Your search keyword '"Ganzhorn, Marc"' showing total 36 results

1. Time-resolved tomography of a driven adiabatic quantum simulation

Author

Salis, Gian, Moll, Nikolaj, Roth, Marco, Ganzhorn, Marc, and Filipp, Stefan

Subjects

Quantum Physics

Abstract

A typical goal of a quantum simulation is to find the energy levels and eigenstates of a given Hamiltonian. This can be realized by adiabatically varying the system control parameters to steer an initial eigenstate into the eigenstate of the target Hamiltonian. Such an adiabatic quantum simulation is demonstrated by directly implementing a controllable and smoothly varying Hamiltonian in the rotating frame of two superconducting qubits, including longitudinal and transverse fields and iSWAP-type two-qubit interactions. The evolution of each eigenstate is tracked using time-resolved state tomography. The energy gaps between instantaneous eigenstates are chosen such that depending on the energy transition rate either diabatic or adiabatic passages are observed in the measured energies and correlators. Errors in the obtained energy values induced by finite $T_1$ and $T_2$ times of the qubits are mitigated by extrapolation to short protocol times., Comment: 5 pages, 4 figures

Published

2020

2. Gate-efficient simulation of molecular eigenstates on a quantum computer

Author

Ganzhorn, Marc, Egger, Daniel J., Barkoutsos, Panagiotis Kl., Ollitrault, Pauline, Salis, Gian, Moll, Nikolaj, Fuhrer, Andreas, Mueller, Peter, Woerner, Stefan, Tavernelli, Ivano, and Filipp, Stefan

Subjects

Quantum Physics

Abstract

A key requirement to perform simulations of large quantum systems on near-term quantum hardware is the design of quantum algorithms with short circuit depth that finish within the available coherence time. A way to stay within the limits of coherence is to reduce the number of gates by implementing a gate set that matches the requirements of the specific algorithm of interest directly in hardware. Here, we show that exchange-type gates are a promising choice for simulating molecular eigenstates on near-term quantum devices since these gates preserve the number of excitations in the system. Complementing the theoretical work by Barkoutsos et al. [PRA 98, 022322 (2018)], we report on the experimental implementation of a variational algorithm on a superconducting qubit platform to compute the eigenstate energies of molecular hydrogen. We utilize a parametrically driven tunable coupler to realize exchange-type gates that are configurable in amplitude and phase on two fixed-frequency superconducting qubits. With gate fidelities around 95% we are able to compute the eigenstates within an accuracy of 50 mHartree on average, a limit set by the coherence time of the tunable coupler.

Published

2018

3. Adiabatic quantum simulations with driven superconducting qubits

Author

Roth, Marco, Moll, Nikolaj, Salis, Gian, Ganzhorn, Marc, Egger, Daniel J., Filipp, Stefan, and Schmidt, Sebastian

Subjects

Quantum Physics

Abstract

We propose a quantum simulator based on driven superconducting qubits where the interactions are generated parametrically by a polychromatic magnetic flux modulation of a tunable bus element. Using a time-dependent Schrieffer-Wolff transformation, we analytically derive a multi-qubit Hamiltonian which features independently tunable $XX$ and $YY$-type interactions as well as local bias fields over a large parameter range. We demonstrate the adiabatic simulation of the ground state of a hydrogen molecule using two superconducting qubits and one tunable bus element. The time required to reach chemical accuracy lies in the few microsecond range and therefore could be implemented on currently available superconducting circuits. Further applications of this technique may also be found in the simulation of interacting spin systems., Comment: 11 pages, 6 figures

Published

2018

4. Quantum algorithms for electronic structure calculations: particle/hole Hamiltonian and optimized wavefunction expansions

Author

Barkoutsos, Panagiotis Kl., Gonthier, Jerome F., Sokolov, Igor, Moll, Nikolaj, Salis, Gian, Fuhrer, Andreas, Ganzhorn, Marc, Egger, Daniel J., Troyer, Matthias, Mezzacapo, Antonio, Filipp, Stefan, and Tavernelli, Ivano

Subjects

Quantum Physics

Abstract

In this work we investigate methods to improve the efficiency and scalability of quantum algorithms for quantum chemistry applications. We propose a transformation of the electronic structure Hamiltonian in the second quantization framework into the particle-hole (p/h) picture, which offers a better starting point for the expansion of the trial wavefunction. The state of the molecular system at study is parametrized in a way to efficiently explore the sector of the molecular Fock space that contains the desired solution. To this end, we explore several trial wavefunctions to identify the most efficient parameterization of the molecular ground state. Taking advantage of known post-Hartree Fock quantum chemistry approaches and heuristic Hilbert space search quantum algorithms, we propose a new family of quantum circuits based on exchange-type gates that enable accurate calculations while keeping the gate count (i.e., the circuit depth) low. The particle-hole implementation of the Unitary Coupled Cluster (UCC) method within the Variational Quantum Eigensolver approach gives rise to an efficient quantum algorithm, named q-UCC , with important advantages compared to the straightforward 'translation' of the classical Coupled Cluster counterpart. In particular, we show how a single Trotter step can accurately and efficiently reproduce the ground state energies of simple molecular systems.

