Your search keyword '"Cerullo G"' showing total 2,325 results

1. Identification of soft modes across the commensurate-to-incommensurate charge density wave transition in 1$T$-TaSe$_2$

Author

Ruggeri, M., Wolverson, D., Romano, V., Cerullo, G., Sayers, C. J., and D'Angelo, G.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

1$T$-TaSe$_2$ is a prototypical charge density wave (CDW) material for which electron-phonon coupling and associated lattice distortion play an important role in driving and stabilizing the CDW phase. Here, we investigate the lattice dynamics of bulk 1$T$-TaSe$_2$ using angle-resolved ultralow wavenumber Raman spectroscopy down to 10 cm$^{-1}$. Our high-resolution spectra allow us to identify at least 27 Raman-active modes in the commensurate (CCDW) phase. Contrary to other layered materials, we do not find evidence of interlayer breathing or shear modes, suggestive of $AA$ stacking in the bulk, or sufficiently weak interlayer coupling. Polarization dependence of the mode intensities allows the assignment of their symmetry, which is supported by first-principles calculations of the phonons for the bulk structure using density functional theory. A detailed temperature dependence in the range $T$ = 80 - 500 K allows us to identify soft modes associated with the CDW superlattice. Upon entering the incommensurate (ICCDW) phase above 473 K, we observe a dramatic loss of resolution of all modes, and significant linewidth broadening associated with a reduced phonon lifetime as the charge-order becomes incommensurate with the lattice., Comment: 8 pages, 3 figures, supplemental material

Published

2024

2. Exploring the Charge Density Wave phase of 1$T$-TaSe$_2$: Mott or Charge-transfer Gap?

Author

Sayers, C. J., Cerullo, G., Zhang, Y., Sanders, C. E., Chapman, R. T., Wyatt, A. S., Chatterjee, G., Springate, E., Wolverson, D., Da Como, E., and Carpene, E.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

1$T$-TaSe$_2$ is widely believed to host a Mott metal-insulator transition in the charge density wave (CDW) phase according to the spectroscopic observation of a band gap that extends across all momentum space. Previous investigations inferred that the occurrence of the Mott phase is limited to the surface only of bulk specimens, but recent analysis on thin samples revealed that the Mott-like behavior, observed in the monolayer, is rapidly suppressed with increasing thickness. Here, we report combined time- and angle-resolved photoemission spectroscopy and theoretical investigations of the electronic structure of 1$T$-TaSe$_2$. Our experimental results confirm the existence of a state above $E_F$, previously ascribed to the upper Hubbard band, and an overall band gap of $\sim 0.7$ eV at $\overline{\Gamma}$. However, supported by density functional theory calculations, we demonstrate that the origin of this state and the gap rests on band structure modifications induced by the CDW phase alone, without the need for Mott correlation effects., Comment: Accepted by PRL

Published

2023

3. A Stimulated Raman Loss spectrometer for metrological studies of quadrupole lines of hydrogen isotopologues

Author

Lamperti, M., Rutkowski, L., Gatti, D., Gotti, R., Moretti, L., Polli, D., Cerullo, G., and Marangoni, M.

Subjects

Physics - Optics

Abstract

We discuss layout and performance of a high-resolution Stimulated Raman Loss spectrometer that has been newly developed for accurate studies of spectral lineshapes and line center frequencies of hydrogen isotopologues and in general of Raman active transitions. Thanks to the frequency comb calibration of the detuning between pump and Stokes lasers and to an active alignment of the two beams, the frequency accuracy is well below 100 kHz. Over the vertical axis the spectrometer benefits from shot-noise limited detection, signal enhancement via multipass cell, active flattening of the spectral baseline and measurement times of few seconds over spectral spans larger than 10 GHz. Under these conditions an efficient averaging of Raman spectra is possible over long measurement times with minimal distortion of spectral lineshapes. By changing the pump laser, transitions can be covered in a very broad frequency span, from 50 to 5000 $\mathrm{cm^{-1}}$, including both vibrational and rotational bands. The spectrometer has been developed for studies of fundamental and collisional physics of hydrogen isotopologues and has been recently applied to the metrology of the Q(1) 1-0 line of $\mathrm{H_2}$.

Published

2023

4. Charge-density-wave in 1T-TiSe2: exciton-phonon separation by femtosecond valence band dynamics

Author

Hedayat H., Bugini D., Karbassi S., Friedmann S., van Wezel J., Clark S. R., Sayers C., Da Como E., Cerullo G., Dallera C., and Carpene E.

Subjects

Physics, QC1-999

Abstract

We investigate the driving mechanism leading to charge-density-wave transition in 1T-TiSe2 single crystals. Our results show that both exciton instability and phonons cooperate to develop the charge ordered phase below 202 K.

Published

2019

5. Parametric Nonlinear Optics with Layered Materials and Related Heterostructures

Author

Dogadov, O., Trovatello, C., Yao, B., Soavi, G., and Cerullo, G.

Subjects

Physics - Optics

Abstract

Nonlinear optics is of crucial importance in several fields of science and technology with applications in frequency conversion, entangled-photon generation, self-referencing of frequency combs, crystal characterization, sensing, and ultra-short light pulse generation and characterization. In recent years, layered materials and related heterostructures have attracted huge attention in this field, due to their huge nonlinear optical susceptibilities, their ease of integration on photonic platforms, and their 2D nature which relaxes the phase-matching constraints and thus offers a practically unlimited bandwidth for parametric nonlinear processes. In this review the most recent advances in this field, highlighting their importance and impact both for fundamental and technological aspects, are reported and explained, and an outlook on future research directions for nonlinear optics with atomically thin materials is provided.

