Putative hybridization gap in 
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 under applied pressure

Piva, M. M.; Thomas, S. M.; Fisk, Z.; Zhu, Jian‐Xin; Thompson, J. D.; Pagliuso, P. G.; Rosa, P. F. S.

doi:10.1103/physrevb.100.045108

Cited by 5 publications

(16 citation statements)

References 38 publications

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“…Additional recent transport studies find a small activation gap between 2 -4 meV. 20 Our calculations yield a larger magnetic moment and energy gap, however our results improve upon those obtained using the HSE06 hybrid functional. 20 Previous studies on transition metal solids, including Fe, Co, Ni, and Mn, where SCAN was employed yielded the complex charge and noncollinear magnetic ordering that occurs at low temperatures, but with a slight enhancement of the magnetization.…”

Section: Magnetic and Electronic Structuresupporting

confidence: 72%

“…The band gap is indirect with the transition from the conduction band and the valence band characterized by a change in crystal momentum from Γ to M . Overall, the band structure resembles the same obtained by the generalized gradient approximation 18,20 , except with a finite band gap. In contrast, the conduction bands obtained by the HSE06 hybrid functional (Ref.…”

Section: Magnetic and Electronic Structuresupporting

confidence: 70%

“…20 Our calculations yield a larger magnetic moment and energy gap, however our results improve upon those obtained using the HSE06 hybrid functional. 20 Previous studies on transition metal solids, including Fe, Co, Ni, and Mn, where SCAN was employed yielded the complex charge and noncollinear magnetic ordering that occurs at low temperatures, but with a slight enhancement of the magnetization. 30 The enhancement is attributed to an oversensitivity of the iso-orbital indicator, α, used to discern various chemical bonding environments and is currently being amended.…”

Section: Magnetic and Electronic Structuresupporting

confidence: 63%

“…18,19 In line with this claim, lowtemperature electrical transport measurements find a slight increase of the gap under pressure. 20 This type of behavior is akin to Ce 3 Bi 4 Pt 3 and other heavy fermion compounds. [21][22][23] Therefore, CaMn 2 Bi 2 could provide a link between the cuprates, pnictides, and heavy fermion systems.…”

Section: Introductionmentioning

confidence: 99%

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Competition between electronic correlations and hybridization in CaMn$_{2}$Bi$_{2}$

Piva¹,

Rosa²,

Zhu³

2019

Preprint

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We study the interplay between electronic correlations and hybridization in the low-energy electronic structure of CaMn2Bi2, a candidate hybridization-gap semiconductor. Utilizing state-of-theart advanced density functionals we find both the antiferromagnetic Néel order and band gap in good agreement with the corresponding experimental values. We further find that, under hydrostatic pressure, the band gap is mainly governed by magnetic correlations, whereas hybridization has a greater impact on states at higher band energies. This result suggests that CaMn2Bi2 is more closely related to the high-temperature superconducting cuprates and iron pnictides than the heavy fermion class of materials. Finally, we also find the antiferromagnetic CaMn2Bi2 to be topologically trivial for all pressures studied.

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Section: Magnetic and Electronic Structuresupporting

confidence: 72%

Section: Magnetic and Electronic Structuresupporting

confidence: 70%

Section: Magnetic and Electronic Structuresupporting

confidence: 63%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Competition between electronic correlations and hybridization in CaMn$_{2}$Bi$_{2}$

Piva¹,

Rosa²,

Zhu³

2019

Preprint

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“…We believe that such a difficulty in empirical demonstration does not rule out our argument regarding the structural metastability of CaAl 2 Si 2 since empirical evidences of HPHT-induced metastability-related transition in CaAl 2 Si 2 -type compounds are well documented in, e.g., the isomorphous SrAl 2 Si 2 [26] and SrMn 2 P 2 [27] as well as in BaAl 2 Si 2 [7] (more detailed analysis will be reported in reference [19]). It is worth mentioning that the isomorphous CaMn 2 Bi 2 manifests a pressure-induced, room-temperature structural P 3m1 → P2 1 /m transition at P c ≈ 2.35 GPa [28,29]: in contrast to CaAl 2 Si 2 , the occurrence of such a transition signals an absence of both a metastable character and an energy barrier, however it is left to be verified if an HPHT treatment would be capable of effecting another P2 1 /m → I4/mmm transition.…”