Published

2018

5. Entanglement generation in superconducting qubits using holonomic operations

Author

Egger, Daniel J., Ganzhorn, Marc, Salis, Gian, Fuhrer, Andreas, Mueller, Peter, Barkoutsos, Panagiotis Kl., Moll, Nikolaj, Tavernelli, Ivano, and Filipp, Stefan

Subjects

Quantum Physics

Abstract

We investigate a non-adiabatic holonomic operation that enables us to entangle two fixed-frequency superconducting transmon qubits attached to a common bus resonator. Two coherent microwave tones are applied simultaneously to the two qubits and drive transitions between the first excited resonator state and the second excited state of each qubit. The cyclic evolution within this effective 3-level $\Lambda$-system gives rise to a holonomic operation entangling the two qubits. Two-qubit states with 95\% fidelity, limited mainly by charge-noise of the current device, are created within $213~\rm{ns}$. This scheme is a step toward implementing a SWAP-type gate directly in an all-microwave controlled hardware platform. By extending the available set of two-qubit operations in the fixed-frequency qubit architecture, the proposed scheme may find applications in near-term quantum applications using variational algorithms to efficiently create problem-specific trial states.

Published

2018

6. Pulsed reset protocol for fixed-frequency superconducting qubits

Author

Egger, Daniel J., Werninghaus, Max, Ganzhorn, Marc, Salis, Gian, Fuhrer, Andreas, Mueller, Peter, and Filipp, Stefan

Subjects

Quantum Physics

Abstract

Improving coherence times of quantum bits is a fundamental challenge in the field of quantum computing. With long-lived qubits it becomes, however, inefficient to wait until the qubits have relaxed to their ground state after completion of an experiment. Moreover, for error-correction schemes it is import to rapidly re-initialize ancilla parity-check qubits. We present a simple pulsed qubit reset protocol based on a two-pulse sequence. A first pulse transfers the excited state population to a higher excited qubit state and a second pulse into a lossy environment provided by a low-Q transmission line resonator, which is also used for qubit readout. We show that the remaining excited state population can be suppressed to $2.2\pm0.8\%$ and utilize the pulsed reset protocol to carry out experiments at enhanced rates.

Published

2018

7. Advanced Fabrication of Single-crystal Diamond Membranes for Quantum Technologies

Author

Challier, Michel, Sonusen, Selda, Barfuss, Arne, Rohner, Dominik, Riedel, Daniel, Koelbl, Johannes, Ganzhorn, Marc, Appel, Patrick, Maletinsky, Patrick, and Neu, Elke

Subjects

Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Quantum Physics

Abstract

Many promising applications of single crystal diamond and its color centers as sensor platform and in photonics require free-standing membranes with a thickness ranging from several micrometers to the few 100 nm range. In this work, we present an approach to conveniently fabricate such thin membranes with up to about one millimeter in size. We use commercially available diamond plates (thickness 50 $\mu$m) in an inductively coupled reactive ion etching process which is based on argon, oxygen and SF$_6$. We thus avoid using toxic, corrosive feed gases and add an alternative to previously presented recipes involving chlorine-based etching steps. Our membranes are smooth (RMS roughness <1 nm) and show moderate thickness variation (central part: <1 $\mu$m over $\approx \,$200x200 $\mu$m$^2$). Due to an improved etch mask geometry, our membranes stay reliably attached to the diamond plate in our chlorine-based as well as SF$_6$-based processes. Our results thus open the route towards higher reliability in diamond device fabrication and up-scaling., Comment: 9 pages, 4 figures, version 2 accepted for publication in MDPI micromachines

Published

2018

8. Quantum optimization using variational algorithms on near-term quantum devices

Author

Moll, Nikolaj, Barkoutsos, Panagiotis, Bishop, Lev S., Chow, Jerry M., Cross, Andrew, Egger, Daniel J., Filipp, Stefan, Fuhrer, Andreas, Gambetta, Jay M., Ganzhorn, Marc, Kandala, Abhinav, Mezzacapo, Antonio, Müller, Peter, Riess, Walter, Salis, Gian, Smolin, John, Tavernelli, Ivano, and Temme, Kristan