Published

2022

6. Stimulated-Raman-Scattering Metrology

Author

Lamperti, M., Rutkowski, L., Ronchetti, D., Gatti, D., Gotti, R., Cerullo, G., Thibault, F., Jóźwiak, H., Wójtewicz, S., Masłowski, P., Wcisło, P., Polli, D., and Marangoni, M.

Subjects

Physics - Optics, Physics - Instrumentation and Detectors

Abstract

Frequency combs have revolutionized optical frequency metrology, allowing one to determine highly accurate transition frequencies of a wealth of molecular species. Despite a recognized scientific interest, these progresses have only marginally benefited infrared-inactive transitions, due to their inherently weak cross-sections. Here we overcome this limitation by introducing stimulated-Raman-scattering metrology, where a frequency comb is exploited to calibrate the frequency detuning between the pump and Stokes excitation lasers. We apply this approach to molecular hydrogen to test quantum electrodynamics. We measure the transition frequency of the Q(1) fundamental line of H$_2$ around 4155 cm$^{-1}$ with few parts-per-billion uncertainty, which is comparable to the theoretical benchmark of ab initio calculations and more than a decade better than the experimental state of the art. Our comb-calibrated stimulated Raman scattering spectrometer extends the toolkit of optical frequency metrology as it can be applied, with simple technical changes, to many other infrared-inactive transitions, over a 50-5000 cm$^{-1}$ range that covers also purely rotational bands.

Published

2022

7. Femtosecond phononic coupling to both spins and charges in a room temperature antiferromagnetic semiconductor

Author

Bossini, D., Conte, S. dal, Terschanski, M., Springholz, G., Bonanni, A., Deltenre, K., Anders, F., Uhrig, G. S., Cerullo, G., and Cinchetti, M.

Subjects

Physics - Optics

Abstract

Spintronics is postulated on the possibility to employ the magnetic degree of freedom of electrons for computation and couple it to charges. In this view, the combination of the high-frequency of spin manipulations offered by antiferromagnets, with the wide tunability of the electronic properties peculiar of semiconductors provides a promising and intriguing platform. Here we explore this scenario in $\alpha$-MnTe, which is a semiconductor antiferromagnetically ordered at room temperature. Relying on a Raman mechanism and femtosecond laser pulses, we drive degenerate modes of coherent optical phonons, which modulate the chemical bonds involved in the super-exchange interaction. The spectrally-resolved measurements of the transient reflectivity reveal a coherent modulation of the band-gap at the frequency of 5.3 THz. The detection of the rotation of the polarisation, typically associated with magneto-optical effects, shows coherent and incoherent contributions. Modelling how the ionic motion induced by the phonons affects the exchange interaction in the material, we calculate the photoinduced THz spin dynamics: the results predict both a coherent and incoherent response, the latter of which is consistent with the experimental observation. Our work demonstrates that the same phonon modes modulate both the charge and magnetic degree of freedom, suggesting the resonant pumping of phonons as a viable way to link spin and charge dynamics even in nonlinear regimes.

Published

2021

8. Cryogenic Penning-Trap Apparatus for Precision Experiments with Sympathetically Cooled (anti)protons

Author

Niemann, M., Meiners, T., Mielke, J., Pulido, N., Schaper, J., Borchert, M. J., Cornejo, J. M., Paschke, A. -G., Zarantonello, G., Hahn, H., Lang, T., Manzoni, C., Marangoni, M., Cerullo, G., Morgner, U., Fenske, J. -A., Bautista-Salvador, A., Lehnert, R., Ulmer, S., and Ospelkaus, C.

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

Current precision experiments with single (anti)protons to test CPT symmetry progress at a rapid pace, but are complicated by the need to cool particles to sub-thermal energies. We describe a cryogenic Penning-trap setup for $^9$Be$^+$ ions designed to allow coupling of single (anti)protons to laser-cooled atomic ions for sympathetic cooling and quantum logic spectroscopy. We report on trapping and laser cooling of clouds and single $^9$Be$^+$ ions. We discuss prospects for a microfabricated trap to allow coupling of single (anti)protons to laser-cooled $^9$Be$^+$ ions for sympathetic laser cooling to sub-mK temperatures on ms time scales., Comment: Presented at the Eighth Meeting on CPT and Lorentz Symmetry, Bloomington, Indiana, May 12-16, 2019

Published

2021

9. Superabsorption in an organic microcavity: towards a quantum battery

Author

Quach, J. Q., McGhee, K. E., Ganzer, L., Rouse, D. M., Lovett, B. W., Gauger, E. M., Keeling, J., Cerullo, G., Lidzey, D. G., and Virgili, T.

