Cr掺杂ZnS纳米管结构和磁性质（英文）

采用第一性原理密度泛函理论系统研究Cr原子单掺杂和双掺杂单壁Zn S纳米管的结构和磁性质.研究发现掺杂纳米管的形成能比纯纳米管的形成能低,说明掺杂过程是放热的.单掺杂纳米管的总磁矩主要来自Cr原子3d态的贡献.结果表明Cr原子掺杂单壁Zn S纳米管趋向于铁磁态.但铁磁态和反铁磁态的能量差仅为0.036 e V.为获得室温铁磁性,我们用一个C原子替代掺杂体系中的一个S原子.计算发现铁磁态的能量比反铁磁态低0.497e V.表明此掺杂体系可能获得室温铁磁性.     

Fe掺杂单壁ZnS纳米管磁性质

采用第一性原理密度泛函理论系统研究Fe原子掺杂单壁ZnS纳米管的结构和磁性质.首先比较掺杂纳米管的稳定性.结果表明,掺杂纳米管的形成能比纯纳米管的形成能低,说明掺杂过程是一个放热反应.单掺杂纳米管的总磁矩等于掺杂的磁性原子的磁矩,主要来自Fe原子3d态的贡献.Fe原子掺杂单壁ZnS纳米管趋向于反铁磁态.为了得到稳定的铁磁态,用一个C原子替代掺杂体系中的一个S原子.计算发现铁磁态的能量比亚铁磁态低0.164 eV的.在铁磁态和反铁磁态之间存在的巨大的能量差,表明此掺杂体系可能获得室温铁磁性.     

Mn/C共掺杂ZnS纳米管磁性质研究

采用第一性原理密度泛函理论系统地研究Mn原子单掺杂和双掺杂ZnS纳米管的结构、电子性质和磁性质.掺杂纳米管的形成能比纯纳米管形成能更低,表明掺杂是个放热过程.掺杂纳米管的能隙远小于纯纳米管能隙.计算结果表明Mn掺杂纳米管趋于反铁磁态.为了获得室温铁磁性,用一个C原子替代一个S原子.发现铁磁态能量比反铁磁态能量低0.454 eV.如此大的能量差表明这类材料中有可能获得室温铁磁性.     

Mn/C共掺杂ZnS纳米管磁性质研究（英文）

采用第一性原理密度泛函理论系统地研究Mn原子单掺杂和双掺杂ZnS纳米管的结构、电子性质和磁性质.掺杂纳米管的形成能比纯纳米管形成能更低,表明掺杂是个放热过程.掺杂纳米管的能隙远小于纯纳米管能隙.计算结果表明Mn掺杂纳米管趋于反铁磁态.为了获得室温铁磁性,用一个C原子替代一个S原子.发现铁磁态能量比反铁磁态能量低0.454 e V.如此大的能量差表明这类材料中有可能获得室温铁磁性.     

Cr掺杂ZnO纳米线电子性质和磁性质

本文采用第一性原理密度泛函理论系统的研究了Cr原子单掺杂和双掺杂两种尺寸ZnO纳米线的电子性质和磁性质.所有掺杂纳米线的形成能都比纯纳米线的形成能低,表明掺杂增强了纳米线的稳定性.研究发现Cr原子趋于替代纳米线表面的Zn原子.所有掺杂纳米线都显示了金属性.纳米线的总磁矩主要来源于Cr原子3d轨道的贡献.由于杂化,相邻的O原子和Zn原子也产生了少量自旋.在超原胞内,Cr和O原子磁矩反平行排列,表明它们之间是反铁磁耦合.表面双掺杂纳米线铁磁态能量比反铁磁态能量低149 meV,表明Cr掺杂ZnO纳米线可能获得室温铁磁性.     

