Facultad de Ciencias

Teoría y simulación en materia condensada.

• Teoría de grafeno y sistemas relacionados, principalmente respuesta  electromagnética.

Mecánica Cuántica II (16408 )

Mecánica Y Ondas II   (16398 )

Técnicas Experimentales II (16401)

1. Plasmon-Enhanced Near-Field Chirality in Twisted van der Waals Heterostructures. Nano Letters 20, 8711-8718 (2020). T. Stauber, T. Low y G. Gómez-Santos.[URL]
2. Chiral Plasmons with Twisted Atomic Bilayers. Physical Review Letters 125, 077401 (2020). X. Lin, Z.F. Liu, T. Stauber, G. Gómez-Santos F. Gao, H.S. Chen, B.L. Zhang y T.Low. [URL]
3. Nonlocal Quantum Effects in Plasmons of Graphene Superlattices.  Physical Review Letters 124, 257401 (2020). L. Brey, T. Stauber, L. Martin-Moreno y G. Gómez-Santos. [URL]
4. Linear response of twisted bilayer graphene: Continuum versus tight-binding models. Physical Review B 98, 195414 (2018). T. Stauber, T. Low y G. Gómez-Santos. [URL]
5. Chiral Response of Twisted Bilayer Graphene. Physical Review Letters 120, 046801 (2018). T. Stauber, T. Low y G. Gómez-Santos. [URL]
6. Extraordinary Absorption of Decorated Undoped Graphene, T. Stauber, G. Gómez-Santos, and F. Javier García de Abajo, Phys. Rev. Lett. 112, 077401, (2014). [URL]
7.  Plasmons and near-field amplification in double-layer graphene, T. Stauber and G. Gómez-Santos, Phys. Rev. B 85, 075410, (2012). [URL]
8. Measurable Lattice Effects on the Charge and Magnetic Response in Graphene, G. Gómez-Santos and T. Stauber, Phys. Rev. Lett. 106, 045504, (2011). [URL]
9. Thermal van der Waals interaction between graphene layers, G. Gómez-Santos, Phys. Rev. B 80, 245424, (2009). [URL]