Subjects

Quantum Physics

Abstract

The rate at which matter emits or absorbs light can be modified by its environment, as dramatically exemplified by the widely-studied phenomenon of superradiance. The reverse process, superabsorption, is harder to demonstrate due to the challenges of probing ultrafast processes, and has only been seen for small numbers of atoms. Its central idea - superextensive scaling of absorption meaning larger systems absorb faster - is also the key idea underpinning quantum batteries. Here we implement experimentally a paradigmatic model of a quantum battery, constructed of a microcavity enclosing a molecular dye. Ultrafast optical spectroscopy allows us to observe charging dynamics at femtosecond resolution to demonstrate superextensive charging rates and storage capacity, in agreement with our theoretical modelling. We find that decoherence plays an important role in stabilising energy storage. Our work opens new opportunities for harnessing collective effects in light-matter coupling for nanoscale energy capture, storage, and transport technologies., Comment: 42 pages, 20 figures, 3 tables

Published

2020

10. Coherent phonons and the interplay between charge density wave and Mott phases in 1$T$-TaSe$_{2}$

Author

Sayers, C. J., Hedayat, H., Ceraso, A., Museur, F., Cattelan, M., Hart, L. S., Farrar, L. S., Conte, S. Dal, Cerullo, G., Dallera, C., Da Como, E., and Carpene, E.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

1$T$-TaSe$_{2}$ is host to coexisting strongly-correlated phases including charge density waves (CDWs) and an unusual Mott transition at low temperature. Here, we investigate coherent phonon oscillations in 1$T$-TaSe$_{2}$ using a combination of time- and angle-resolved photoemission spectroscopy (TR-ARPES) and time-resolved reflectivity (TRR). Perturbation by a femtosecond laser pulse triggers a modulation of the valence band binding energy at the $\Gamma$-point, related to the Mott gap, that is consistent with the in-plane CDW amplitude mode frequency. By contrast, TRR measurements show a modulation of the differential reflectivity comprised of multiple frequencies belonging to the distorted CDW lattice modes. Comparison of the temperature dependence of coherent and spontaneous phonons across the CDW transition shows that the amplitude mode intensity is more easily suppressed during perturbation of the CDW state by the optical excitation compared to other modes. Our results clearly identify the relationship of the in-plane CDW amplitude mode with the Mott phase in 1$T$-TaSe$_{2}$ and highlight the importance of lattice degrees of freedom., Comment: 7 pages, 4 figures, supplemental material

Published

2020

11. Non-equilibrium Band Broadening, Gap Renormalization and Band Inversion in Black Phosphorus

Author

Hedayat, H., Ceraso, A., Soavi, G., Akhavan, S., Cadore, A., Dallera, C., Cerullo, G., Ferrari, A. C., and Carpene, E.

Subjects

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

Abstract

Black phosphorous (BP) is a layered semiconductor with high carrier mobility, anisotropic optical response and wide bandgap tunability. In view of its application in optoelectronic devices, understanding transient photo-induced effects is crucial. Here, we investigate by time- and angle-resolved photoemission spectroscopy BP in its pristine state and in the presence of Stark splitting, chemically induced by Cs ad-sorption. We show that photo-injected carriers trigger bandgap renormalization and a concurrent valence band attening caused by Pauli blocking. In the biased sample, photoexcitation leads to a long-lived (ns) surface photovoltage of few hundreds mV that counterbalances the Cs-induced surface band bending. This allows us to disentangle bulk from surface electronic states and to clarify the mechanism underlying the band inversion observed in bulk samples.

Published

2020

12. Tracing of backward energy transfer from LH1 to LH2 in photosynthetic membranes grown under high and low irradiation.

Author

Lanzani G., Brida D., Hoseinkhani S., Polli D., Brotosudarmo T. H. P., Henry S., Moulisová V., Lüer L., Cerullo G., and Cogdell R. J.

Subjects

Physics, QC1-999

Abstract

By introducing derivative transient absorption spectroscopy, we obtain rate constants for backward and forward energy transfer between LH1 and LH2 complexes in purple bacterial membranes. We find that backward energy transfer is strongly reduced in membranes grown under low irradiation conditions, compared to high light grown ones. We conclude that backward energy transfer is managed actively by the bacteria to avoid LH1 exciton deactivation under high irradiation conditions. The analytical method is generally applicable to excitonically coupled systems.

Published

2013

13. Real-time observation of ultrafast Rabi oscillations between excitons and plasmons in metal/molecular aggregate hybrid nanostructures

Author

Cerullo G., Manzoni C., Maiuri M., Lammers M., Pomraenke R., Vasa P., Wang W., and Lienau C.

Subjects

Physics, QC1-999

Abstract

We demonstrate ultrafast coherent manipulation of the normal mode splitting in metal/molecular-aggregate nanostructures by real-time observation of Rabi oscillations between excitons and surface-plasmon-polaritons. Oscillations in exciton density on a 10-fs timescale control the Rabi splitting.

Published

2013

14. Ultrafast Non-Thermal Electron Dynamics in Single Layer Graphene

Author

Novoselov K.S., Geim A.K., Nair R.R., Polini M., Tomadin A., Cerullo G., Manzoni C., Brida D., Milana S., Lombardo A., and Ferrari A. C.

Subjects

Physics, QC1-999

Abstract

We study the ultrafast dynamics of non-thermal electron relaxation in graphene upon impulsive excitation. The 10-fs resolution two color pump-probe allows us to unveil the non-equilibrium electron gas decay at early times.

Published

2013

15. Ultra-fast polariton dynamics in an organic microcavity

Author

Polli D., Brida D., Rajendran S.K., Michetti P., Clark C., Adawi A.M., Coles D., Virgili T., Cerullo G., and Lidzey D.G.

