Superconductivity in diamond

Екимов, Е. А.; Sidorov, V. A.; Bauer, E. D.; Melnik, N. N.; Curro, N. J.; Thompson, J. D.; Стишов, С. М.

doi:10.1038/nature02449

Cited by 1,094 publications

(740 citation statements)

References 20 publications

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“…(1) can be well understood since hydrogen adsorption effectively removes π bonds (sp 3 C-H bond). Concerning (2), the feature appears between 284.3 eV and 285.3 eV, as indicated by the arrows in fig. 1(c).…”

Section: Resultsmentioning

confidence: 98%

Direct observation of a dispersionless impurity band in hydrogenated graphene

et al. 2011

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We show with angle-resolved photoemission spectroscopy that a new energy band appears in the electronic structure of electron doped hydrogenated monolayer graphene (H-graphene). Its occupation can be controlled with the hydrogen amount and allows for tuning of graphene's doping level. Our calculations of the electronic structure of H-graphene suggest that this state is largely composed from hydrogen 1s orbitals and remains extended for low H coverages despite the random chemisorption of H. Further evidence for the existence of a hydrogen state is provided by X-ray absorption studies of undoped H-graphene which are clearly showing the emergence of an additional state in the vicinity of the π * -resonance.

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Section: Resultsmentioning

confidence: 98%

Direct observation of a dispersionless impurity band in hydrogenated graphene

et al. 2011

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“…Diamond has been reported [1] to become a superconductor upon high boron doping with a T c ≈ 4 K. This remarkable discovery of superconductivity in an uncompensated p-type semiconductor has possible implications for basic science and technology. As an example, shallow dopant states in Si and Ge play a key role in modern solid state electronics; from physics point of view they offer a testing ground for various ideas such as Anderson and Mott localization and their interplay.…”

Section: Pacs Numbersmentioning

confidence: 98%

Resonating Valence Bond Mechanism of Impurity Band Superconductivity in Diamond

Baskaran

2007

J Supercond Nov Magn

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Superconductivity in an uncompensated boron doped diamond, a very recent observation, is strikingly close to an earlier observation of Anderson-Mott insulator to metal transition, prompting us to suggest an electron correlation driven superconductivity in an impurity band. Random coulomb potential remove a three fold orbital degeneracy of boron acceptor states, resulting in an effective single, narrow, tight binding and half filled band of holes. Singlet coupling between spins of neighboring neutral acceptors B 0 − B 0 is the seed of pairing. Across the insulator to metal transition, a small and equal fraction of charged B + and B − states (free carriers) get spontaneously generated and delocalize. Thereupon neutral singlets resonate and get charged resulting in a resonating valence bond (RVB) superconducting state.

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“…This new class of superconductors with directional covalent bonding, most likely electron-phonon mediated, consists not only of doped diamond, but also other doped semiconductors 3 . In the 1960's, it was predicted that doping a semiconductor with many-valley features in the band structure would induce an effective interaction to overcome the Coulomb repulsion 4,5 ; this mechanism was confirmed in subsequent experiments on reduced SrTiO 3 6 and Ge 1−x Te 7 , albeit with rather low transition temperatures, T c , of at most 0.5 K. Nevertheless, the 2004 discovery [8][9][10] of superconductivity in boron-doped diamond has excited interest in this new class of superconductors, which now also extends to silicon 11 and SiC 12,13 . In doped diamond, the concentration of B dopants exceeded a critical value responsible for a metal-insulator transition, which eventually induced superconductivity around 7-9 K with carrier densities of ∼10 21 cm −38,14 .…”

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confidence: 94%

Electric-field-driven hole carriers and superconductivity in diamond

et al. 2013

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First-principles calculations of electric field (E-field)-driven superconductivity at the hydrogenated diamond (110) surface are presented. While the hydrogens on the surface effectively maintain the intrinsic sp 3 covalent nature of diamond, the hole carriers induced by an external negative E-field lead to a metallic surface region. Importantly, the concentration of hole carriers, confined within a few carbon-layers of thickness ∼5-10Å below the surface, exceeds 10 21 cm −3 , which is larger than the critical hole density responsible for superconductivity in the boron-doped diamond, while the calculated electron-phonon coupling constants are comparable in magnitude, suggesting the possibility of superconductivity with enhanced critical field.

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Superconductivity in diamond

Cited by 1,094 publications

References 20 publications

Direct observation of a dispersionless impurity band in hydrogenated graphene

Direct observation of a dispersionless impurity band in hydrogenated graphene

Resonating Valence Bond Mechanism of Impurity Band Superconductivity in Diamond

Electric-field-driven hole carriers and superconductivity in diamond

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