Prof Arzhang Ardavan

Real-World Data of High-Grade Lymphoma Patients Treated with CD19 CAR-T in England

Blood American Society of Hematology 134:Supplement_1 (2019) 767

Authors:

Andrea Kuhnl, Claire Roddie, Nuria Martinez-Cibrian, Tobias F Menne, Kim Linton, Sanne Lugthart, Sridhar Chaganti, Robin Sanderson, Maria AV Marzolini, Jane Norman, Wendy Osborne, John Radford, Stephen Robinson, Ram Malladi, Piers EM Patten, Maeve A O'Reilly, Muhammad Saif, Geoff Shenton, Adrian Bloor, Clare J Rowntree, David A Irvine, Orla Stewart, Arzhang Ardavan, Kate Robinson, Antonio Pagliuca, Kristian M Bowles, Graham P Collins, Rod Johnson, Andrew K McMillan

Coherent spin manipulation of individual atoms on a surface

Science American Association for the Advancement of Science 366:6464 (2019) 509-512

Authors:

K Yang, W Paul, S-H Phark, P Willke, Y Bae, T Choi, T Esat, Arzhang Ardavan, A Heinrich, C Lutz

Abstract:

Achieving time-domain control of quantum states with atomic-scale spatial resolution in nanostructures is a long-term goal in quantum nanoscience and spintronics. Here, we demonstrate coherent spin rotations of individual atoms on a surface at the nanosecond time scale, using an all-electric scheme in a scanning tunneling microscope (STM). By modulating the atomically confined magnetic interaction between the STM tip and surface atoms, we drive quantum Rabi oscillations between spin-up and spin-down states in as little as ~20 nanoseconds. Ramsey fringes and spin echo signals allow us to understand and improve quantum coherence. We further demonstrate coherent operations on engineered atomic dimers. The coherent control of spins arranged with atomic precision provides a solid-state platform for quantum-state engineering and simulation of many-body systems.

Mott polaritons in cavity-coupled quantum materials

New Journal of Physics IOP Publishing 21 (2019) 073066

Authors:

Martin Kiffner, Jonathan Coulthard, Frank Schlawin, Arzhang Ardavan, Dieter Jaksch

Abstract:

We show that strong electron-electron interactions in quantum materials can give rise to electronic transitions that couple strongly to cavity fields, and collective enhancement of these interactions can result in ultrastrong effective coupling strengths. As a paradigmatic example we consider a Fermi-Hubbard model coupled to a single-mode cavity and find that resonant electron-cavity interactions result in the formation of a quasi-continuum of polariton branches. The vacuum Rabi splitting of the two outermost branches is collectively enhanced and scales with USD g_{\text{eff}}\propto\sqrt{2L} USD, where USD L USD is the number of electronic sites, and the maximal achievable value for USD g_{\text{eff}} USD is determined by the volume of the unit cell of the crystal. We find that USD g_{\text{eff}} USD for existing quantum materials can by far exceed the width of the first excited Hubbard band. This effect can be experimentally observed via measurements of the optical conductivity and does not require ultrastrong coupling on the single-electron level. Quantum correlations in the electronic ground state as well as the microscopic nature of the light-matter interaction enhance the collective light-matter interaction compared to an ensemble of independent two-level atoms interacting with a cavity mode.

Mott polaritons in cavity-coupled quantum materials

(2019)

Authors:

Martin Kiffner, Jonathan Coulthard, Frank Schlawin, Arzhang Ardavan, Dieter Jaksch

Manipulating quantum materials with quantum light (vol 99, 085116, 2019)

Physical Review B (2019)

Authors:

MARTIN Kiffner, F Schlawin, A Ardavan, DIETER Jaksch

Abstract:

© 2019 American Physical Society. The interaction Hamiltonian (Formula Presented) Eq. (14) describing the interaction between the cavity and the electronic system was obtained by expanding the Peierls Hamiltonian in Eq. (A4) up to first order in the small parameter (Formula Presented) All results presented in the paper are consistent with this appro imate interaction Hamiltonian, leading to an effective Hamiltonian that depends quadratically on. However, it turns out that a straightforward improvement of the parameters entering the effective Hamiltonian in Eq. (26) can be obtained by including the second-order term in the Peierls Hamiltonian in Eq. (A4). This term gives rise to modifications of our results that are also of order through a renormalization of the nearest-neighbor hopping amplitude (Formula Presented) The authors would like to thank M. A. Sentef for bringing the importance of the second-order term in Eq. (A4) to our attention.