Subjects

Physics, QC1-999

Abstract

We study an organic semiconductor microcavity operating in the strong-coupling regime using femtosecond pump-probe spectroscopy. By probing the photo-induced absorption bands, we characterize the time-dependent population densities of states in the two polariton branches. We found evidence of a scattering process from the upper-branch cavity polaritons to the exciton reservoir having a rate of (150 fs)-1. A slower process similarly populates lower-branch polaritons with a rate of around (3ps)-1

Published

2013

16. Coherent Synthesis of ultra-broadband Optical Parametric Amplifiers

Author

De Silvestri S., Moses J., Farinello P., Cirmi G., Huang S.W., Manzoni C., Kärtner F. X., and Cerullo G.

Subjects

Physics, QC1-999

Abstract

We report on coherent synthesis of outputs from two ultra-broadband optical parametric amplifiers; their timing is locked to sub-30-as by a balanced cross-correlator. Synthesised pulses have octave-spanning (500-1000 nm) spectra and nearly single-cycle 3.8-fs duration.

Published

2013

17. Ultrafast Energy Transfer in an Artificial Photosynthetic Antenna

Author

van Grondelle R., Moore A.L., Moore T.A., Gust D., Pillai S., van Stokkum I.H.M., Snellenburg J.J., Maiuri M., Cerullo G., and Polli D.

Subjects

Physics, QC1-999

Abstract

We temporally resolved energy transfer kinetics in an artificial light-harvesting dyad composed of a phthalocyanine covalently linked to a carotenoid. Upon carotenoid photo-excitation, energy transfers within ≈100fs (≈52% efficiency) to the phthalocyanine.

Published

2013

18. Quantum coherence controls the charge separation in a prototypical artificial light harvesting system

Author

Schramm H., Cerullo G., Maiuri M., Brida D., Molinari E., Rubio A., Spallanzani N., Rozzi C. A., Falke S.M., Christoffers J., and Lienau C.

Subjects

Physics, QC1-999

Abstract

Ultrafast spectroscopy and quantum-dynamics simulations of an artificial supramolecular light-harvesting system — a supramolecular triad - provide strong evidence that the quantum-correlated wavelike motion of electrons and nuclei on a timescale of few tens of femtoseconds governs the ultrafast electronic charge transfer.

Published

2013

19. Ultrafast-Laser-Induced Backward Stimulated Raman Scattering for Tracing Atmospheric Gases

Author

Zheltiko A., Giniūnas L., Danielius A., Baltuška A., Pugžlys A., Ališauskas S., Pu Z., Kartashov D., Malevich P. N., Marangoni M., and Cerullo G.

Subjects

Physics, QC1-999

Abstract

By combining tunable broadband pulse generation with nonlinear spectral compression, we demonstrate a prototype scheme for highly selective coherent standoff sensing of air molecules and discuss its coupling to the recently demonstrated backward atmospheric lasing.

Published

2013

20. Strongly coupled coherent phonons in single-layer MoS$_2$

Author

Trovatello, C., Miranda, H. P. C., Molina-Sánchez, A., Varillas, R. Borrego, Manzoni, C., Moretti, L., Ganzer, L., Maiuri, M., Wang, J., Dumcenco, D., Kis, A., Wirtz, L., Marini, A., Soavi, G., Ferrari, A. C., Cerullo, G., Sangalli, D., and Conte, S. Dal

Subjects

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

Abstract

We present a transient absorption setup combining broadband detection over the visible-UV range with high temporal resolution ($\sim$20fs) which is ideally suited to trigger and detect vibrational coherences in different classes of materials. We generate and detect coherent phonons (CPs) in single layer (1L) MoS$_2$, as a representative semiconducting 1L-transition metal dichalcogenide (TMD), where the confined dynamical interaction between excitons and phonons is unexplored. The coherent oscillatory motion of the out-of-plane $A'_{1}$ phonons, triggered by the ultrashort laser pulses, dynamically modulates the excitonic resonances on a timescale of few tens fs. We observe an enhancement by almost two orders of magnitude of the CP amplitude when detected in resonance with the C exciton peak, combined with a resonant enhancement of CP generation efficiency. Ab initio calculations of the change in 1L-MoS$_2$ band structure induced by the $A'_{1}$ phonon displacement confirm a strong coupling with the C exciton. The resonant behavior of the CP amplitude follows the same spectral profile of the calculated Raman susceptibility tensor. This demonstrates that CP excitation in 1L-MoS$_2$ can be described as a Raman-like scattering process. These results explain the CP generation process in 1L-TMDs, paving the way for coherent all-optical control of excitons in layered materials in the THz frequency range.

Published

2019

21. A Hyperspectral Microscope based on an Ultrastable Common-Path Interferometer

Author

Candeo, A., de Faria, B. E. Nogueira, Erreni, M., Valentini, G., Bassi, A., de Paula, A. M., Cerullo, G., and Manzoni, C.