Subjects

Quantum Physics

Abstract

Universal fault-tolerant quantum computers will require error-free execution of long sequences of quantum gate operations, which is expected to involve millions of physical qubits. Before the full power of such machines will be available, near-term quantum devices will provide several hundred qubits and limited error correction. Still, there is a realistic prospect to run useful algorithms within the limited circuit depth of such devices. Particularly promising are optimization algorithms that follow a hybrid approach: the aim is to steer a highly entangled state on a quantum system to a target state that minimizes a cost function via variation of some gate parameters. This variational approach can be used both for classical optimization problems as well as for problems in quantum chemistry. The challenge is to converge to the target state given the limited coherence time and connectivity of the qubits. In this context, the quantum volume as a metric to compare the power of near-term quantum devices is discussed. With focus on chemistry applications, a general description of variational algorithms is provided and the mapping from fermions to qubits is explained. Coupled-cluster and heuristic trial wave-functions are considered for efficiently finding molecular ground states. Furthermore, simple error-mitigation schemes are introduced that could improve the accuracy of determining ground-state energies. Advancing these techniques may lead to near-term demonstrations of useful quantum computation with systems containing several hundred qubits., Comment: Contribution to the special issue of Quantum Science & Technology on "What would you do with 1000 qubits"

Published

2017

9. Analysis of parametrically driven exchange-type (iSWAP) and two-photon (bSWAP) interactions between superconducting qubits

Author

Roth, Marco, Ganzhorn, Marc, Moll, Nikolaj, Filipp, Stefan, Salis, Gian, and Schmidt, Sebastian

Subjects

Quantum Physics

Abstract

A current bottleneck for quantum computation is the realization of high-fidelity two-qubit quantum operations between two and more quantum bits in arrays of coupled qubits. Gates based on parametrically driven tunable couplers offer a convenient method to entangle multiple qubits by selectively activating different interaction terms in the effective Hamiltonian. Here, we study theoretically and experimentally a superconducting qubit setup with two transmon qubits connected via a capacitively coupled tunable bus. We develop a time-dependent Schrieffer-Wolff transformation and derive analytic expressions for exchange-interaction gates swapping excitations between the qubits (iSWAP) and for two-photon gates creating and annihilating simultaneous two-qubit excitations (bSWAP). We find that the bSWAP gate is generally slower than the more commonly used iSWAP gate, but features favorable scalability properties with less severe frequency crowding effects, which typically degrade the fidelity in multi-qubit setups. Our theoretical results are backed by experimental measurements as well as exact numerical simulations including the effects of higher transmon levels and dissipation., Comment: 10 pages, 5 figures

Published

2017

10. Fabrication of all diamond scanning probes for nanoscale magnetometry

Author

Appel, Patrick, Neu, Elke, Ganzhorn, Marc, Barfuss, Arne, Batzer, Marietta, Gratz, Micha, Tschöpe, Andreas, and Maletinsky, Patrick

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The electronic spin of the nitrogen vacancy (NV) center in diamond forms an atomically sized, highly sensitive sensor for magnetic fields. To harness the full potential of individual NV centers for sensing with high sensitivity and nanoscale spatial resolution, NV centers have to be incorporated into scanning probe structures enabling controlled scanning in close proximity to the sample surface. Here, we present an optimized procedure to fabricate single-crystal, all-diamond scanning probes starting from commercially available diamond and show a highly efficient and robust approach for integrating these devices in a generic atomic force microscope. Our scanning probes consisting of a scanning nanopillar (200 nm diameter, $1-2\,\mu$m length) on a thin ($< 1\mu$m) cantilever structure, enable efficient light extraction from diamond in combination with a high magnetic field sensitivity ($\mathrm{\eta_{AC}}\approx50\pm20\,\mathrm{nT}/\sqrt{\mathrm{Hz}}$). As a first application of our scanning probes, we image the magnetic stray field of a single Ni nanorod. We show that this stray field can be approximated by a single dipole and estimate the NV-to-sample distance to a few tens of nanometer, which sets the achievable resolution of our scanning probes.

Published

2016

11. Quantitative nanoscale vortex-imaging using a cryogenic quantum magnetometer

Author

Thiel, Lucas, Rohner, Dominik, Ganzhorn, Marc, Appel, Patrick, Neu, Elke, Müller, Benedikt, Kleiner, Reinhold, Koelle, Dieter, and Maletinsky, Patrick