V,Cr,Mn掺杂MoS2磁性的第一性原理研究

基于第一性原理的自旋极化密度泛函理论分别研究了过渡金属V, Cr, Mn掺杂单层MoS₂的电子结构、 磁性和稳定性. 结果表明: V和Mn单掺杂均能产生一定的磁矩, 而磁矩主要集中在掺杂的过渡金属原子上, Cr单掺杂时体系不显示磁性. 进一步讨论双原子掺杂MoS₂ 体系中掺杂原子之间的磁耦合作用发现, Mn掺杂的体系在室温下显示出稳定的铁磁性, 而V掺杂则表现出非自旋极化基态. 形成能的计算表明Mn掺杂的MoS₂体系相对V和Cr 掺杂结构更稳定. 由于Mn掺杂的MoS₂ 不仅在室温下可以获得比较好的铁磁性而且其稳定性很高, 有望在自旋电子器件方面发挥重要的作用. 关键词： 2')" href="#">单层MoS₂ 掺杂 铁磁态 第一性原理     

C掺杂ZnO纳米线的磁性研究

运用第一性原理方法研究了C掺杂ZnO纳米线的电子性质和磁性质.研究发现C原子趋于替代纳米线表面的O原子.所有掺杂纳米线显示了半导体特性.纳米线的总磁矩主要来源于C原子2p轨道的贡献.由于杂化,相邻的Zn原子和O原子也产生了少量自旋.在超原胞内,C、Zn和O原子磁矩平行排列,表明它们之间是铁磁耦合.铁磁态和反铁磁态的能量差达到了186meV,表明C掺杂ZnO纳米线可能存在室温铁磁性,在自旋电子学领域有很大应用前景.     

Zn1-xMnxS(001)稀磁半导体薄膜的能量稳定性、磁性和电子结构

通过基于广义梯度近似的总能密度泛函理论研究不同Mn掺杂浓度的ZnS(001)薄膜的电学和磁学特性. 计算单个Mn原子和两个Mn原子处于各种掺杂位置及不同的磁耦合状态时的能量稳定性.计算了单个Mn原子掺杂和两个Mn原子掺杂的ZnS(001)薄膜的态密度. 不同掺杂组态的p-d杂化的程度不同. 不同掺杂组态,Mn原子所处的晶场环境不同,所以不同掺杂组态的Mn的3d分波态密度峰的劈裂有很大的不同. 掺杂两个Mn原子时,得到三种稳定组态的基态都是反铁磁态. 分析了以上三种能量稳定的组态中,两个Mn原子在不同磁耦合状态下的3d态密度图. 当两原子为铁磁耦合时,由于d-d电子相互作用,使反键态的态密度峰明显加宽. 随着Mn掺杂浓度的增加,Mn原子有相互靠近,并围绕S原子形成団簇的趋势. 对于这样的组态,Mn原子之间为反铁磁耦合能量更低.     

过渡金属(Cr,Mn,Fe,Co)掺杂对TiO_2磁性影响的第一性原理研究

关于过渡金属掺杂TiO_2是否会产生室温铁磁性及其磁性的来源存在争议,为了解决此问题,本文采用基于密度泛函理论下的GGA+U方法对体系Ti_(0.875)X_(0.125)O_2 (X=Cr,Mn,Fe,Co)的磁学性质及光学性质进行了第一性原理的研究.首先计算了铁磁和反铁磁的基态能量,比较后推测出铁磁态为它们的基态;分析能带结构发现Ti_(0.875)Cr_(0.125)O_2和Ti0.875Mn_(0.125)O_2两种体系保持半导体性质,Ti_(0.875)Fe_(0.125)O_2和Ti_(0.875)Co_(0.125)O_2两种体系表现金属特性;掺杂体系都产生了室温铁磁性,磁性来源主要是过渡金属元素(Cr,Mn,Fe,Co)3d电子轨道诱导极化了周围的O-2p态自旋电子,导致体系产生净磁矩而呈现铁磁性;掺杂体系的吸收光谱均发生了红移,有效扩展了对可见光的吸收范围.     

