This shows you the differences between two versions of the page.
Both sides previous revisionPrevious revisionNext revision | Previous revisionNext revisionBoth sides next revision | ||
panda:publications [2020/07/10 09:30] – Christian Franz | panda:publications [2020/07/10 10:01] – [2019] Christian Franz | ||
---|---|---|---|
Line 1: | Line 1: | ||
====2020==== | ====2020==== | ||
- | //Magnonic Weyl states in Cu2OSeO3//. L.-C. Zhang et al. **Phys. Rev. Research** 2, 013063 (2020) | + | //Magnonic Weyl states in Cu2OSeO3//. L.-C. Zhang et al. **Phys. Rev. Research** 2, 013063 (2020) |
https:// | https:// | ||
- | //Magnetic anisotropy in ferromagnetic CrI3//. Lebing Chen et al. **PRB** B 101, 134418 (2020) | + | //Magnetic anisotropy in ferromagnetic CrI3//. Lebing Chen et al. **PRB** B 101, 134418 (2020) |
https:// | https:// | ||
- | //Nature of the spin resonance mode in CeCoIn5//. Yu Song et al. **Nature Communications Physics** | + | //Nature of the spin resonance mode in CeCoIn5//. Yu Song et al. **Nature Communications Physics** |
https:// | https:// | ||
- | //Neutron Spin Resonance in the Heavily Hole-Doped KFe2As2 Superconductor// | + | //Neutron Spin Resonance in the Heavily Hole-Doped KFe2As2 Superconductor// |
https:// | https:// | ||
- | // | + | // |
https:// | https:// | ||
- | // | + | // |
https:// | https:// | ||
Line 25: | Line 25: | ||
====2019==== | ====2019==== | ||
- | //Spin-wave directional anisotropies in antiferromagnetic Ba3NbFe3Si2O14//, | + | //Spin-wave directional anisotropies in antiferromagnetic Ba3NbFe3Si2O14//, |
+ | https:// | ||
- | // | + | // |
//Evidence for singular-phonon-induced nematic superconductivity in a topological superconductor candidate Sr0.1Bi2Se3//, | //Evidence for singular-phonon-induced nematic superconductivity in a topological superconductor candidate Sr0.1Bi2Se3//, | ||
- | // | + | // |
+ | https:// | ||
//Interplay of Electronic and Spin Degrees in Ferromagnetic SrRuO3: Anomalous Softening of the Magnon Gap and Stiffness//, | //Interplay of Electronic and Spin Degrees in Ferromagnetic SrRuO3: Anomalous Softening of the Magnon Gap and Stiffness//, | ||
- | // | + | // |
+ | https:// | ||
//Relaxing Kondo-screened Kramers doublets in CeRhSi3//, J. Pásztorová et al., **Phys. Rev. B.** 99 125144 | //Relaxing Kondo-screened Kramers doublets in CeRhSi3//, J. Pásztorová et al., **Phys. Rev. B.** 99 125144 | ||
Line 41: | Line 44: | ||
// | // | ||
- | // | + | // |
+ | https:// | ||
Line 47: | Line 51: | ||
====2018==== | ====2018==== | ||
- | // | + | // |
+ | https:// | ||
Line 57: | Line 62: | ||
//Absence of a Large Superconductivity-Induced Gap in Magnetic Fluctuations of Sr2 RuO4//, S. Kunkemöller et al., **Phys. Rev. Lett.** | //Absence of a Large Superconductivity-Induced Gap in Magnetic Fluctuations of Sr2 RuO4//, S. Kunkemöller et al., **Phys. Rev. Lett.** | ||
- | // | + | // |
+ | https:// | ||
//Large positive correlation between the effective electron mass and the multipolar fluctuation in the heavy-fermion metal Ce1−xLaxB6//, | //Large positive correlation between the effective electron mass and the multipolar fluctuation in the heavy-fermion metal Ce1−xLaxB6//, | ||
Line 65: | Line 71: | ||
//Spinon con_nement in a quasi one dimensional anisotropic Heisenberg magnet//, A. K. Bera, **Phys. Rev. B** 96 054423 | //Spinon con_nement in a quasi one dimensional anisotropic Heisenberg magnet//, A. K. Bera, **Phys. Rev. B** 96 054423 | ||
- | //4-spin plaquette singlet state in the Shastry–Sutherland compound SrCu2(BO3)2//, | + | //4-spin plaquette singlet state in the Shastry–Sutherland compound SrCu2(BO3)2//, |
+ | https:// | ||
//Magnetic phase diagram of CeCu2Ge2 up to 15 T: On the route to understand field-induced phase transitions//, | //Magnetic phase diagram of CeCu2Ge2 up to 15 T: On the route to understand field-induced phase transitions//, |