Pressure-driven collapse of the relativistic electronic ground state in a honeycomb iridate

Clancy, J. P.; Gretarsson, H.; Sears, Jennifer; Singh, Yogesh; Desgreniers, Serge; Mehlawat, Kavita; Layek, Samar; Rozenberg, G. Kh.; Ding, Yang; Upton, M. H.; Casa, D.; Chen, Ning; Im, Junhyuck; Lee, Yong Jae; Yadav, Ravi; Hozoi, Liviu; Efremov, D. V.; Brink, Jeroen van den; Kim, Yong Baek

doi:10.1038/s41535-018-0109-0

Cited by 49 publications

(64 citation statements)

References 45 publications

(51 reference statements)

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“…We first consider α‐Li 2 IrO 3 . The pressure effects in this system has been studied experimentally by X‐ray diffraction measurements with synchrotron radiation and more recently by other X‐ray techniques . These studies reveal that α‐Li 2 IrO 3 undergoes a transition from the monoclinic phase (

C 2 / m

space group) to a lower symmetry triclinic phase (

P \overset{1}{true}

space group) at the critical pressure

P_{c} = 3.8 GPa

.…”

Section: Resultsmentioning

confidence: 99%

“…Details of the interplay between electronic correlations ( U ), spin‐orbit coupling (SOC) effects, magnetism and covalent bonding in α‐Li 2 IrO 3 have been explored by DFT simulations and quantum chemistry calculations . Two competing interactions controlling the structural transition at finite pressure are (a) the energy gain due to the local moment formation and (b) the dimerization and the consequent quenching of local moments.…”

Section: Resultsmentioning

confidence: 99%

“…it is possible to steer the systems through various phase transitions in a controlled way. As a matter of fact, this technique has proven to be utterly useful to uncover the nature of quantum phases, such as a Mott insulator, spin liquid, correlated metal, multiferroic, or unconventional superconductor . Materials where such a tuning parameter is very effective are, for instance, organic charge transfer salts, where, due to the softness of the organic components, small pressures induce large changes in the electronic properties of the materials giving rise to complex phase diagrams .…”

Section: Introductionmentioning

confidence: 99%

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Microscopic Modeling of Correlated Systems Under Pressure: Representative Examples

Borisov

Biswas

et al. 2019

Physica Status Solidi (b)

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The complex interplay between different order parameters in correlated systems can be finely tuned by mechanical pressure giving access to a variety of distinct phases and thereby providing new functionalities. This review addresses the challenges in the state‐of‐the‐art theoretical simulations of pressure‐induced phenomena on a few representative examples of correlated systems that are currently in the focus of on‐going contemporary research. These include organic charge‐transfer multiferroics, unconventional iron‐based superconductors, frustrated quantum magnets, and candidate systems for Kitaev physics. All these systems show pronounced structural response to moderate pressures or even structural transitions to new phases which can be successfully addressed from first principles. The simulation techniques and general trends in pressure effects are discussed for each material class.

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C 2 / m

space group) to a lower symmetry triclinic phase (

P \overset{1}{true}

space group) at the critical pressure

P_{c} = 3.8 GPa

.…”

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Microscopic Modeling of Correlated Systems Under Pressure: Representative Examples

Borisov

Biswas

et al. 2019

Physica Status Solidi (b)

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“…Experiments finally showed that the electronic ground state of Na 2 IrO 3 can be well described in terms of a relativistic Mott insulator with a half-filled j eff =1/2-band split by the Hubbard U [17,27,32,33], although it exhibits a significant intrahexagon itinerant character which could lead to a mixing of j eff =1/2 (j 1/2 ) and j eff =3/2 (j 3/2 ) states in the Ir t 2g level [17,34,35]. Compared to Na 2 IrO 3 , for α-Li 2 IrO 3 signs for an increased QMO character was observed at ambient conditions [17] and at low pressures [36].…”