二氧化铈基稀磁氧化物的第一性原理研究

基于第一性原理的计算方法研究了纯CeO_2、Co掺杂CeO_2和同时引入氧空位Vo和Co掺杂的CeO_2稀磁半导体体系.通过计算体系的能带结构和态密度,探讨了该体系磁性产生的机制.计算发现,纯CeO_2体系不具有磁性;没有氧空位Vo的Co掺杂CeO_2体系中,Co离子之间通过O原子发生超交换反铁磁耦合,体系无铁磁性;当氧空位Vo和Co离子同时存在于CeO_2体系中时,Co离子之间通过氧空位Vo发生铁磁耦合,该体系表现出铁磁性能.另外,由氧空位Vo诱导的Co离子之间的铁磁耦合不仅发生在紧邻的两个Co离子,而且可以扩展到几个原子距离的长度.计算结果证明了氧空位Vo诱导铁磁性耦合机制.本文工作将为CeO_2基稀磁半导体体系制备与磁学性质的研究提供支持.     

First-principle study on magnetic properties of Mn/Fe codoped ZnS

We studied the magnetic properties of Mn/Fe codoped ZnS comparatively with and without defects using first-principle calculation. The calculated results indicate that the Mn/Fe codoped ZnS system tends to stabilize in a ferrimagnetic (FiM) configuration. To obtain a ferromagnetic (FM) configuration, we consider the doped system with defects, such as S or Zn vacancy. The calculated results indicate that the doped system with Zn vacancy favors FiM states. Although the FM states of the doped system with S vacancy are more stable than the FiM states in negative charge states, the FM states are not stable enough to exist. Finally, we replaced an S atom by a C atom in the doped system. The C atom prefers to substitute the S atom connecting Mn and Fe atoms. The formation energy of this defect is −0.40 eV, showing that Mn/Fe/C codoped ZnS can be fabricated easily by experiments. Furthermore, the FM state was lower in energy than the FiM state by 114 meV. Such a large energy difference between the FM and FiM states implies that room temperature ferromagnetism could be expected in such a system.     

First-principles study on the magnetic property of C-doped wurtzite ZnS

We have studied the structure, electronic and magnetic properties of wurtzite (WZ) ZnS semiconductor doped with one or two C atoms using first-principles calculations. The moderate formation energy implied that C-doped ZnS could be fabricated experimentally. The total magnetic moment of the 72 atom super cell was 2.02μB, mainly due to the 2p component of the C atom. Electronic structures showed ZnS doped with C atom was p-type half-metallic ferromagnetic (FM) semiconductor and hole mediation was responsible for the ferromagnetism. The large energy difference (154 meV) between the FM and antiferromagnetic (AFM) state implied room-temperature ferromagnetism for C-doped WZ ZnS, which has great potential in spintronic devices.     

Structure, electronic and magnetic properties of Cr-doped (ZnS)12 clusters: A first-principles study

We have studied the structural, electronic, and magnetic properties of (ZnS)₁₂ clusters doped with one (monodoped) and two (bidoped) Cr atoms in terms of a first-principles method. Substitutional, exohedral, and endohedral doping are considered. The substitutional isomer is found to be most favorable in energy for monodoped clusters, while the exohedral isomers are found to be most favorable for bidoped clusters. The magnetic coupling between the Cr atoms is mainly governed by the competition between direct Cr-Cr antiferromagnetic (AFM) interaction and the ferromagnetic (FM) interaction between two Cr atoms via S atom due to strong p-d hybridization. Finally, we show that the exohedral bidoped (ZnS)₁₂ clusters favor the FM state, which has potential applications in nanoscale quantum devices.     