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Microscopic studies of superconductors and their vortices play a pivotal role in our understanding of the mechanisms underlying superconductivity. Local measurements of penetration depths or magnetic stray-fields enable access to fundamental aspects of superconductors such as nanoscale variations of superfluid densities or the symmetry of their order parameter. However, experimental tools, which offer quantitative, nanoscale magnetometry and operate over the large range of temperature and magnetic fields relevant to address many outstanding questions in superconductivity, are still missing. Here, we demonstrate quantitative, nanoscale magnetic imaging of Pearl vortices in the cuprate superconductor YBCO, using a scanning quantum sensor in form of a single Nitrogen-Vacancy (NV) electronic spin in diamond. The sensor-to-sample distance of ~10nm we achieve allows us to observe striking deviations from the prevalent monopole approximation in our vortex stray-field images, while we find excellent quantitative agreement with Pearl's analytic model. Our experiments yield a non-invasive and unambiguous determination of the system's local London penetration depth, and are readily extended to higher temperatures and magnetic fields. These results demonstrate the potential of quantitative quantum sensors in benchmarking microscopic models of complex electronic systems and open the door for further exploration of strongly correlated electron physics using scanning NV magnetometry., Comment: Main text (5 pages, 4 figures) plus supplementary material (5 pages, 6 figures). Comments welcome. Further information under http://www.quantum-sensing.ch

Published

2015

12. Nanoscale microwave imaging with a single electron spin in diamond

Author

Appel, Patrick, Ganzhorn, Marc, Neu, Elke, and Maletinsky, Patrick

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report on imaging of microwave (MW) magnetic fields using a magnetometer based on the electron spin of a nitrogen vacancy center in diamond. We quantitatively image the magnetic field generated by high frequency (GHz) MW current with nanoscale resolution using a scanning probe technique. We demonstrate a MW magnetic field sensitivity in the range of a few nT/$\sqrt{\text{Hz}}$, polarization selection and broadband capabilities under ambient conditions and thereby establish the nitrogen vacancy center a versatile and high performance tool for the detection of MW fields. As a first application of this scanning MW detector, we determine the MW current density in a stripline and demonstrate a MW current sensitivity of a few nA/$\sqrt{\text{Hz}}$

Published

2015

13. Photonic nano-structures on (111) oriented diamond

Author

Neu, Elke, Appel, Patrick, Ganzhorn, Marc, Miguel-Sanchez, Javier, Lesik, Margarita, Mille, Vianney, Jacques, Vincent, Tallaire, Alexandre, Achard, Jocelyn, and Maletinsky, Patrick

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We demonstrate the fabrication of single-crystalline diamond nanopillars on a (111)-oriented chemical vapor deposited diamond substrate. This crystal orientation offers optimal coupling of nitrogen-vacancy (NV) center emission to the nanopillar mode and is thus advantageous over previous approaches. We characterize single native NV centers in these nanopillars and find one of the highest reported saturated fluorescence count rates in single crystalline diamond in excess of 10${}^6$ counts per second. We show that our nano-fabrication procedure conserves the preferential alignment as well as the spin coherence of the NVs in our structures. Our results will enable a new generation of highly sensitive probes for NV magnetometry and pave the way toward photonic crystals with optimal orientation of the NV center's emission dipole., Comment: 4 pages original manuscript, 3 pages supplementary material

Published

2014

14. Dynamics and Dissipation induced by Single-Electron Tunneling in Carbon Nanotube Nanoelectromechanical Systems

Author

Ganzhorn, Marc and Wernsdorfer, Wolfgang

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We demonstrate the effect of single-electron tunneling (SET) through a carbon nanotube quantum dot on its nanomechanical motion. We find that the frequency response and the dissipation of the nanoelectromechanical system (NEMS) to SET strongly depends on the electronic environment of the quantum dot, in particular on the total dot capacitance and the tunnel coupling to the metal contacts. Our findings suggest that one could achieve quality factors of 10$^{6}$ or higher by choosing appropriate gate dielectrics and/or by improving the tunnel coupling to the leads.

Published

2012

15. Molecular Quantum Spintronics Using Single-Molecule Magnets

Author

Ganzhorn, Marc, Wernsdorfer, Wolfgang, Avouris, Phaedon, Series editor, Bhushan, Bharat, Series editor, Bimberg, Dieter, Series editor, von von Klitzing, Klaus, Series editor, Sakaki, Hiroyuki, Series editor, Wiesendanger, Roland, Series editor, Bartolomé, Juan, editor, Luis, Fernando, editor, and Fernández, Julio F., editor

Published

2014

16. Time-resolved tomography of a driven adiabatic quantum simulation

Author

Salis, Gian, primary, Moll, Nikolaj, additional, Roth, Marco, additional, Ganzhorn, Marc, additional, and Filipp, Stefan, additional

Published

2020

17. Adiabatic quantum simulations with driven superconducting qubits

Author

Roth, Marco, primary, Moll, Nikolaj, additional, Salis, Gian, additional, Ganzhorn, Marc, additional, Egger, Daniel J., additional, Filipp, Stefan, additional, and Schmidt, Sebastian, additional

Published

2019

18. Quantum algorithms for electronic structure calculations: Particle-hole Hamiltonian and optimized wave-function expansions