Subjects

Physics - Instrumentation and Detectors, Physics - Optics

Abstract

We introduce a wide field hyperspectral microscope using the Fourier-transform approach. The interferometer is based on the Translating-Wedge-Based Identical Pulses eNcoding System (TWINS) [Opt. Lett. 37, 3027 (2012)], a common-path birefringent interferometer which combines compactness, intrinsic interferometric delay precision, long-term stability and insensitivity to vibrations. We describe three different implementations of our system: two prototypes designed to test different optical schemes and an add-on for a commercial microscope. We show high-quality spectral microscopy of the fluorescence from stained cells and powders of inorganic pigments, demonstrating that the device is suited to biology and materials science. We demonstrate the acquisition of a 1Mpixel hyperspectral image in 75 seconds in the spectral range from 400 to 1100 nm. We also introduce an acquisition method which synthesizes a tunable spectral filter, providing band-passed images by the measurement of only two maps., Comment: 16 pages, 11 figures

Published

2019

22. Multi-channel lock-in based differential front-end for broadband Raman spectroscopy

Author

Ragni, A., Sciortino, G., Sampietro, M., Ferrari, G., Crisafi, F., Kumar, V., Cerullo, G., and Polli, D.

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

In Broadband Stimulated Raman Spectroscopy, the intrinsic limit given by the laser shot noise is seldom reached due to the electronic noise of the front-end amplifier and the intensity fluctuations of the laser source. In this paper we present a low-noise multi-channel acquisition system, with an integration-oriented design, able to compensate the common-mode fluctuations of the laser output power with the pseudo-differential structure and reach a sensitivity better than 10 ppm thanks to the lock-in technique., Comment: Post review version

Published

2019

23. Versatile control of $^9$Be$^+$ ions using a spectrally tailored UV frequency comb

Author

Paschke, A. -G., Zarantonello, G., Hahn, H., Lang, T., Manzoni, C., Marangoni, M., Cerullo, G., Morgner, U., and Ospelkaus, C.

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

We demonstrate quantum control of $^9$Be$^+$ ions directly implemented by an optical frequency comb. Based on numerical simulations of the relevant processes in $^9$Be$^+$ for different magnetic field regimes, we demonstrate a wide applicability when controlling the comb's spectral properties. We introduce a novel technique for the selective and efficient generation of a spectrally tailored narrow-bandwidth optical frequency comb near 313 nm. We experimentally demonstrate internal state control and internal-motional state coupling of $^9$Be$^+$ ions implemented by stimulated-Raman manipulation using a spectrally optimized optical frequency comb. Our pulsed laser approach is a key enabling step for the implementation of quantum logic and quantum information experiments in Penning traps., Comment: Includes supplementary material

Published

2019

24. Hot electrons modulation of third harmonic generation in graphene

Author

Soavi, G., Wang, G., Rostami, H., Tomadin, A., Balci, O., Paradeisanos, I., Pogna, E. A. A., Cerullo, G., Lidorikis, E., Polini, M., and Ferrari, A. C.

Subjects

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

Abstract

Hot electrons dominate the ultrafast ($\sim$fs-ps) optical and electronic properties of metals and semiconductors and they are exploited in a variety of applications including photovoltaics and photodetection. We perform power-dependent third harmonic generation measurements on gated single-layer graphene and detect a significant deviation from the cubic power-law expected for a third harmonic generation process. We assign this to the presence of hot electrons. Our results indicate that the performance of nonlinear photonics devices based on graphene, such as optical modulators and frequency converters, can be affected by changes in the electronic temperature, which might occur due to increase of absorbed optical power or Joule heating.

Published

2019

25. Coherent anti-Stokes Raman Spectroscopy of single and multi-layer graphene

Author

Virga, A., Ferrante, C., Batignani, G., De Fazio, D., Nunn, A. D. G., Ferrari, A. C., Cerullo, G., and Scopigno, T.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

We report stimulated Raman spectroscopy of the G phonon in both single and multi-layer graphene, through Coherent anti-Stokes Raman Scattering (CARS). The signal generated by the third order nonlinearity is dominated by a vibrationally non-resonant background (NVRB), which obscures the Raman lineshape. We demonstrate that the vibrationally resonant CARS peak can be measured by reducing the temporal overlap of the laser excitation pulses, suppressing the NVRB. We model the observed spectra, taking into account the electronically resonant nature of both CARS and NVRB. We show that CARS can be used for graphene imaging with vibrational sensitivity., Comment: 10 pages, 5 figures

Published

2019

26. Modeling the Ultrafast Response of Two-Magnon Raman Excitations in Antiferromagnets on the Femtosecond Timescale

Author

Batignani, G, Pontecorvo, E, Bossini, D, Ferrante, C, Fumero, G, Cerullo, G, Mukamel, S, and Scopigno, T

Subjects

coherent Raman, light-matter interaction, nonlinear optics, ultrafast photonics, Mathematical Sciences, Physical Sciences, General Physics

Abstract

Illuminating a magnetic material with femtosecond laser pulses induces complex ultrafast dynamical processes. The resulting optically detectable response usually contains contributions from both the optical properties and the magnetic degrees of freedom. Disentangling all the different components concurring to the generation of the total signal is a major challenge of contemporary experimental solid-state physics. Here, this problem is tackled, addressing the purely optical, nonmagnetic artifacts on the time resolved two-magnon stimulated Raman spectrum of an antiferromagnet, rationalizing the recent observation on the exchange energy modification upon photo-excitation. It is demonstrated how the genuine dynamics of the magnetic eigenmode can be disentangled from the nonlinear optical effects, generated by cross phase modulation, on the femtosecond timescale. The introduced approach can be extended for the investigation of