Ferromagnetic properties of Cu-doped ZnS: A density functional theory study

Using plane-wave pseudopotential (PWPP) method, the magnetism and spin-resolved electronic properties of Cu-doped ZnS system are studied. Our calculations indicate that ferromagnetic (FM) state is ground state in Cu-doped ZnS. The FM coupling strength in ZnS doping with Cu fluctuates with the variation of distance between two dopants and the fluctuation gets larger with increase in distance. Room temperature ferromagnetism can be observed in Cu-doped ZnS with high dopant concentration. Formation energy calculation implies that the clustering effect is not obvious in Cu-doped ZnS. Thus, Cu-doped ZnS can be a promising dilute magnetic semiconductor (DMS), which promises to be free of magnetic precipitates.     

Room temperature ferromagnetism in Cu–Gd co-doped GaN nanowires: A first-principles study

The electronic structure and room temperature ferromagnetism of wurtzite Cu–Gd co-doped GaN nanowires have been investigated by means of the first-principles calculations within the density functional theory, including the on-site Coulomb energy U. The magnetic coupling between Gd atoms in the Gd-doped GaN nanowire is paramagnetic instead of ferromagnetic (FM) as in the bulk structure. After replacing Ga with Cu atom we find a stable FM coupling between Gd magnetic moments in this p-type system. p–d coupling between Cu-3d and N-2p states pushes N-2p states up to Fermi level due to the existence of hole states introduced by Cu dopants. While the p–d coupling between host N-2p and Gd-5d states near Fermi level stabilizes a FM phase of Gd magnetic moments. Furthermore, we get a FM state above room temperature by increasing the holes concentration.     

利用第一性原理研究Ni掺杂ZnO铁磁性起源

采用基于密度泛函理论和局域密度近似的第一性原理分析了Ni掺杂ZnO磁性质.文中计算了8个不同几何结构的铁磁(FM)和反铁磁耦合能量,结果表明FM耦合更稳定.态密度结果显示Ni 3d 与O 2p发生杂化,导致费米能级附近电子态自旋极化.文中也分析了O空位对Ni掺杂ZnO铁磁性质的影响,O空位通过诱导电子调节FM耦合,从而稳定Ni掺杂ZnO铁磁性质,其强度足以引发室温铁磁性.通过Ni 3d能级耦合具体分析了Ni 掺杂ZnO铁磁性起源.另外,也分析了晶格应变对Ni掺杂ZnO FM耦合的影响. 关键词： 第一性原理 半导体 铁磁性 缺陷     

ZnS(111)表面掺杂Mn的电子结构和磁性的第一性原理研究

应用基于密度泛函理论的第一性原理,研究Mn原子掺杂在ZnS(111)表面的电子结构和磁性.对于单原子的掺杂组态,替位表面第一层的Zn原子时体系形成能最低,说明该层是最稳定的掺杂位置.体系总磁矩取决于Mn原子的局域环境.而对于双掺杂组态,当Mn与Mn之间呈短程铁磁耦合作用时体系最稳定.这可由Mn原子和近邻S原子的p-d杂化作用解释.此时,体系的居里温度估算值为469 K,明显高于室温,具有理论指导意义.Mn原子和受主半导体之间的相互作用是自旋极化产生的主要原因.计算结果表明,该掺杂材料可以很好的用来制作稀磁半导体,具有良好的应用前景.     

Origin of charge density wave formation in insulators from a high resolution photoemission study of BaIrO3

We investigate the origin of charge density wave (CDW) formation in insulators by studying BaIrO3 using high-resolution (1.4 meV) photoemission spectroscopy. The spectra reveal the existence of localized density of states at the Fermi level, E(F), in the vicinity of room temperature. These localized states are found to vanish as the temperature is lowered, thereby, opening a soft gap at E(F), as a consequence of CDW transition. In addition, the energy dependence of the spectral density of states reveals the importance of magnetic interactions, rather than well-known Coulomb repulsion effect, in determining the electronic structure thereby implying a close relationship between ferromagnetism and CDW observed in this compound. Also, Ba core level spectra surprisingly exhibit an unusual behavior prior to CDW transition.