Your search keyword '"Pomarico E"' showing total 8 results

1. Laser-Induced Skyrmion Writing and Erasing in an Ultrafast Cryo-Lorentz Transmission Electron Microscope

Author

Berruto, G, Madan, I, Murooka, Y, Vanacore, G, Pomarico, E, Rajeswari, J, Lamb, R, Huang, P, Kruchkov, A, Togawa, Y, Lagrange, T, Mcgrouther, D, Ronnow, H, Carbone, F, Berruto G, Madan I, Murooka Y, Vanacore G, Pomarico E, Rajeswari J, Lamb R, Huang P, Kruchkov AJ, Togawa Y, LaGrange T, McGrouther D, Ronnow HM, Carbone F, Berruto, G, Madan, I, Murooka, Y, Vanacore, G, Pomarico, E, Rajeswari, J, Lamb, R, Huang, P, Kruchkov, A, Togawa, Y, Lagrange, T, Mcgrouther, D, Ronnow, H, Carbone, F, Berruto G, Madan I, Murooka Y, Vanacore G, Pomarico E, Rajeswari J, Lamb R, Huang P, Kruchkov AJ, Togawa Y, LaGrange T, McGrouther D, Ronnow HM, and Carbone F

Abstract

We demonstrate that light-induced heat pulses of different duration and energy can write Skyrmions in a broad range of temperatures and magnetic field in FeGe. Using a combination of camera-rate and pump-probe cryo-Lorentz transmission electron microscopy, we directly resolve the spatiotemporal evolution of the magnetization ensuing optical excitation. The Skyrmion lattice was found to maintain its structural properties during the laser-induced demagnetization, and its recovery to the initial state happened in the sub-mu s to mu s range, depending on the cooling rate of the system

Published

2018

2. Photon-induced far-field and near-field electron microscopy

Author

Wang, K, Vanacore, G, Pomarico, E, Madan, I, Berruto, G, de Abajo, F, Kaminer, I, Carbone, F, Wang K., Vanacore G. M., Pomarico E., Madan I., Berruto G., de Abajo F. J. G., Kaminer I., Carbone F., Wang, K, Vanacore, G, Pomarico, E, Madan, I, Berruto, G, de Abajo, F, Kaminer, I, Carbone, F, Wang K., Vanacore G. M., Pomarico E., Madan I., Berruto G., de Abajo F. J. G., Kaminer I., and Carbone F.

Abstract

We present developments in the technique of photo-induced near-field electron microscopy. (PINEM) We image the electron interaction with a far-field plane wave reflected from a mirror, and with the near-field resonance of a plasmonic nanowire.

Published

2018

3. Holographic imaging of electromagnetic fields via electron-light quantum interference

Author

Madan, I, Vanacore, G, Pomarico, E, Berruto, G, Lamb, R, Mcgrouther, D, Lummen, T, Latychevskaia, T, Garcia de Abajo, F, Carbone, F, VANACORE, GIOVANNI MARIA, Lamb, RJ, McGrouther, D, Lummen, TTA, Garcia de Abajo, FJ, Madan, I, Vanacore, G, Pomarico, E, Berruto, G, Lamb, R, Mcgrouther, D, Lummen, T, Latychevskaia, T, Garcia de Abajo, F, Carbone, F, VANACORE, GIOVANNI MARIA, Lamb, RJ, McGrouther, D, Lummen, TTA, and Garcia de Abajo, FJ

Abstract

Holography relies on the interference between a known reference and a signal of interest to reconstruct both the amplitude and the phase of that signal. With electrons, the extension of holography to the ultrafast time domain remains a challenge, although it would yield the highest possible combined spatiotemporal resolution. Here, we show that holograms of local electromagnetic fields can be obtained with combined attosecond/nanometer resolution in an ultrafast transmission electron microscope (UEM). Unlike conventional holography, where signal and reference are spatially separated and then recombined to interfere, our method relies on electromagnetic fields to split an electron wave function in a quantum coherent superposition of different energy states. In the image plane, spatial modulation of the electron energy distribution reflects the phase relation between reference and signal fields. Beyond imaging applications, this approach allows implementing quantum measurements in parallel, providing an efficient and versatile tool for electron quantum optics.

Published

2019

4. Ultrafast generation and control of an electron vortex beam via chiral plasmonic near fields

Author

Vanacore, G, Berruto, G, Madan, I, Pomarico, E, Biagioni, P, Lamb, R, Mcgrouther, D, Reinhardt, O, Kaminer, I, Barwick, B, Larocque, H, Grillo, V, Karimi, E, Garcia de Abajo, F, Carbone, F, Lamb, R J, McGrouther, D, Garcia de Abajo, FJ, Vanacore, G, Berruto, G, Madan, I, Pomarico, E, Biagioni, P, Lamb, R, Mcgrouther, D, Reinhardt, O, Kaminer, I, Barwick, B, Larocque, H, Grillo, V, Karimi, E, Garcia de Abajo, F, Carbone, F, Lamb, R J, McGrouther, D, and Garcia de Abajo, FJ

Abstract

Vortex-carrying matter waves, such as chiral electron beams, are of significant interest in both applied and fundamental science. Continuous-wave electron vortex beams are commonly prepared via passive phase masks imprinting a transverse phase modulation on the electron's wavefunction. Here, we show that femtosecond chiral plasmonic near fields enable the generation and dynamic control on the ultrafast timescale of an electron vortex beam. The vortex structure of the resulting electron wavepacket is probed in both real and reciprocal space using ultrafast transmission electron microscopy. This method offers a high degree of scalability to small length scales and a highly efficient manipulation of the electron vorticity with attosecond precision. Besides the direct implications in the investigation of nanoscale ultrafast processes in which chirality plays a major role, we further discuss the perspectives of using this technique to shape the wavefunction of charged composite particles, such as protons, and how it can be used to probe their internal structure