Published

2019

27. Non-linear excitation microscopy of live cells by using an implantable microscope objective-on-a-chip

Author

Tarnok, A, Houston, JP, Nardini, A, Vázquez, R, Conci, C, Grassi, M, Marini, M, Bouzin, M, Collini, M, Osellame, R, Cerullo, G, Kariman, B, Raimondi, M, Chirico, G, Nardini A., Vázquez R. M., Conci C., Grassi M., Marini M., Bouzin M., Collini M., Osellame R., Cerullo G. N., Kariman B. S., Raimondi M. T., Chirico G., Tarnok, A, Houston, JP, Nardini, A, Vázquez, R, Conci, C, Grassi, M, Marini, M, Bouzin, M, Collini, M, Osellame, R, Cerullo, G, Kariman, B, Raimondi, M, Chirico, G, Nardini A., Vázquez R. M., Conci C., Grassi M., Marini M., Bouzin M., Collini M., Osellame R., Cerullo G. N., Kariman B. S., Raimondi M. T., and Chirico G.

Abstract

In the context of biomaterials, small-molecules and drugs testing, intravital microscopy allows to quantify in-vivo the immune reaction, reducing the number of laboratory animals required to statistically validate the product. However, fluorescence microscopy is affected by limited tissue penetration due to light scattering and by optical aberrations, induced on focused beams, by the animal tissue surrounding the implant. In this framework, we developed a system of microlenses coupled to microscaffolds, both incorporated in a miniaturized imaging window. The chip is designed to act as an in-situ microscope objective with the aim to overcome the restrictions of in-vivo imaging (i.e. spherical aberrations) and to allow multiple biological observations in the same animal (by including fluorescent beacons). The device is fabricated by two-photon polymerizing a biocompatible photoresist called SZ2080. The microlenses are manufactured by the concentric polar scanning of the laser beam to realize their outer surface, followed by the UV bulk polymerization of their inner SZ2080. We preliminarily characterized the imaging capabilities of our implantable system on live cells cultured on flat substrates and 3D microscaffolds by coupling it to low magnification objectives. The microlenses optical quality is sufficient to induce non-linear excitation and collect two-photon excitation images with the same level of laser intensity and signal-to-noise ratio. Remarkably, they allow to efficiently excite the fluorescence of labelled human fibroblasts collecting high resolution magnified images. These results will open the way to the application of implanted micro-optics for the real-time and continuous in-vivo observation of complex biological processes.

Published

2024

28. Role of matrix elements in the time-resolved photoemission signal

Author

Boschini, F., Bugini, D., Zonno, M., Michiardi, M., Day, R. P., Razzoli, E., Zwartsenberg, B., Neto, E. H. da Silva, Conte, S. dal, Kushwaha, S. K., Cava, R. J., Zhdanovich, S., Mills, A. K., Levy, G., Carpene, E., Dallera, C., Giannetti, C., Jones, D. J., Cerullo, G., and Damascelli, A.

Subjects

Condensed Matter - Materials Science

Abstract

Time- and angle-resolved photoemission spectroscopy accesses the ultrafast evolution of quasiparticles and many-body interactions in solid-state systems. However, the momentum- and energy-resolved transient photoemission intensity may not be unambiguously related to the intrinsic relaxation dynamics of photoexcited electrons. In fact, interpretation of the time-dependent photoemission signal can be affected by the transient evolution of both the one-electron removal spectral function as well as the photoemission dipole matrix elements. Here we investigate the topological insulator Bi$_{1.1}$Sb$_{0.9}$Te$_2$S to demonstrate, by means of a careful probe-polarization study, the transient contribution of matrix elements to the time-resolved photoemission signal., Comment: 7 pages, 3 figures

Published

2018

29. Direct observation of intravalley spin relaxation in single-layer WS$_2$

Author

Wang, Z., Molina-Sanchez, A., Altmann, P., Sangalli, D., De Fazio, D., Soavi, G., Sassi, U., Bottegoni, F., Ciccacci, F., Finazzi, M., Wirtz, L., Ferrari, A. C., Marini, A., Cerullo, G., and Conte, S. Dal

Subjects

Condensed Matter - Materials Science

Abstract

In monolayer Transition Metal Dichalcogenides (TMDs) the valence and conduction bands are spin split because of the strong spin-orbit interaction. In tungsten-based TMDs the spin-ordering of the conduction band is such that the so-called dark exciton, consisting of an electron and a hole with opposite spin orientation, has lower energy than the A exciton. A possible mechanism leading to the transition from bright to dark excitons involves the scattering of the electrons from the upper to the lower conduction band state in K. Here we exploit the valley selective optical selection rules and use two-color helicity-resolved pump-probe spectroscopy to directly measure the intravalley spin-flip relaxation dynamics of electrons in the conduction band of single-layer WS$_2$. This process occurs on a sub-ps time scale and it is significantly dependent on the temperature, indicative of a phonon-assisted relaxation. These experimental results are supported by time-dependent ab-initio calculations which show that the intra-valley spin-flip scattering occurs on significantly longer time scales only exactly at the K point. In a realistic situation the occupation of states away from the minimum of the conduction band leads to a dramatic reduction of the scattering time.

Published

2018

30. Solution processable and optically switchable 1D photonic structures

Author

Paternò, G. M., Iseppon, C., D'Altri, A., Fasanotti, C., Merati, G., Randi, M., Desii, A., Pogna, E. A. A., Viola, D., Cerullo, G., Scotognella, F., and Kriegel, I.

