-Al间成键,从而加强了Al层与Fe基体的结合,且结合强度由强到弱依次为:掺Zn>掺Mn>掺Ni;与实验比较吻合。
3.Using the extended Su-Schriffer-Heeger model,in real space,we calculate the electronic structure andcharge density of three systems,(9,0)-(8,0),(9,0)-(7,0) and (9,0)-(6,0),which are achieved by introducing topological defects (5/7) ,(5/6/7),and (5/6/6/7) in the perfect hexagonal network of the zigzag carbon nanotube configuration.在紧束缚近似基础上,利用扩展的SuSchrifferHeeger(SSH)模型,在实空间中计算了理想的“zigzag”碳纳米管中分别引入5/7,5/6/7,5/6/6/7拓扑缺陷所构成的(9,0)(8,0),(9,0)(7,0)和(9,0)(6,0)三种系统的能带结构和电荷密度,并对这三种系统的计算结果进行了比较。
4)electric charge density电荷密度
1.It tests the resistance of yarn and theelectric charge density of fabric on surface.将有机导电纤维与羊毛混纺制成纱线与织物,测试纱线电阻值及织物表面摩擦电荷密度,研究导电纤维含量、织物组织结构及纱线线密度对织物抗静电性能的影响。
5)charge density荷电密度
1.Method for obtaining thecharge density of nanofiltration membrane;一种求得纳滤膜荷电密度的快速方法
6)high charge density高电荷密度
1.This paper simply introduces the research and application onhigh charge density organic flocculant at home and abroad in the past twenty years,objectively and scientifically points out the problems and developing orientation of the research and manufacture inhigh charge density organic flocculant in our country.高电荷密度有机絮凝剂因其优良的絮凝性能和较宽的适用范围,受到了国内外众多研究者的重视与开发应用。
2.The fine paper containing bagasse chemical pulp and chemical wood pulp was sized with PAC modified cationic dispersed rosin size and AKD emulsion,andhigh charge density PAC was used as precipitating agent.结果表明,PAC及其复合物电荷密度对施胶有较大影响,在加入相同电荷量的PAC及其复合物时,高电荷密度PAC复合物比高纯PAC获得更高的施胶pH值和更满意的施胶度,PAC及其复合物改性阳离子松香胶对AKD的施胶有增效作用。
延伸阅读
电荷密度波电荷密度波Charge-density wave电荷密度波(charge—density Wa ve)在金属的基态,传导电子的电荷密度在空间受正弦调制。这个附加调制的周期与晶格周期无关,它由传导电子在动量空间的费米面的面积来决定。描述传导电子的电荷密度10。(,)一般与位置r有关,且具有与正离子晶格相同的空间周期性,具有电荷密度波(CI)w)的金属其电荷密度由式(1)给出:p(r’)=Po(r)[1+。pcos(Q·,+中)], (1)声是电荷密度波的振幅,其典型值约为o.1左右。传导电子的费米面决定电荷密度波的波矢Q。在动量空间,具有半径加的球形费米面的简单金属,其波矢可由式(2)近似给出:Q∽4砷F/^,(2)其中^是普朗克常量,虽然电荷密度波的波长与晶格常数比较接近,但二者之间却不存在什么确定的关系,因而可以说电荷密度波是不能通约的。在这样的情况下,金属的总能量与式(1)中的相位妒无关,参阅“费米面”(Fermi surface)条。起源 电子间的库仑相互作用常常使电荷密度波不稳定。这类贡献有二个,一个是泡利不相容原理引起的交换能,另一个是电子一电子散射引起的相关能。在电荷密度波存在时,这两个能量减少。但是,经典的静电能力图减小这种不稳定性,并将遏制住它的发生,如果正离子晶格不介入的话,参阅“不相容原理”(exclusion principle)条。晶格畸变设“(r)是正离子相对r处晶格的位移,则由式(3)给出的似波位移将产生正离子电荷密度,H(,)一Asin[Q·r+咖。(3)后者与电荷密度波的电子电荷调制相抵消,位移振幅的典型值是A~10。。一lO_1。米。为达到这点,离子与离子间的相互作用必须很小。由此看来,具有较小弹性模量的金属更易出现电荷密度波。检测在单晶x射线散射实验中,在每个布拉格(Bragg)反射的左右两边可观察到二个较小的次反射信号,便是电荷密度波的明显示例。此现象的起因是式(3)的晶格位移。这类实验首先是在金属二硫化钽(Tasz)和二硒化钽(TaSe2)上完成的。它们有三个电荷密度波,Q在六角形平面中彼此夹角120。,当温度降低时,可观察到从不可约到可约的跃迁Q,。届时电荷密度波的长度是某个晶格周期的整数倍。参阅“X射线衍射”(x—ray diffraction)条。费米面的作用对传导电子能谱有影响的周期势场导致电荷密度波以自持形式出现。如果原始的费米面与简单的,例如球面相连,它可能会出现畸变,并扩大联接的范围。具有立方对称性的金属取得一个电荷密度波的话,其电子的性质将变得非常的各向异性和反常。扩大联系的费米面在低温磁阻效应中可出现引人注目的现象。