Section: Introductionmentioning

confidence: 96%

Optical signature of the pressure-induced dimerization in the honeycomb iridate α−Li2IrO3

et al. 2019

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We studied the effect of external pressure on the electrodynamic properties of α-Li2IrO3 single crystals in the frequency range of the phonon modes and the Ir d-d transitions. The abrupt hardening of several phonon modes under pressure supports the onset of the dimerized phase at the critical pressure P c=3.8 GPa. With increasing pressure an overall decrease in spectral weight of the Ir d-d transitions is found up to P c. Above P c, the local (on-site) d-d excitations gain spectral weight with increasing pressure, which hints at a pressure-induced increase in the octahedral distortions. The non-local (intersite) Ir d-d transitions show a monotonic blue-shift and decrease in spectral weight. The changes observed for the non-local excitations are most prominent well above P c, namely for pressures ≥12 GPa, and only small changes occur for pressures close to P c. The profile of the optical conductivity at high pressures (∼20 GPa) appears to be indicative for the dimerized state in iridates.

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“…5d materials are unique for several reasons. First, strong spin-orbit coupling competes with magnetic, crystalfield, many-body Coulomb, and other interactions to drive new physical behaviors [7], such as the J eff = 1/2 state in certain iridates [8,9]. Second, the bonding interactions associated with the larger 5d orbitals promote inter-cation dimerization in pairwise, chain-like, and other complex orderings [10,11].…”

Section: Introductionmentioning

confidence: 99%

Spin–lattice and electron–phonon coupling in 3d/5d hybrid Sr3NiIrO6

et al. 2019

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While 3d-containing materials display strong electron correlations, narrow band widths, and robust magnetism, 5d systems are recognized for strong spin-orbit coupling, increased hybridization, and more diffuse orbitals. Combining these properties leads to novel behavior. Sr3NiIrO6, for example, displays complex magnetism and ultra-high coercive fields -up to an incredible 55 T. Here, we combine infrared and optical spectroscopies with high-field magnetization and first principles calculations to explore the fundamental excitations of the lattice and related coupling processes including spin-lattice and electron-phonon mechanisms. Magneto-infrared spectroscopy reveals spin-lattice coupling of three phonons that modulate the Ir environment to reduce the energy required to modify the spin arrangement. While these modes primarily affect exchange within the chains, analysis also uncovers important inter-chain motion. This provides a mechanism by which inter-chain interactions can occur in the developing model for ultra-high coercivity. At the same time, analysis of the on-site Ir 4+ excitations reveals vibronic coupling and extremely large crystal field parameters that lead to a t2g-derived low-spin state for Ir. These findings highlight the spin-chargelattice entanglement in Sr3NiIrO6 and suggest that similar interactions may take place in other 3d/5d hybrids. * musfeldt@utk.edu shifts in orbital energies, combined with spin-orbit and bandwidth effects, can drive band inversions leading to topological phases and enhanced Rashba splittings [12][13][14][15]. In contrast, 3d transition metal compounds typically display much narrower bandwidths, more robust magnetism, and stronger electron-electron interactions, and correlations [16,17]. When these two sets of properties are brought together, as in Sr 3 NiIrO 6 , new and potentially useful behaviors can emerge.What makes Sr 3 NiIrO 6 so remarkable is the extraordinary coercivity -up to 55 T depending on sample details [18]. By contrast, traditional hard magnets like Fe/Pt, Nd 31−x Dy x Fe bal Co 2 B 1 (x = 7 wt %), and LuFe 2 O 4 have coercivities on the order of 1, 3, and 9 T, respectively [19][20][21]. The extraordinarily high coercive field is not due to ferromagnetic domains since the material is antiferromagnetic, though the exact mechanism arXiv:1907.09392v1 [cond-mat.mtrl-sci]

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Pressure-driven collapse of the relativistic electronic ground state in a honeycomb iridate

Cited by 49 publications

References 45 publications

Microscopic Modeling of Correlated Systems Under Pressure: Representative Examples

Microscopic Modeling of Correlated Systems Under Pressure: Representative Examples

Optical signature of the pressure-induced dimerization in the honeycomb iridate α−Li2IrO3

Spin–lattice and electron–phonon coupling in 3d/5d hybrid Sr3NiIrO6

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