Search

Your search keyword '"Antonelli, Tommaso"' showing total 18 results
Start Over Author "Antonelli, Tommaso"
18 results on '"Antonelli, Tommaso"'

1. Exploring the energy spectrum of a four-terminal Josephson junction: Towards topological Andreev band structures

Author

Antonelli, Tommaso, Coraiola, Marco, Ohnmacht, David Christian, Svetogorov, Aleksandr E., Sabonis, Deividas, Kate, Sofieke C. ten, Cheah, Erik, Krizek, Filip, Schott, Rüdiger, Cuevas, Juan Carlos, Belzig, Wolfgang, Wegscheider, Werner, and Nichele, Fabrizio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Hybrid multiterminal Josephson junctions (JJs) are expected to harbor a novel class of Andreev bound states (ABSs), including topologically nontrivial states in four-terminal devices. In these systems, topological phases emerge when ABSs depend on at least three superconducting phase differences, resulting in a three-dimensional (3D) energy spectrum characterized by Weyl nodes at zero energy. Here, we realize a four-terminal JJ in a hybrid Al/InAs heterostructure, where ABSs form a synthetic 3D band structure. We probe the energy spectrum using tunneling spectroscopy and identify spectral features associated with the formation of a tri-Andreev molecule, a bound state whose energy depends on three superconducting phases and, therefore, is able to host topological ABSs. The experimental observations are well described by a numerical model. The calculations predict the appearance of four Weyl nodes at zero energy within a gap smaller than the experimental resolution. These topological states are theoretically predicted to remain stable within an extended region of the parameter space, well accessible by our device. These findings establish an experimental foundation to study high-dimensional synthetic band structures in multiterminal JJs, and to realize topological Andreev bands.

Published
2025

2. Dichotomy of electron-phonon interactions in the delafossite PdCoO$_2$: From weak bulk to polaronic surface coupling

Author

Siemann, Gesa-R., Murgatroyd, Philip A. E., Antonelli, Tommaso, Morales, Edgar Abarca, Khim, Seunghyun, Rosner, Helge, Watson, Matthew D., Mackenzie, Andrew P., and King, Phil D. C.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

The metallic delafossites host ultra-high mobility carriers in the bulk, while at their polar surfaces, intrinsic electronic reconstructions stabilise markedly distinct electronic phases, from charge-disproportionated insulators, to Rashba-split heavy-hole gases and ferromagnetic metals. The understanding of these phases has been strongly informed by surface spectroscopic measurements, but previous studies have been complicated by the presence of spatially varying terminations of the material surface. Here, we demonstrate the potential of microscopic-area angle-resolved photoemission to overcome these challenges. Our measurements of the model compound PdCoO$_2$ yield extremely high-quality spectra of the electronic structure, which allows us to place new experimental constraints on the weak electron-phonon coupling in the bulk of PdCoO$_2$, while revealing much stronger interactions at its surfaces. While the CoO$_2$-terminated surface exhibits a conventional weak-coupling behavior, our measurements reveal surprising spectroscopic signatures of polaron formation at the Pd-terminated surface, despite its pronounced metallicity. Together, our findings reveal how mode and symmetry-selective couplings can markedly tune the electron-phonon interactions in a single host material, here opening routes to stabilise surprisingly persistent polaronic quasiparticles., Comment: 17 pages including supplementary information

Published
2025

3. Development of a Nb-based semiconductor-superconductor hybrid platform

Author

Telkamp, Sjoerd, Antonelli, Tommaso, Todt, Clemens, Hinderling, Manuel, Coraiola, Marco, Haxell, Daniel, Kate, Sofieke C. ten, Sabonis, Deividas, Zeng, Peng, Schott, Rüdiger, Cheah, Erik, Reichl, Christian, Nichele, Fabrizio, Krizek, Filip, and Wegscheider, Werner