Author

Barkoutsos, Panagiotis Kl., primary, Gonthier, Jerome F., additional, Sokolov, Igor, additional, Moll, Nikolaj, additional, Salis, Gian, additional, Fuhrer, Andreas, additional, Ganzhorn, Marc, additional, Egger, Daniel J., additional, Troyer, Matthias, additional, Mezzacapo, Antonio, additional, Filipp, Stefan, additional, and Tavernelli, Ivano, additional

Published

2018

19. Quantum optimization using variational algorithms on near-term quantum devices

Author

Moll, Nikolaj, primary, Barkoutsos, Panagiotis, additional, Bishop, Lev S, additional, Chow, Jerry M, additional, Cross, Andrew, additional, Egger, Daniel J, additional, Filipp, Stefan, additional, Fuhrer, Andreas, additional, Gambetta, Jay M, additional, Ganzhorn, Marc, additional, Kandala, Abhinav, additional, Mezzacapo, Antonio, additional, Müller, Peter, additional, Riess, Walter, additional, Salis, Gian, additional, Smolin, John, additional, Tavernelli, Ivano, additional, and Temme, Kristan, additional

Published

2018

20. Erratum: Analysis of a parametrically driven exchange-type gate and a two-photon excitation gate between superconducting qubits [Phys. Rev. A 96 , 062323 (2017)]

Author

Roth, Marco, primary, Ganzhorn, Marc, additional, Moll, Nikolaj, additional, Filipp, Stefan, additional, Salis, Gian, additional, and Schmidt, Sebastian, additional

Published

2018

21. Advanced Fabrication of Single-Crystal Diamond Membranes for Quantum Technologies

Author

Challier, Michel, primary, Sonusen, Selda, additional, Barfuss, Arne, additional, Rohner, Dominik, additional, Riedel, Daniel, additional, Koelbl, Johannes, additional, Ganzhorn, Marc, additional, Appel, Patrick, additional, Maletinsky, Patrick, additional, and Neu, Elke, additional

Published

2018

22. Analysis of a parametrically driven exchange-type gate and a two-photon excitation gate between superconducting qubits

Author

Roth, Marco, primary, Ganzhorn, Marc, additional, Moll, Nikolaj, additional, Filipp, Stefan, additional, Salis, Gian, additional, and Schmidt, Sebastian, additional

Published

2017

23. Fabrication of all diamond scanning probes for nanoscale magnetometry

Author

Appel, Patrick, primary, Neu, Elke, additional, Ganzhorn, Marc, additional, Barfuss, Arne, additional, Batzer, Marietta, additional, Gratz, Micha, additional, Tschöpe, Andreas, additional, and Maletinsky, Patrick, additional

Published

2016

24. Quantum Einstein-de Haas effect

Author

Ganzhorn, Marc, primary, Klyatskaya, Svetlana, additional, Ruben, Mario, additional, and Wernsdorfer, Wolfgang, additional

Published

2016

25. Coupling magnetism and mechanics at a molecular level

Author

Ganzhorn, Marc, Institut Néel (NEEL), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF), Université de Grenoble, Wolfgang Wernsdorfer, and STAR, ABES

Subjects

NEMS, Quantum tunneling of magnetization, Single-Molecule Magnet, [PHYS.PHYS]Physics [physics]/Physics [physics], Molecule aimant, Nano-mecanical resonator, Effet tunnel de l'aimantation, [PHYS.PHYS] Physics [physics]/Physics [physics], Molecular Spintronics, Nanorésonateur mécanique, Nanotube de carbone, Carbon nanotube, Spintronique moléculaire

