石墨烯基磁量子环的低态能谱对磁场的依赖关系(英文)

Magnetic-field dependence of low-lying spectra of graphene-based magnetic ring

导出

摘要我们采用狄拉克-韦尔(Dirac-Weyl)模型,计算出二维石墨烯基磁量子环和磁量子点分别在垂直非均匀磁场下的低态能谱,并讨论包括两组旋量分量的低态能谱跟磁场的依赖关系。从直接对角计算法所获得的数值结果表明,在非均匀磁场下,磁量子点和磁量子环的能谱中的最低朗道能级(N-=0)皆为高度简并,且数值恒等为零。在其邻近较高的朗道能级,磁量子环出现了由磁场诱导的轨道角动量间的跃迁,而磁量子点则没有。最后本文指出,除了最低朗道能级(N-=0)外,两组旋量分量的能谱完全一样,只是其朗道能级所标记的两组量子数不同而已。 Using the Dirac-Weyl model, we present the magnetic-field dependence of low-lying spectra of two-dimensional graphene-based magnetic dot and ring, including both spinor components, creating from perpendicular inhomogeneous magnetic fields. Numerical results obtained from direct diagonalization show that, under inhomogeneous magnetic fields, the lowest Landau level （ N^[-]= 0 ） is highly degenerate at zero energy, and for the other higher neighboring Landau levels, there exist angular momentum transitions in- duced by magnetic fields for the magnetic ring but not for the magnetic dot. Furthermore, the low-lying spectra for both spinor components, except for N-= 0, are exactly the same only with the states labeled by different sets of quantum numbers.

作者李泽民阮文英刘玉龙

机构地区中国科学院物理研究所美国佐治亚理工学院物理学院

出处《光散射学报》北大核心 2012年第1期48-52,共5页 The Journal of Light Scattering

基金国家自然科学基金(10674171)

关键词石墨烯磁量子环磁量子点 graphenel magnetic ringl magnetic dot

分类号 O469 [理学—凝聚态物理] O481.1 [理学—固体物理]

引文网络
相关文献

参考文献15

1Novoselov K S,Geim A K,Morozov S V. Electric field effect in atomically thin carbon films[J].Science,2004.666-669.
2Berger C,Song Z M,Li T B. Ultrathin epitaxial graphite:? 2D electron gas properties and a route toward graphene-based nanoelectronics[J].Journal of Physical Chemistry B,2004,(52):19912-19916.doi:10.1021/jp040650f.
3Beenakker C W J. Colloquium:andreev reflection and Klein tunneling in graphene[J].Reviews of Modern Physics,2008.1337-1354.
4Castro Neto A H,Guinea F,Peres N M R. The electronic properties of graphene[J].Reviews of Modern Physics,2009,(1):109-162.doi:10.1103/RevModPhys.81.109.
5Abergel D S L,Apalkov V,Berashevich J. Properties of graphene:a theoretical perspective[J].Advances in Physics,.
6Goerbig M O. Electronic properties of graphene in a strong magnetic field[J].Reviews of Modern Physics,2011.1193-1243.
7Semenoff G W. Condensed-matter Simulation of a three-dimensional anomaly[J].Physical Review Letters,1984.2449-2452.doi:10.1103/PhysRevLett.53.2449.
8DiVincenzo D P,Mele E J. Self-consistent effective-mass theory for intralayer screening in graphite intercalation compounds[J].Physical Review B:Condensed Matter,1984.1685-1694.
9Bending S J,yon Klitzing K,Ploog K. Weak localization in a distribution of magnetic flux tubes[J].Physical Review Letters,1990.1060-1063.
10shnan K M. Ferromagnetic δ-Mn1-xGax thin films with perpendicular anisotropy[J].Applied Physics Letters,1992.2365.doi:10.1063/1.108245.

1姚志东,陆肖励.圆盘锯齿型石墨烯量子点的电子结构研究[J].长春大学学报,2011,21(6):61-64.
2姚志东,李炜,高先龙.点缺陷扶手型石墨烯量子点的电子性质研究[J].物理学报,2012,61(11):449-454. 被引量：1
3李鑫,冯小波,李志松.圆盘形石墨烯量子点电子能态的尺寸效应[J].云南师范大学学报（自然科学版）,2016,36(1):53-58.
4郑国珍,韦亚一,郭少令,汤定元.浅施主杂质态在n－Hg_（1－x）Cd_xTe磁致金属－绝缘体相变中的作用[J].Journal of Semiconductors,1995,16(7):497-502.
5王国栋.磁量子数m取值变化与元素周期表重排[J].科技资讯,2008,6(12). 被引量：1
6秦国毅,P.N.Butcher,T.M.Fromhold.硅反型层中热功率的磁量子振荡[J].Journal of Semiconductors,1993,14(10):597-604.
7陈硕,李定平,林宏烨,儒森斯坦.蒙特卡罗方法模拟无序涡旋系统中的相图[J].北京大学学报（自然科学版）,2009,45(6):941-946.
8XU Qin-Feng CHENG Ze.Quasiprobability Distribution of Squeezed Thermal Spin States in Ferromagnet[J].Communications in Theoretical Physics,2008,49(3):777-782.
9惠萍.氢分子离子的平衡距离随外磁场强度的变化[J].广东第二师范学院学报,2014,34(3):39-42.
10杨仕清,张万里,龚捷,王豪才,何世光.纳米晶Nd-Fe-B基稀土永磁体的磁性能的微磁量子理论计算[J].原子与分子物理学报,1997,14(3):445-450. 被引量：3

光散射学报

2012年第1期

浏览历史

内容加载中请稍等...

石墨烯基磁量子环的低态能谱对磁场的依赖关系(英文)

参考文献15

相关作者

相关机构

相关主题

浏览历史