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Semiconductor-superconductor hybrid materials are used as a platform to realise Andreev bound states, which hold great promise for quantum applications. These states require transparent interfaces between the semiconductor and superconductor, which are typically realised by in-situ deposition of an Al superconducting layer. Here we present a hybrid material based on an InAs two-dimensional electron gas (2DEG) combined with in-situ deposited Nb and NbTi superconductors, which offer a larger operating range in temperature and magnetic field due to their larger superconducting gap. We overcome the inherent difficulty associated with the formation of an amorphous interface between III-V semiconductors and Nb-based superconductors by introducing a 7 nm Al interlayer. The Al interlayer provides an epitaxial connection between an in-situ magnetron sputtered Nb or NbTi thin film and a shallow InAs 2DEG. This metal-to-metal epitaxy is achieved by optimization of the material stack and results in an induced superconducting gap of approximately 1 meV, determined from transport measurements of superconductor-semiconductor Josephson junctions. This induced gap is approximately five times larger than the values reported for Al-based hybrid materials and indicates the formation of highly-transparent interfaces that are required in high-quality hybrid material platforms.

Published
2024

4. Charge doping into spin minority states mediates doubling of $T_\mathrm{C}$ in ferromagnetic CrGeTe$_3$

Author

Trzaska, Liam, Qiao, Lei, Watson, Matthew D., Hatnean, Monica Ciomaga, Marković, Igor, Morales, Edgar Abarca, Antonelli, Tommaso, Cacho, Cephise, Balakrishnan, Geetha, Ren, Wei, Picozzi, Silvia, and King, Phil D. C.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The recent discovery of the persistence of long-range magnetic order when van der Waals layered magnets are thinned towards the monolayer limit has provided a tunable platform for the engineering of novel magnetic structures and devices. Here, we study the evolution of the electronic structure of CrGeTe$_3$ as a function of electron doping in the surface layer. From angle-resolved photoemission spectroscopy, we observe spectroscopic fingerprints that this electron doping drives a marked increase in $T_\mathrm{C}$, reaching values more than double that of the undoped material, in agreement with recent studies using electrostatic gating. Together with density functional theory calculations and Monte Carlo simulations, we show that, surprisingly, the increased $T_\mathrm{C}$ is mediated by the population of spin-minority Cr $t_{2g}$ states, forming a half-metallic 2D electron gas at the surface. We show how this promotes a novel variant of double exchange, and unlocks a significant influence of the Ge -- which was previously thought to be electronically inert in this system -- in mediating Cr-Cr exchange., Comment: 10 pages including supplementary information

Published
2023
Full Text
View/download PDF

6. Charge doping into spin minority states mediates doubling of TC in ferromagnetic CrGeTe3.

Author

Trzaska, Liam, Qiao, Lei, Watson, Matthew D., Ciomaga Hatnean, Monica, Marković, Igor, Abarca Morales, Edgar, Antonelli, Tommaso, Cacho, Cephise, Balakrishnan, Geetha, Ren, Wei, Picozzi, Silvia, and King, Phil D. C.

Subjects
TWO-dimensional electron gas, MONTE Carlo method, DENSITY functional theory, MAGNETIC structure, MAGNETIC devices
Abstract

The recent discovery of the persistence of long-range magnetic order when van der Waals magnets are thinned towards monolayers provides a tunable platform for engineering of novel magnetic structures and devices. Here, we study the evolution of the electronic structure of CrGeTe3 as a function of surface electron doping. From angle-resolved photoemission, we observe spectroscopic fingerprints that this electron doping drives a marked increase in TC, reaching values more than double that of the undoped material, in agreement with recent studies using electrostatic gating. Together with density functional theory calculations and Monte Carlo simulations, we show that, surprisingly, the increased TC is mediated by the population of spin-minority Cr t2g states, forming a half-metallic 2D electron gas. This promotes a novel variant of double exchange, and unlocks a significant influence of Ge – which was previously thought to be electronically inert in this system – in mediating Cr-Cr exchange. [ABSTRACT FROM AUTHOR]

Published
2025
Full Text
View/download PDF

8. Chemical Trends of the Bulk and Surface Termination-Dependent Electronic Structure of Metal-Intercalated Transition Metal Dichalcogenides.