Abstract

In this manuscript, we will first present the ultimate molecular building block for spintronic devices, so called single-molecule magnets (Chapter 2). In particular we will focus on a TbPc2 complex and various approaches of probing its magnetization using carbon nanotube detectors and different coupling mechanisms (magnetic flux, electronic and mechanical coupling). With the aim of building a supramolecular torque magnetometer capable of probing the magnetic moment of a molecular magnet, we will describe in Chapter 3 a promising candidate, a carbon nanotube nanoelectromechanical system (NEMS). We will first describe the advantages of carbon based NEMS over classical Si based resonators. Subsequently we will present the state of art of carbon nanotube NEMS and focus in particular on two different nanomechanical motions, a transverse bending mode and a longitudinal stretching mode. In Chapter 4, we present the experimental implementation of a supramolecular torque magnetometer based on carbon nanotube NEMS and single molecule magnets. We first describe the ultraclean bottom-up fabrication process and the extensive characterisation steps of carbon nanotube NEMS at room and cryogenic temperatures. We will finally demonstrate a method of grafting a TbPc2 single molecules magnet on such a carbon nanotube NEMS, that conserves both the magnetic properties of the molecule and the mechanical properties of the resonator. In Chapter 5, we will then perform a systematic study of the transverse bending mode vibration in a carbon nanotube NEMS. We demonstrate for instance, that the dissipation of a carbon nanotube's bending mode vibration to single electron tunneling through the carbon nanotube NEMS-quantum dot critically depends on the dot's electronic environment, i.e. the capacitance, the tunnel coupling to the metal leads, the current and temperature. The findings suggest that one could achieve quality factors of 10^6 or higher by choosing appropriate gate dielectrics and/or by improving the tunnel coupling to the leads, which would notably increase the sensitivity of the carbon nanotube NEMS with respect to a magnetic torque generate by a rotating molecular magnet. In Chapter 6, we demonstrate the presence of a quantized longitudinal stretching mode vibration in a carbon nanotube NEMS functionnalized with TbPc2 single molecule quantum magnets. We will in particular demonstrate that the quantum mechanical nature of both systems, results in a strong coupling between the longitudinal stretching mode and the magnetization of an individual TbPc2 single molecule magnet grafted to the carbon nanotube's sidewall. The strong coupling in fact enables the detection of the nuclear spin states in the TbPc2 molecule. Finally, we present in the conclusion of this manuscript some future prospects for the detection and (coherent) manipulation of a single (nuclear) spin using a mechanical quantum system., Dans ce manuscrit, nous présentons d'abord le bloc de construction moléculaire ultime pour les dispositifs de spintronique, les aimants à molécule unique (Chapitre 2). En particulier, nous nous concentrerons sur une molecule de TbPc2 et différentes approches pour sonder son aimantation à l'aide de détecteurs a base de nanotubes de carbone et de mécanismes de couplage différents (flux magnétique, couplage électronique et mécanique). Dans le but de construire un detecteur de torque supramoléculaire capable de sonder le moment magnétique d'un aimant moléculaire, nous allons décrire dans le chapitre 3 un candidat très prometteur, un système nanoélectromécanique (NEMS) à base d'un nanotube de carbone. Nous décrirons d'abord les avantages de NEMS à base de carbone par rapport aux résonateurs classiques à base de silicium. Par la suite, nous présenterons l'état de l'art des NEMS à base de nanotubes de carbone, en nous focalisant en particulier sur deux différents mouvements nanomécaniques, un mode de flexion transverse et un mode de compression longitudinal. Dans le chapitre 4, nous présenterons la mise en oeuvre expérimentale d'un detecteur de torque supramoléculaire basé sur NEMS à nanotubes de carbone et des aimants à molécule unique. Nous décrirons d'abord le processus de fabrication ultra propre et les étapes de la caractérisation d'un NEMS à nanotubes de carbone à températures ambiante et cryogénique. Nous allons ensuite démontrer un procédé de greffage d'une molécule aimants de TbPc2 sur un tel NEMS à nanotube de carbone, qui conserve à la fois les propriétés magnétiques de la molécule et les propriétés mécaniques du résonateur. Dans le chapitre 5, nous allons ensuite procéder à une étude systématique du mode de flexion transverse dans un NEMS à nanotube de carbone. Nous montrerons, que la dissipation de ce mode de vibration induit par l'effet tunnel d'électron unique à travers le nanotube de carbone (considére comme point quantique) dépend essentiellement de l'environnement électronique du nanotube, c'est à dire de la capacité, du couplage entre le nanotube de carbone et les electrodes métalliqes, du courant et de la température. Les résultats indiquent que l'on pourrait atteindre des facteurs de qualité de 10^6 ou plus en choisissant un diélectrique de grille appropriées et/ou en améliorant le couplage entre le nanotube de carbone et les electrodes, ce qui permettrait notamment d'augmenter la sensibilité du NEMS nanotubes de carbone par rapport à un torque magnétique générer par le retournement d'un aimant moléculaire. Dans le chapitre 6, nous démontrons la présence d'un mode de vibration longitudinal quantique dans un NEMS à base de nanotube de carbon fonctionnalisé avec des aimants moléculaires de TbPc2. Nous allons en particulier montrer que la nature quantique des deux systèmes, se traduit par un fort couplage entre le mode de compression longitudinal et l'aimantation d'un aimant moléculaire TbPc2 unique greffé sur la parois du nanotube de carbone. Ce fort couplage permet par la suite de détecter les états de spin nucléaire dans la molécule de TbPc2. Enfin, nous présenterons dans la conclusion de ce manuscrit quelques perspectives pour la détection et la manipulation (coherente) d'un seul spin (nucléaire) à l'aide d'un système mécanique quantique.