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

In this work, we report the first demonstration of a solution processable, optically switchable 1D photonic crystal by implementing phototunable doped metal oxide nanocrystals. The resulting device structure shows bi-photonic response with the photonic bandgap covering the visible spectral range and the plasmon resonance of the doped metal oxide the near infrared. By means of a facile photodoping process, we tuned the plasmonic response and switched effectively the optical properties of the photonic crystal, translating the effect from the near infrared to the visible. The ultrafast bandgap pumping induces a signal change in the region of the photonic stopband, with recovery times of several picoseconds, providing a step toward the ultrafast optical switching. Optical modeling uncovers the importance to understand largely the variations of the dielectric function of the photodoped material, and variations in the high frequency region of the Drude response are responsible for the strong switching in the visible after photodoping. Our device configuration offers unprecedented tunablility due to flexibility in device design, cover wavelength ranges from the visible to the near infrared. Our findings indicate a new protocol to modify the optical response of photonic devices by optical triggers only., Comment: 12 pages, 3 figures

Published

2017

31. Laser-driven quantum magnonics and THz dynamics of the order parameter in antiferromagnets

Author

Bossini, D., Conte, S. Dal, Gomonay, O., Pisarev, R. V., Borovsak, M., Mihailovic, D., Sinova, J., Cerullo, G., Mentink, J. H., Rasing, Th., and Kimel, A. V.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

The impulsive generation of two-magnon modes in antiferromagnets by femtosecond optical pulses, so-called femto-nanomagnons, leads to coherent longitudinal oscillations of the antiferromagnetic order parameter that cannot be described by a thermodynamic Landau-Lifshitz approach. We argue that this dynamics is triggered as a result of a laser-induced modification of the exchange interaction. In order to describe the oscillations we have formulated a quantum mechanical description in terms of magnon pair operators and coherent states. Such an approach allowed us to} derive an effective macroscopic equation of motion for the temporal evolution of the antiferromagnetic order parameter. An implication of the latter is that the photo-induced spin dynamics represents a macroscopic entanglement of pairs of magnons with femtosecond period and nanometer wavelength. By performing magneto-optical pump-probe experiments with 10 femtosecond resolution in the cubic KNiF$_3$ and the uniaxial K$_2$NiF$_4$ collinear Heisenberg antiferromagnets, we observed coherent oscillations at the frequency of 22 THz and 16 THz, respectively. The detected frequencies as a function of the temperature ideally fit the two-magnon excitation up to the N\'eel point. The experimental signals are described as dynamics of magnetic linear dichroism due to longitudinal oscillations of the antiferromagnetic vector., Comment: 25 pages, 10 figures

Published

2017

32. Broadband, electrically tuneable, third harmonic generation in graphene

Author

Soavi, G., Wang, G., Rostami, H., Purdie, D., De Fazio, D., Ma, T., Luo, B., Wang, J., Ott, A. K., Yoon, D., Bourelle, S., Muench, J. E., Goykhman, I., Conte, S. Dal, Celebrano, M., Tomadin, A., Polini, M., Cerullo, G., and Ferrari, A. C.

Subjects

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

Abstract

Optical harmonic generation occurs when high intensity light ($>10^{10}$W/m$^{2}$) interacts with a nonlinear material. Electrical control of the nonlinear optical response enables applications such as gate-tunable switches and frequency converters. Graphene displays exceptionally strong-light matter interaction and electrically and broadband tunable third order nonlinear susceptibility. Here we show that the third harmonic generation efficiency in graphene can be tuned by over two orders of magnitude by controlling the Fermi energy and the incident photon energy. This is due to logarithmic resonances in the imaginary part of the nonlinear conductivity arising from multi-photon transitions. Thanks to the linear dispersion of the massless Dirac fermions, ultrabroadband electrical tunability can be achieved, paving the way to electrically-tuneable broadband frequency converters for applications in optical communications and signal processing.

Published

2017

33. Raman spectroscopy of graphene under ultrafast laser excitation

Author

Ferrante, C., Virga, A., Benfatto, L., Martinati, M., De Fazio, D., Sassi, U., Fasolato, C., Ott, A. K., Postorino, P., Yoon, D., Cerullo, G., Mauri, F., Ferrari, A. C., and Scopigno, T.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

The equilibrium optical phonons of graphene are well characterized in terms of anharmonicity and electron-phonon interactions, however their non-equilibrium properties in the presence of hot charge carriers are still not fully explored. Here we study the Raman spectrum of graphene under ultrafast laser excitation with 3ps pulses, which trade off between impulsive stimulation and spectral resolution. We localize energy into hot carriers, generating non-equilibrium temperatures in the ~1700-3100K range, far exceeding that of the phonon bath, while simultaneously detecting the Raman response. The linewidth of both G and 2D peaks show an increase as function of the electronic temperature. We explain this as a result of the Dirac cones' broadening and electron-phonon scattering in the highly excited transient regime, important for the emerging field of graphene-based photonics and optoelectronics., Comment: 10 pages, 7 figures

