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Setup. A DFT Study of Electron-Phonon Coupling in Proxy CuX (X = S, Se, Te) Structures and Its Relationship to Possible Manifestation of Superconductivity.

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Presentation on theme: "Setup. A DFT Study of Electron-Phonon Coupling in Proxy CuX (X = S, Se, Te) Structures and Its Relationship to Possible Manifestation of Superconductivity."— Presentation transcript:

1 Setup

2 A DFT Study of Electron-Phonon Coupling in Proxy CuX (X = S, Se, Te) Structures and Its Relationship to Possible Manifestation of Superconductivity Paul M. Grant W2AGZ Technologies Robert H. Hammond Stanford University Session Q11 Chalcogenide Superconductors 2:30 PM – 4:54 PM, Wednesday, 4 March Paper 11 4:06 PM – 4:18 PM Room 007B

3 – Our Computational Tool Box – DFT + Hubbard U – Quantum Espresso Fermiologies, States (DOS), Phonons, e-p “Lambda” Graphics – Xcrysden, XMGRACE Fermi Surfaces, Projected DOS Modeling – Debye Temperatures a la Gibbs2 Package Thanks to Alberto Otero-de-la-Rosa, http://azufre.quimica.uniovi.es/src/gibbs2/gibbs2.pdf – Then Superconductivity via Eliashberg/McMillan!

4 “Configuration/Coordination Space” Relative Ground State Energies Tennorite The Various Flavors of Copper “Monoxide” “1-2-3” tet-rs-CuO Siemons, et al. (2009) Grant (2008) Franchini Group (2011) Cococcioni Group (2011) Can we compute/synthesize the S, Se, Te analogues...and what would be their physical properties wrt magnetism and superconductivity? Magnetic properties revealed at APS MM Denver 2014. Now superconductivity!

5 CuO Ground State Energies via Gibbs2: CuO & CuS CuS Min GSE at a0 = 4.13 Å (Cubic) Cubic CuO (Cubic)  D = 693 K Min GSE at a0 = 3.9 Å, c/a = 1.15 Tetragonal CuO (Tet)  D = 733 K Min GSE at a0 = 4.75 Å CuS (Cubic)  D = 525 K Min GSE at a0 = 4.5 Å, c/a = 1.12 CuS(Tet)  D = 780 K

6 CuSe CuTe Ground State Energies via Gibbs2: CuSe & CuTe Min GSE at a0 = 5.0 Å Cubic CuSe (Cubic)  D = 409 K Min GSE at a0 = 5.34 Å CuTe (Cubic)  D = 327 K Min GSE at a0 = 4.75 Å, c/a = 1.1 Tetragonal CuTe (Tet)  D = 622 K Min GSE at a0 = 5.05 Å, c/a = 1.1 CuTe (Tet)  D = 489 K

7 Superconductivity and Phonons BCS via Eliashberg-McMillan To get, need to compute! NB! The “double deltas” will be approximated by two Gaussians of width “sigma (  )” whose numerical convergence is governed by imposed precision limits and basis set symmetry. Con Quidado!

8 Eliashberg-McMillan-Allen-Dynes Let’s Go!

9 CuSe T C  D = 409 K;  * = 0.0 Cubic T C (max) ~ 17 K Tetragonal T C (max) ~ 36 K  D = 623 K;  * = 0.0

10 CuTe T C  D = 327 K;  * = 0.0 Cubic T C (max) ~ 4.2 K Tetragonal T C (max) ~ 45 K  D = 490 K;  * = 0.0

11 CuS T C  D = 525 K;  * = 0.0 Cubic T C (max) ~ 28 K Tetragonal  D = 780 K;  * = 0.0 Whoops! Unphysically “negative” ! Convergence issues? Symmetry issues? “Needs more work ;-)”

12 OK...Now What About CuO? Well? Assume a doping density for“g = 0.15 holes/CuO” in this region for experimentally determined Tet-CuO that effectively screens “U” such that we have an “ideal” Fermi liquid. Then what does Gibbs2 and Eliashberg- McMillan tell us about the possibility of electron-phonon mediated superconducting copper oxide perovskites?

13 CuO (tetragonal) q = 0.15/CuO T C  D = 928 K T C (avg) ~ 75 K  * = 0.05 with maybe a little help from their spins! Ipso Facto... At least at optimum doping... the holes are paired by lattice shakes...

14 So What Else is New? Macfarlane, Rosen, Seki, SSC 63, 831 (1987) Raman Spectroscopy of YBCO We can see Phonons have been there ever since the Creation!

15 At the End of the Day... Can We Actually Make Any of this Stuff?

16 Aluminum (Quantum-ESPESSO Example)  * = 0.1 Log_w ~  D T C (exp) = 1.2 K 

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