Published

2013

26. Couplage de systèmes magnétiques et mécaniques à échelle moléculaire

Author

Ganzhorn, Marc, Institut Néel (NEEL), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF), Université de Grenoble, and Wolfgang Wernsdorfer

Subjects

NEMS, Quantum tunneling of magnetization, Single-Molecule Magnet, [PHYS.PHYS]Physics [physics]/Physics [physics], Molecule aimant, Nano-mecanical resonator, Effet tunnel de l'aimantation, Molecular Spintronics, Nanorésonateur mécanique, Nanotube de carbone, Carbon nanotube, Spintronique moléculaire

Abstract

In this manuscript, we will first present the ultimate molecular building block for spintronic devices, so called single-molecule magnets (Chapter 2). In particular we will focus on a TbPc2 complex and various approaches of probing its magnetization using carbon nanotube detectors and different coupling mechanisms (magnetic flux, electronic and mechanical coupling). With the aim of building a supramolecular torque magnetometer capable of probing the magnetic moment of a molecular magnet, we will describe in Chapter 3 a promising candidate, a carbon nanotube nanoelectromechanical system (NEMS). We will first describe the advantages of carbon based NEMS over classical Si based resonators. Subsequently we will present the state of art of carbon nanotube NEMS and focus in particular on two different nanomechanical motions, a transverse bending mode and a longitudinal stretching mode. In Chapter 4, we present the experimental implementation of a supramolecular torque magnetometer based on carbon nanotube NEMS and single molecule magnets. We first describe the ultraclean bottom-up fabrication process and the extensive characterisation steps of carbon nanotube NEMS at room and cryogenic temperatures. We will finally demonstrate a method of grafting a TbPc2 single molecules magnet on such a carbon nanotube NEMS, that conserves both the magnetic properties of the molecule and the mechanical properties of the resonator. In Chapter 5, we will then perform a systematic study of the transverse bending mode vibration in a carbon nanotube NEMS. We demonstrate for instance, that the dissipation of a carbon nanotube's bending mode vibration to single electron tunneling through the carbon nanotube NEMS-quantum dot critically depends on the dot's electronic environment, i.e. the capacitance, the tunnel coupling to the metal leads, the current and temperature. The findings suggest that one could achieve quality factors of 10^6 or higher by choosing appropriate gate dielectrics and/or by improving the tunnel coupling to the leads, which would notably increase the sensitivity of the carbon nanotube NEMS with respect to a magnetic torque generate by a rotating molecular magnet. In Chapter 6, we demonstrate the presence of a quantized longitudinal stretching mode vibration in a carbon nanotube NEMS functionnalized with TbPc2 single molecule quantum magnets. We will in particular demonstrate that the quantum mechanical nature of both systems, results in a strong coupling between the longitudinal stretching mode and the magnetization of an individual TbPc2 single molecule magnet grafted to the carbon nanotube's sidewall. The strong coupling in fact enables the detection of the nuclear spin states in the TbPc2 molecule. Finally, we present in the conclusion of this manuscript some future prospects for the detection and (coherent) manipulation of a single (nuclear) spin using a mechanical quantum system.; Dans ce manuscrit, nous présentons d'abord le bloc de construction moléculaire ultime pour les dispositifs de spintronique, les aimants à molécule unique (Chapitre 2). En particulier, nous nous concentrerons sur une molecule de TbPc2 et différentes approches pour sonder son aimantation à l'aide de détecteurs a base de nanotubes de carbone et de mécanismes de couplage différents (flux magnétique, couplage électronique et mécanique). Dans le but de construire un detecteur de torque supramoléculaire capable de sonder le moment magnétique d'un aimant moléculaire, nous allons décrire dans le chapitre 3 un candidat très prometteur, un système nanoélectromécanique (NEMS) à base d'un nanotube de carbone. Nous décrirons d'abord les avantages de NEMS à base de carbone par rapport aux résonateurs classiques à base de silicium. Par la suite, nous présenterons l'état de l'art des NEMS à base de nanotubes de carbone, en nous focalisant en particulier sur deux différents mouvements nanomécaniques, un mode de flexion transverse et un mode de compression longitudinal. Dans le chapitre 4, nous présenterons la mise en oeuvre expérimentale d'un detecteur de torque supramoléculaire basé sur NEMS à nanotubes de carbone et des aimants à molécule unique. Nous décrirons d'abord le processus de fabrication ultra propre et les étapes de la caractérisation d'un NEMS à nanotubes de carbone à températures ambiante et cryogénique. Nous allons ensuite démontrer un procédé de greffage d'une molécule aimants de TbPc2 sur un tel NEMS à nanotube de carbone, qui conserve à la fois les propriétés magnétiques de la molécule et les propriétés mécaniques du résonateur. Dans le chapitre 5, nous allons ensuite procéder à une étude systématique du mode de flexion transverse dans un NEMS à nanotube de carbone. Nous montrerons, que la dissipation de ce mode de vibration induit par l'effet tunnel d'électron unique à travers le nanotube de carbone (considére comme point quantique) dépend essentiellement de l'environnement électronique du nanotube, c'est à dire de la capacité, du couplage entre le nanotube de carbone et les electrodes métalliqes, du courant et de la température. Les résultats indiquent que l'on pourrait atteindre des facteurs de qualité de 10^6 ou plus en choisissant un diélectrique de grille appropriées et/ou en améliorant le couplage entre le nanotube de carbone et les electrodes, ce qui permettrait notamment d'augmenter la sensibilité du NEMS nanotubes de carbone par rapport à un torque magnétique générer par le retournement d'un aimant moléculaire. Dans le chapitre 6, nous démontrons la présence d'un mode de vibration longitudinal quantique dans un NEMS à base de nanotube de carbon fonctionnalisé avec des aimants moléculaires de TbPc2. Nous allons en particulier montrer que la nature quantique des deux systèmes, se traduit par un fort couplage entre le mode de compression longitudinal et l'aimantation d'un aimant moléculaire TbPc2 unique greffé sur la parois du nanotube de carbone. Ce fort couplage permet par la suite de détecter les états de spin nucléaire dans la molécule de TbPc2. Enfin, nous présenterons dans la conclusion de ce manuscrit quelques perspectives pour la détection et la manipulation (coherente) d'un seul spin (nucléaire) à l'aide d'un système mécanique quantique.