Published

2019

5. meV Resolution in Laser-Assisted Energy-Filtered Transmission Electron Microscopy

Author

Pomarico, E, Madan, I, Berruto, G, Vanacore, G, Wang, K, Kaminer, I, de Abajo, F, Carbone, F, Wang, KP, de Abajo, FJG, Pomarico, E, Madan, I, Berruto, G, Vanacore, G, Wang, K, Kaminer, I, de Abajo, F, Carbone, F, Wang, KP, and de Abajo, FJG

Abstract

The electronic, optical, and magnetic properties of quantum solids are determined by their low-energy (<100 meV) many-body excitations. Dynamical characterization and manipulation of such excitations rely on tools that combine nm-spatial, fs-temporal, and meV-spectral resolution. Currently, phonons and collective plasmon resonances can be imaged in nanostructures with atomic (sub-nm) and tens of meV space/energy resolution using state-of-the-art energy-filtered transmission electron microscopy (TEM), but only under static conditions, while fs-resolved measurements are common but lack spatial or energy resolution. Here, we demonstrate a new method of spectrally resolved photon-induced near-field electron microscopy (SRPINEM) that allows us to obtain nm-fs-resolved maps of nanoparticle plasmons with an energy resolution determined by the laser line width (20 meV in this work) and no longer limited by the electron beam and spectrometer energy spreading. This technique can be extended to any optically accessible low-energy mode, thus pushing TEM to a previously unattainable spectral domain with an unprecedented combination of space, energy, and temporal resolution.

Published

2018

6. Attosecond coherent control of free-electron wave functions using semi-infinite light fields

Author

Vanacore, G, Madan, I, Berruto, G, Wang, K, Pomarico, E, Lamb, R, Mcgrouther, D, Kaminer, I, Barwick, B, de Abajo, F, Carbone, F, Lamb, RJ, McGrouther, D, de Abajo, FJG, Vanacore, G, Madan, I, Berruto, G, Wang, K, Pomarico, E, Lamb, R, Mcgrouther, D, Kaminer, I, Barwick, B, de Abajo, F, Carbone, F, Lamb, RJ, McGrouther, D, and de Abajo, FJG

Abstract

Light-electron interaction is the seminal ingredient in free-electron lasers and dynamical investigation of matter. Pushing the coherent control of electrons by light to the attosecond timescale and below would enable unprecedented applications in quantum circuits and exploration of electronic motions and nuclear phenomena. Here we demonstrate attosecond coherent manipulation of a free-electron wave function, and show that it can be pushed down to the zeptosecond regime. We make a relativistic single-electron wavepacket interact in free-space with a semi-infinite light field generated by two light pulses reflected from a mirror and delayed by fractions of the optical cycle. The amplitude and phase of the resulting electron-state coherent oscillations are mapped in energy-momentum space via momentum-resolved ultrafast electron spectroscopy. The experimental results are in full agreement with our analytical theory, which predicts access to the zeptosecond timescale by adopting semi-infinite X-ray pulses.

Published

2018

7. Applications of quantum cloning

Author

Pomarico, E., Sanguinetti, B., Sekatski, P., Zbinden, H., Gisin, N., Pomarico, E., Sanguinetti, B., Sekatski, P., Zbinden, H., and Gisin, N.

Abstract

Quantum Cloning Machines (QCMs) allow for the copying of information, within the limits imposed by quantum mechanics. These devices are particularly interesting in the high-gain regime, i.e., when one input qubit generates a state of many output qubits. In this regime, they allow for the study of certain aspects of the quantum to classical transition. The understanding of these aspects is the root of the two recent applications that we will review in this paper: the first one is the Quantum Cloning Radiometer, a device which is able to produce an absolute measure of spectral radiance. This device exploits the fact that in the quantum regime information can be copied with only finite fidelity, whereas when a state becomes macroscopic, this fidelity gradually increases to 1. Measuring the fidelity of the cloning operation then allows to precisely determine the absolute spectral radiance of the input optical source. We will then discuss whether a Quantum Cloning Machine could be used to produce a state visible by the naked human eye, and the possibility of a Bell Experiment with humans playing the role of detectors

Published

2018

8. Applications of quantum cloning

Author

Pomarico, E., Sanguinetti, B., Sekatski, P., Zbinden, H., Gisin, N., Pomarico, E., Sanguinetti, B., Sekatski, P., Zbinden, H., and Gisin, N.

Abstract

Quantum Cloning Machines (QCMs) allow for the copying of information, within the limits imposed by quantum mechanics. These devices are particularly interesting in the high-gain regime, i.e., when one input qubit generates a state of many output qubits. In this regime, they allow for the study of certain aspects of the quantum to classical transition. The understanding of these aspects is the root of the two recent applications that we will review in this paper: the first one is the Quantum Cloning Radiometer, a device which is able to produce an absolute measure of spectral radiance. This device exploits the fact that in the quantum regime information can be copied with only finite fidelity, whereas when a state becomes macroscopic, this fidelity gradually increases to 1. Measuring the fidelity of the cloning operation then allows to precisely determine the absolute spectral radiance of the input optical source. We will then discuss whether a Quantum Cloning Machine could be used to produce a state visible by the naked human eye, and the possibility of a Bell Experiment with humans playing the role of detectors