Author

Edwards, Brendan, Deaconu, Darius-A., Murgatroyd, Philip A. E., Buchberger, Sebastian, Antonelli, Tommaso, Halliday, Daniel, Siemann, Gesa-R., Zivanovic, Andela, Trzaska, Liam, Rajan, Akhil, Abarca Morales, Edgar, Mayoh, Daniel A., Hall, Amelia E., Belosludov, Rodion V., Watson, Matthew D., Kim, Timur K., Biswas, Deepnarayan, Lee, Tien-Lin, Polley, Craig M., and Carbone, Dina

Published
2024
Full Text
View/download PDF

11. Title redacted

Author

Antonelli, Tommaso, King, Phil, and Leverhulme Trust

Subjects
QC173.454A68
Abstract

redacted

Published
2023

12. Orbital-selective band hybridisation at the charge density wave transition in monolayer TiTe2.

Author

Antonelli, Tommaso, Rahim, Warda, Watson, Matthew D., Rajan, Akhil, Clark, Oliver J., Danilenko, Alisa, Underwood, Kaycee, Marković, Igor, Abarca-Morales, Edgar, Kavanagh, Seán R., Le Fèvre, P., Bertran, F., Rossnagel, K., Scanlon, David O., and King, Phil D. C.

Subjects
CHARGE density waves, ORBITAL hybridization, ELECTRONIC band structure, PHASE transitions, CONDUCTION bands, PHOTOEMISSION
Abstract

Reducing the thickness of a material to its two-dimensional (2D) limit can have dramatic consequences for its collective electronic states, including magnetism, superconductivity, and charge and spin ordering. An extreme case is TiTe2, where a charge density wave (CDW) emerges in the single-layer, which is absent for the bulk compound, and whose origin is still poorly understood. Here, we investigate the electronic band structure evolution across this CDW transition using temperature-dependent angle-resolved photoemission spectroscopy. Our study reveals an orbital-selective band hybridisation between the backfolded conduction and valence bands occurring at the CDW phase transition, which in turn leads to a significant electronic energy gain, underpinning the CDW transition. For the bulk compound, we show how this energy gain is almost completely suppressed due to the three-dimensionality of the electronic band structure, including via a kz-dependent band inversion which switches the orbital character of the valence states. Our study thus sheds new light on how control of the electronic dimensionality can be used to trigger the emergence of new collective states in 2D materials. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

13. Strong-coupling charge density wave in monolayer TiSe2

Author

Watson, Matthew D, primary, Rajan, Akhil, additional, Antonelli, Tommaso, additional, Underwood, Kaycee, additional, Marković, Igor, additional, Mazzola, Federico, additional, Clark, Oliver J, additional, Siemann, Gesa-Roxanne, additional, Biswas, Deepnarayan, additional, Hunter, Andrew, additional, Jandura, Sven, additional, Reichstetter, Janika, additional, McLaren, Martin, additional, Le Fèvre, Patrick, additional, Vinai, Giovanni, additional, and King, Philip D C, additional

Published
2020
Full Text
View/download PDF

14. Strong-coupling charge density wave in monolayer TiSe2.

Author

Watson, Matthew D, Rajan, Akhil, Antonelli, Tommaso, Underwood, Kaycee, Marković, Igor, Mazzola, Federico, Clark, Oliver J, Siemann, Gesa-Roxanne, Biswas, Deepnarayan, Hunter, Andrew, Jandura, Sven, Reichstetter, Janika, McLaren, Martin, Fčvre, Patrick Le, Vinai, Giovanni, and King, Philip D C

Published
2021
Full Text
View/download PDF

15. Controlling the Charge Density Wave Transition in Single-Layer TiTe2xSe2(1–x)Alloys by Band Gap Engineering

Author

Antonelli, Tommaso, Rajan, Akhil, Watson, Matthew D., Soltani, Shoresh, Houghton, Joe, Siemann, Gesa-Roxanne, Zivanovic, Andela, Bigi, Chiara, Edwards, Brendan, and King, Phil D. C.

