M. T. Barriuso scite author profile

This article reviews the microscopic origin of properties due to transition-metal (TM) impurities, M, in insulator materials. Particular attention is paid to the influence of pressure upon impurity properties. Basic concepts such as the electronic localization in an MX(N) complex, the electrostatic potential, V(R), arising from the rest of the lattice ions or the elastic coupling of the complex to the host lattice are initially exposed. The dependence of optical and magnetic parameters on the impurity-ligand distance, R, in cubic lattices is discussed in a first step. Emphasis is put on the actual origin of the R dependence of 10Dq. Examples revealing that laws for strict cubic symmetry cannot in general be transferred to lower symmetries are later given. This relevant fact is shown to come from allowed hybridizations like nd-(n+1)s as well as the influence of V(R). As a salient feature the different colour in ruby and emerald is stressed to arise from distinct V(R) potentials in Al(2)O(3) and Be(3)Si(6)Al(2)O(18). The last part of this review deals with electronic instabilities. The phenomena associated with the Jahn-Teller (JT) effect in cubic lattices, the origin of the energy barrier among equivalent minima and the existence of coherent tunnelling in systems like MgO:Cu(2+) are discussed. An increase of elastic coupling is pointed out to favour a transition from an elongated to a compressed equilibrium conformation. Interestingly the equilibrium geometry of JT ions in non-cubic lattices is shown to be controlled by mechanisms different to those in cubic systems, V(R) playing again a key role. The relevance of first principles calculations for clarifying the subtle mechanisms behind off-centre instabilities is also pointed out. Examples concern monovalent and divalent TM impurities in lattices with the CaF(2) structure. The instability due to the transition from the ground to an excited state is finally considered. For complexes with significant elastic coupling vibrational frequencies and the Stokes shift are expected to undergo bigger changes through a chemical rather than a hydrostatic pressure. The reduction of Huang-Rhys factors upon increasing the pressure is discussed as well.

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Cu²⁺ in Layered Compounds: Origin of the Compressed Geometry in the Model System K₂ZnF₄:Cu²⁺

Aramburu

et al. 2013

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Many relevant properties (including superconductivity and colossal magnetoresistance) of layered materials containing Cu(2+), Ag(2+), or Mn(3+) ions are commonly related to the Jahn-Teller instability. Along this line, the properties of the CuF6(4-) complex in the K2ZnF4 layered perovskite have recently been analyzed using a parametrized Jahn-Teller model with an imposed strain [Reinen, D. Inorg. Chem.2012, 51, 4458]. Here, we present results of ab initio periodic supercell and cluster calculations on K2ZnF4:Cu(2+), showing unequivocally that the actual origin of the unusual compressed geometry of the CuF6(4-) complex along the crystal c axis in that tetragonal lattice is due to the presence of an electric field due to the crystal surrounding the impurity. Our calculations closely reproduce the experimental optical spectrum. The calculated values of the equilibrium equatorial and axial Cu(2+)-F(-) distances are, respectively, R(ax) = 193 pm and R(eq) = 204 pm, and so the calculated distortion R(ax) - R(eq) = 11 pm is three times smaller than the estimated through the parametrized Jahn-Teller model. As a salient feature, we find that if the CuF6(4-) complex would assume a perfect octahedral geometry (R(ax) = R(eq) = 203 pm) the antibonding a(1g)*(∼3z(2) - r(2)) orbital is placed above b(1g)*(∼x(2) - y(2)) with a transition energy E((2)A(1g) → (2)B(1g)) = 0.34 eV. This surprising fact stresses that about half the experimental value E((2)A(1g) → (2)B(1g)) = 0.70 eV is not due to the small shortening of the axial Cu(2+)-F(-) distance, but it comes from the electric field, E(R)(r), created by the rest of the lattice ions on the CuF6(4-) complex. This internal field, displaying tetragonal symmetry, is thus responsible for the compressed geometry in K2ZnF4:Cu(2+) and the lack of symmetry breaking behind the ligand relaxation. Moreover, we show that the electronic energy gain in this process comes from bonding orbitals and not from antibonding ones. The present results underline the key role played by ab initio calculations for unveiling all the complexity behind the properties of the model system K2ZnF4:Cu(2+), opening at the same time a window for improving our knowledge on d(9), d(7), or d(4) ions in other layered compounds.

