Landrum GA, Dronskowski R
Institut für Anorganische Chemie Rheinisch-Westfälische Technische Hochschule Prof.-Pirlet-Strasse 1, 52056 Aachen (Germany).
Angew Chem Int Ed Engl. 2000 May;39(9):1560-1585. doi: 10.1002/(sici)1521-3773(20000502)39:9<1560::aid-anie1560>3.0.co;2-t.
A chemical view of spin magnetic phenomena in finite (atoms and molecules) and infinite (transition metals and their alloys) systems using the concepts of bonding and electronic shielding is presented. The concept is intended to serve as a semiquantitative signpost for the synthesis of new ferromagnets. After a concise overview of the historic development of related theories developed within the physics community, the consequences of spin-spin coupling (made manifest in the exchange or Fermi hole) in atoms and molecules are explored. Upon moving to a paramagnetic state, the majority/minority spin species become more/less tightly bound to the nucleus, resulting in differences in the energies and spatial extents of the two sets of spin orbitals. By extrapolating well-known arguments from ligand-field theory, the paucity of ferromagnetic transition metals arises from quenching the paramagnetism of the free atoms due to strong interatomic interactions in the solid state. Critical valence electron concentrations in Fe, Co, and Ni, however, result in local electronic instabilities due to the population of antibonding states at the Fermi level varepsilon(F). Removal of these antibonding states from the vicinity of varepsilon(F) is the origin of ferromagnetism; in the pure metals this results in strengthening the chemical bonds. In the 4d and 5d transition metals, the valence d orbitals are too well shielded from the nucleus, so a transition to a ferromagnetic state does not result in sufficiently large changes to occur. Thus, the exceptional occurence of ferromagnetism only in the first transition series appears to parallel the special main-group chemistry of the first long period. A connection between ferromagnetism in the transition metals and Pearson's absolute hardness eta is easily established and shows that ferromagnetism appears only when eta<0.2 eV in the nonmagnetic calculation. As expected from the principle of maximum hardness, Fe, Co, and Ni all become harder upon moving to the more stable ferromagnetic state. Magnetism in intermetallic alloys follows the same path. Whether or not an alloy contains ferromagnetic elements, the presence of antibonding states at varepsilon(F) serves as a "fingerprint" to indicate a ferromagnetic instability. The differences in the sizes of the local magnetic moments on the constituent atoms of a ferromagnetic alloy can be understood in terms of the relative contributions to the density of states at varepsilon(F) in the nonmagnetic calculations. Appropriately parameterized, nonmagnetic, semi-empirical calculations can also be used to expose the ferromagnetic instability in elements and alloys. These techniques, which have become relatively commonplace, can be used to guide the synthetic chemist in search of new ferromagnetic materials.
本文利用键合和电子屏蔽的概念,对有限体系(原子和分子)和无限体系(过渡金属及其合金)中的自旋磁现象进行了化学视角的阐述。该概念旨在为新型铁磁体的合成提供一个半定量的指引。在简要回顾了物理学界相关理论的历史发展之后,探讨了原子和分子中自旋 - 自旋耦合(表现为交换或费米空穴)的后果。当进入顺磁状态时,多数/少数自旋态与原子核的结合变得更紧密/更松散,导致两组自旋轨道的能量和空间范围出现差异。通过外推配体场理论中的著名论点可知,由于固态中强烈的原子间相互作用使自由原子的顺磁性猝灭,导致铁磁过渡金属数量稀少。然而,铁、钴和镍中的临界价电子浓度会由于费米能级ε(F)处反键态的占据而导致局部电子不稳定。从ε(F)附近去除这些反键态是铁磁性的起源;在纯金属中,这会导致化学键增强。在4d和5d过渡金属中,价d轨道受到原子核的屏蔽作用过强,因此向铁磁态的转变不会导致足够大的变化发生。因此,铁磁性仅在第一过渡系中出现这一特殊情况似乎与第一长周期中特殊的主族化学现象相平行。过渡金属中的铁磁性与皮尔逊绝对硬度η之间很容易建立联系,结果表明在非磁性计算中,仅当η<0.2 eV时才会出现铁磁性。正如最大硬度原理所预期的那样,铁、钴和镍在转变为更稳定的铁磁态时都会变得更硬。金属间合金中的磁性遵循相同的规律。无论合金是否包含铁磁元素,ε(F)处反键态的存在都可作为表明铁磁不稳定性的“指纹”。铁磁合金中组成原子上局部磁矩大小的差异可以根据非磁性计算中对ε(F)处态密度的相对贡献来理解。经过适当参数化的非磁性半经验计算也可用于揭示元素和合金中的铁磁不稳定性。这些技术如今已相对常见,可用于指导合成化学家寻找新型铁磁材料。