Published

2013

27. Nanoscale microwave imaging with a single electron spin in diamond

Author

Appel, Patrick, primary, Ganzhorn, Marc, additional, Neu, Elke, additional, and Maletinsky, Patrick, additional

Published

2015

28. Photonic nano-structures on (111)-oriented diamond

Author

Neu, Elke, primary, Appel, Patrick, additional, Ganzhorn, Marc, additional, Miguel-Sánchez, Javier, additional, Lesik, Margarita, additional, Mille, Vianney, additional, Jacques, Vincent, additional, Tallaire, Alexandre, additional, Achard, Jocelyn, additional, and Maletinsky, Patrick, additional

Published

2014

29. Carbon Nanotube Nanoelectromechanical Systems as Magnetometers for Single-Molecule Magnets

Author

Ganzhorn, Marc, primary, Klyatskaya, Svetlana, additional, Ruben, Mario, additional, and Wernsdorfer, Wolfgang, additional

Published

2013

30. Strong spin–phonon coupling between a single-molecule magnet and a carbon nanotube nanoelectromechanical system

Author

Ganzhorn, Marc, primary, Klyatskaya, Svetlana, additional, Ruben, Mario, additional, and Wernsdorfer, Wolfgang, additional

Published

2013

31. Dynamics and Dissipation Induced by Single-Electron Tunneling in Carbon Nanotube Nanoelectromechanical Systems

Author

Ganzhorn, Marc, primary and Wernsdorfer, Wolfgang, additional

Published

2012

32. A Scalable, CMOS‐Compatible Assembly of Ambipolar Semiconducting Single‐Walled Carbon Nanotube Devices

Author

Ganzhorn, Marc, primary, Vijayaraghavan, Aravind, additional, Green, Alexander A., additional, Dehm, Simone, additional, Voigt, Achim, additional, Rapp, Michael, additional, Hersam, Mark C., additional, and Krupke, Ralph, additional

Published

2011

33. Hydrogen Sensing with Diameter- and Chirality-Sorted Carbon Nanotubes

Author

Ganzhorn, Marc, primary, Vijayaraghavan, Aravind, additional, Dehm, Simone, additional, Hennrich, Frank, additional, Green, Alexander A., additional, Fichtner, Maximilian, additional, Voigt, Achim, additional, Rapp, Michael, additional, von Löhneysen, Hilbert, additional, Hersam, Mark C., additional, Kappes, Manfred M., additional, and Krupke, Ralph, additional

Published

2011

34. Toward Single-Chirality Carbon Nanotube Device Arrays

Author

Vijayaraghavan, Aravind, primary, Hennrich, Frank, additional, Stürzl, Ninette, additional, Engel, Michael, additional, Ganzhorn, Marc, additional, Oron-Carl, Matti, additional, Marquardt, Christoph W., additional, Dehm, Simone, additional, Lebedkin, Sergei, additional, Kappes, Manfred M., additional, and Krupke, Ralph, additional

Published

2010

35. Nanoscale microwave imaging with a single electron spin in diamond

Author

Appel, Patrick, Ganzhorn, Marc, Neu, Elke, and Maletinsky, Patrick

Subjects

7. Clean energy

36. Low-loss broadband antenna for efficient photon collection from a coherent spin in diamond

Author

Riedel, Daniel, Rohner, Dominik, Ganzhorn, Marc, Kaldewey, Timo, Appel, Patrick, Neu, Elke, Warburton, Richard J., and Maletinsky, Patrick M.

Subjects

7. Clean energy, 3. Good health