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Spectrochemical Series and the Dependence of Racah and 10Dq Parameters on the Metal−Ligand Distance: Microscopic Origin

et al. 2011

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The origin of the spectrochemical series and the different dependence of crystal-field splitting (10Dq) and Racah parameters on the metal-ligand distance, R, is explored through ab initio calculations on Cr(3+)-doped K2NaScF6, Cs2NaYCl6, Cs2NaYBr6, and Cs2NaYI6 lattices. For this purpose both periodic and cluster calculations have been performed. An analysis of ab initio results proves that 10Dq values mostly come from the small admixture of deep nLs ligand orbitals present in the antibonding eg(∼ x(2)-y(2),3z(2)-r(2)) level and not from the dominant covalency with valence nLp ligand orbitals, which is actually responsible for the reduction of Racah parameters. This study thus reveals the microscopic origin of the stronger dependence upon R of 10Dq when compared to that observed for Racah parameters, thus explaining why electronic transitions which are 10Dq-independent give rise to sharp optical bands. As a salient feature, while the covalency with nLp levels increases significantly on passing from CrF6(3-) to CrI6(3-), the nLs admixture in eg is found to be practically unmodified. This fact helps to understand the progressive decrease of 10Dq through the series of CrF6(3-), CrCl6(3-), CrBr6(3-), and CrI6(3-) complexes embedded in the corresponding host lattices when compared at the corresponding equilibrium distance at zero pressure. The growing importance of the nLs admixture is well-depicted using deformation density diagrams on passing from the ground state (4)A2(t2g(3)) to the (4)T2(t2g(2)eg) excited state depicted at several R values.

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Dynamic and Static Jahn-Teller Effect in Impurities: Determination of the Tunneling Splitting

García‐Fernández

Trueba

Barriuso

et al. 2011

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The Huang-Rhys factor S(a_1g) for transition-metal impurities: a microscopic insight

Moreno¹,

Barriuso²,

Aramburu³

1992

J. Phys.: Condens. Matter

110

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AbsIracL A micmsmpic model for evaluating the Huang-Rhys factor S(at8) associated with the symmetric mode of a transition-metal impurity M in insulators is p r o p e l . It is applied Io the first excited states of C?+, Vz+, Mnz+ and Cuz+. If lODq is proportional to R-" (R is the metal-ligand distance) it is shown that S(a1,) is proportional to n' as well as lo [w(al8)]-'. Theoretical calculated values of the exponent n indicate that it varies slightly along the ligand series F-+ C1--+ Br-giving rise to an i n c r r m in S(alg). This expiains why the Stokes shift of systems involving M B ~N unib can be similar or higher than the corresponding shifb of MFN complexes The calculated values of S(alg) are reasonably cl-Io available experimental estimations and support the fact that the wntibution of the at, mode to the Stokes shift is between 50 and 70% for CrX2-(X 5 halides) wmplexes while it is smaller than 40% for the wrrerponding systems involving Mn2+.The dependence of S(a1,) on R is alw analysed, leading to an increase in S(a1,) upon increasing R. This lrend which has been directly verified for Vz+ in chlorides can also explain the increase in the Stokes shift observed experimentally when R is increased.

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M. T. Barriuso

Microscopic insight into properties and electronic instabilities of impurities in cubic and lower symmetry insulators: the influence of pressure

Cu²⁺ in Layered Compounds: Origin of the Compressed Geometry in the Model System K₂ZnF₄:Cu²⁺

Spectrochemical Series and the Dependence of Racah and 10Dq Parameters on the Metal−Ligand Distance: Microscopic Origin

Dynamic and Static Jahn-Teller Effect in Impurities: Determination of the Tunneling Splitting

The Huang-Rhys factor S(a_1g) for transition-metal impurities: a microscopic insight

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M. T. Barriuso

Microscopic insight into properties and electronic instabilities of impurities in cubic and lower symmetry insulators: the influence of pressure

Cu2+ in Layered Compounds: Origin of the Compressed Geometry in the Model System K2ZnF4:Cu2+

Spectrochemical Series and the Dependence of Racah and 10Dq Parameters on the Metal−Ligand Distance: Microscopic Origin

Dynamic and Static Jahn-Teller Effect in Impurities: Determination of the Tunneling Splitting

The Huang-Rhys factor S(a1g) for transition-metal impurities: a microscopic insight

Contact Info

Product

Resources

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Cu²⁺ in Layered Compounds: Origin of the Compressed Geometry in the Model System K₂ZnF₄:Cu²⁺

The Huang-Rhys factor S(a_1g) for transition-metal impurities: a microscopic insight