Section: Discussionmentioning

confidence: 99%

Pressure dependence of room-temperature structural properties of CaAl₂Si₂

Strikos¹,

Joseph²,

Alabarse³

et al. 2020

J. Phys.: Condens. Matter

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We investigated the pressure dependence of the crystal structure of CaAl2Si2 by means of ab initio calculations and room-temperature synchrotron x-ray powder diffraction. Ab initio calculations reproduce satisfactorily the experimentally observed pressure-dependent structural evolution up to 3 GPa where the title system remains in the trigonal phase. In the pressure range 3–8 GPa, pressure evolution of the calculated in-plane lattice parameters is steeper than the observed. Ab initio calculations predict a structural phase transition to a tetragonal phase ( to I4/mmm) near 7.5 GPa for zero (or room) temperature. Temperature effects are included through calculation of vibrational properties (phonon spectra). These calculations confirm that both phases are either globally or locally stable (metastable) and allow for the construction of a P − T phase diagram for this system. However, our experiments show no sign of such a transition up to 12 GPa. Such a discrepancy can be explained if one considers the trigonal () structure to be metastable above the critical pressure, but is separated from the predicted tetragonal (I4/mmm) structure by a relatively high energy barrier. The applied pressure alone may not be able to surpass the energy-barrier; rather a joint high-pressure and high-temperature (HPHT) treatment may lead to it. However, empirical verification of such a hypothetical transition may be hampered by the chemistry of CaAl2Si2 system which shows tendency to decompose peritectically into Ca2Al3Si4 and aluminum under HPHT treatment.

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Correlation versus hybridization gap in CaMn$$_{2}$$Bi$$_{2}$$

Piva

Rosa

Zhu

2023

Sci Rep

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We study the interplay between electronic correlations and hybridization in the low-energy electronic structure of CaMn$$_2$$ 2 Bi$$_2$$ 2 , a candidate hybridization-gap semiconductor. By employing a DFT+U approach we find both the antiferromagnetic Néel order and band gap in good agreement with the corresponding experimental values. Under hydrostatic pressure, we find a crossover from hybridization gap to charge-transfer insulting physics due to the delicate balance of hybridization and correlations. Increasing the pressure above $$P_c=4$$ P c = 4 GPa we find a simultaneous pressure-induced volume collapse, plane-to-chain, insulator to metal transition. Finally, we have also analyzed the topology in the antiferromagnetic CaMn$$_2$$ 2 Bi$$_2$$ 2 for all pressures studied.

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Putative hybridization gap in CaMn2Bi2 under applied pressure

Cited by 5 publications

References 38 publications

Competition between electronic correlations and hybridization in CaMn$_{2}$Bi$_{2}$

Competition between electronic correlations and hybridization in CaMn$_{2}$Bi$_{2}$

Pressure dependence of room-temperature structural properties of CaAl₂Si₂

Correlation versus hybridization gap in CaMn$$_{2}$$Bi$$_{2}$$

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Putative hybridization gap in CaMn2Bi2 under applied pressure

Cited by 5 publications

References 38 publications

Competition between electronic correlations and hybridization in CaMn$_{2}$Bi$_{2}$

Competition between electronic correlations and hybridization in CaMn$_{2}$Bi$_{2}$

Pressure dependence of room-temperature structural properties of CaAl2Si2

Correlation versus hybridization gap in CaMn$$_{2}$$Bi$$_{2}$$

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Product

Resources

About

Pressure dependence of room-temperature structural properties of CaAl₂Si₂