Abstract

Closing the band gap of a semiconductor into a semimetallic state gives a powerful potential route to tune the electronic energy gains that drive collective phases like charge density waves (CDWs) and excitonic insulator states. We explore this approach for the controversial CDW material monolayer (ML) TiSe2by engineering its narrow band gap to the semimetallic limit of ML-TiTe2. Using molecular beam epitaxy, we demonstrate the growth of ML-TiTe2xSe2(1–x)alloys across the entire compositional range and unveil how the (2 × 2) CDW instability evolves through the normal state semiconductor–semimetal transition via in situangle-resolved photoemission spectroscopy. Through model electronic structure calculations, we identify how this tunes the relative strength of excitonic and Peierls-like coupling, demonstrating band gap engineering as a powerful method for controlling the microscopic mechanisms underpinning the formation of collective states in two-dimensional materials.

Published
2023
Full Text
View/download PDF

16. Quantum phase estimation algorithms

Author

Antonelli, Tommaso, thesis supervisor: Ercolessi, Elisa, Antonelli, Tommaso, and thesis supervisor: Ercolessi, Elisa

Abstract

Al contrario dei computer classici, i computer quantistici lavorano tramite le leggi della meccanica quantistica, e pertanto i qubit, ovvero l'unità base di informazione quantistica, possiedono proprietà estremamente interessanti di sovrapposizione ed entanglement. Queste proprietà squisitamente quantistiche sono alla base di innumerevoli algoritmi, i quali sono in molti casi più performanti delle loro controparti classiche. Obiettivo di questo lavoro di tesi è introdurre dal punto di vista teorico la logica computazionale quantistica e di riassumere brevemente una classe di tali algoritmi quantistici, ossia gli algoritmi di Quantum Phase Estimation, il cui scopo è stimare con precisione arbitraria gli autovalori di un dato operatore unitario. Questi algoritmi giocano un ruolo cruciale in vari ambiti della teoria dell'informazione quantistica e pertanto verranno presentati anche i risultati dell'implementazione degli algoritmi discussi sia su un simulatore che su un vero computer quantistico.

17. Quantum phase estimation algorithms

Author

Antonelli, Tommaso, thesis supervisor: Ercolessi, Elisa, Antonelli, Tommaso, and thesis supervisor: Ercolessi, Elisa

Abstract

Al contrario dei computer classici, i computer quantistici lavorano tramite le leggi della meccanica quantistica, e pertanto i qubit, ovvero l'unità base di informazione quantistica, possiedono proprietà estremamente interessanti di sovrapposizione ed entanglement. Queste proprietà squisitamente quantistiche sono alla base di innumerevoli algoritmi, i quali sono in molti casi più performanti delle loro controparti classiche. Obiettivo di questo lavoro di tesi è introdurre dal punto di vista teorico la logica computazionale quantistica e di riassumere brevemente una classe di tali algoritmi quantistici, ossia gli algoritmi di Quantum Phase Estimation, il cui scopo è stimare con precisione arbitraria gli autovalori di un dato operatore unitario. Questi algoritmi giocano un ruolo cruciale in vari ambiti della teoria dell'informazione quantistica e pertanto verranno presentati anche i risultati dell'implementazione degli algoritmi discussi sia su un simulatore che su un vero computer quantistico.

18. Controlling the Charge Density Wave Transition in Single-Layer TiTe 2 x Se 2(1- x ) Alloys by Band Gap Engineering.

Author

Antonelli T, Rajan A, Watson MD, Soltani S, Houghton J, Siemann GR, Zivanovic A, Bigi C, Edwards B, and King PDC

Abstract

Closing the band gap of a semiconductor into a semimetallic state gives a powerful potential route to tune the electronic energy gains that drive collective phases like charge density waves (CDWs) and excitonic insulator states. We explore this approach for the controversial CDW material monolayer (ML) TiSe 2 by engineering its narrow band gap to the semimetallic limit of ML-TiTe 2 . Using molecular beam epitaxy, we demonstrate the growth of ML-TiTe 2 x Se 2(1- x ) alloys across the entire compositional range and unveil how the (2 × 2) CDW instability evolves through the normal state semiconductor-semimetal transition via in situ angle-resolved photoemission spectroscopy. Through model electronic structure calculations, we identify how this tunes the relative strength of excitonic and Peierls-like coupling, demonstrating band gap engineering as a powerful method for controlling the microscopic mechanisms underpinning the formation of collective states in two-dimensional materials.

Published
2024
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results