Published

2017

34. Out-of-plane heat transfer in van der Waals stacks: electron-hyperbolic phonon coupling

Author

Tielrooij, K. J., Hesp, N. C. H., Principi, A., Lundeberg, M., Pogna, E. A. A., Banszerus, L., Mics, Z., Massicotte, M., Schmidt, P., Davydovskaya, D., Purdie, D. G., Goykhman, I., Soavi, G., Lombardo, A., Watanabe, K., Taniguchi, T., Bonn, M., Turchinovich, D., Stampfer, C., Ferrari, A. C., Cerullo, G., Polini, M., and Koppens, F. H. L.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Van der Waals heterostructures have emerged as promising building blocks that offer access to new physics, novel device functionalities, and superior electrical and optoelectronic properties. Applications such as thermal management, photodetection, light emission, data communication, high-speed electronics and light harvesting require a thorough understanding of (nanoscale) heat flow. Here, using time-resolved photocurrent measurements we identify an efficient out-of-plane energy transfer channel, where charge carriers in graphene couple to hyperbolic phonon polaritons in the encapsulating layered material. This hyperbolic cooling is particularly efficient, giving picosecond cooling times, for hexagonal BN, where the high-momentum hyperbolic phonon polaritons enable efficient near-field energy transfer. We study this heat transfer mechanism through distinct control knobs to vary carrier density and lattice temperature, and find excellent agreement with theory without any adjustable parameters. These insights may lead to the ability to control heat flow in van der Waals heterostructures.

Published

2017

35. Robust singlet fission in pentacene thin films with tuned charge transfer interactions.

Author

Broch, K, Dieterle, J, Branchi, F, Hestand, NJ, Olivier, Y, Tamura, H, Cruz, C, Nichols, VM, Hinderhofer, A, Beljonne, D, Spano, FC, Cerullo, G, Bardeen, CJ, and Schreiber, F

Abstract

Singlet fission, the spin-allowed photophysical process converting an excited singlet state into two triplet states, has attracted significant attention for device applications. Research so far has focused mainly on the understanding of singlet fission in pure materials, yet blends offer the promise of a controlled tuning of intermolecular interactions, impacting singlet fission efficiencies. Here we report a study of singlet fission in mixtures of pentacene with weakly interacting spacer molecules. Comparison of experimentally determined stationary optical properties and theoretical calculations indicates a reduction of charge-transfer interactions between pentacene molecules with increasing spacer molecule fraction. Theory predicts that the reduced interactions slow down singlet fission in these blends, but surprisingly we find that singlet fission occurs on a timescale comparable to that in pure crystalline pentacene. We explain the observed robustness of singlet fission in such mixed films by a mechanism of exciton diffusion to hot spots with closer intermolecular spacings.

Published

2018

36. Adapting wild biodiversity conservation approaches to conserve agrobiodiversity

Author

Jago, S., Elliott, K. F. V. A., Tovar, C., Soto Gomez, M., Starnes, T., Abebe, W., Alexander, C., Antonelli, A., Baldaszti, L., Cerullo, G., Cockel, C., Collison, D., Cowell, C., Delgado, R., Demissew, S., Devenish, A., Dhanjal-Adams, K., Diazgranados, M., Drucker, A. G., Dulloo, M. E., Erland, B. M., Fadika, S., Huang, W., Inwood, K., Jones, S. K., Klitgaard, B. B., Lebbie, A., Lim, F. K. S., Lulekal, E., Morales-Rozo, C., Niang, F., Nic Lughadha, E., Oliveira, R. P., Ortega-Argueta, A., Pironon, S., Plummer, J. F., Ramirez, M., Ryan, P., Simbiano, F. J., Smith, R. J., Stevenson, P. C., Treydte, A. C., Victor, J. E., Weber, O., Williams, C., Yohanna, C. T., Grace, O. M., Darbyshire, I., Borrell, J. S., Jago, S., Elliott, K. F. V. A., Tovar, C., Soto Gomez, M., Starnes, T., Abebe, W., Alexander, C., Antonelli, A., Baldaszti, L., Cerullo, G., Cockel, C., Collison, D., Cowell, C., Delgado, R., Demissew, S., Devenish, A., Dhanjal-Adams, K., Diazgranados, M., Drucker, A. G., Dulloo, M. E., Erland, B. M., Fadika, S., Huang, W., Inwood, K., Jones, S. K., Klitgaard, B. B., Lebbie, A., Lim, F. K. S., Lulekal, E., Morales-Rozo, C., Niang, F., Nic Lughadha, E., Oliveira, R. P., Ortega-Argueta, A., Pironon, S., Plummer, J. F., Ramirez, M., Ryan, P., Simbiano, F. J., Smith, R. J., Stevenson, P. C., Treydte, A. C., Victor, J. E., Weber, O., Williams, C., Yohanna, C. T., Grace, O. M., Darbyshire, I., and Borrell, J. S.

Abstract

The global biodiversity crisis in agriculture is overlooked compared with that in wild systems. This must change if we are to safeguard domesticated plant diversity and meet global sustainable development and biodiversity goals. In this Perspective, we review tools developed through decades of wild biodiversity conservation and provide a framework for adapting and applying these for agrobiodiversity conservation. We focus on challenges and solutions around monitoring the status of agrobiodiversity, prioritizing its conservation, conserving it in situ and financing to ensure these actions can be maintained long term. Conserving global agrobiodiversity supports wider conservation efforts and is crucial for achieving food security, climate resilience and a sustainable future.

Published

2024

37. In vivo label-free tissue histology through a microstructured imaging window

Author

Conci, C, Sironi, L, Jacchetti, E, Panzeri, D, Inverso, D, Martínez Vázquez, R, Osellame, R, Collini, M, Cerullo, G, Chirico, G, Teresa Raimondi, M, Claudio Conci, Laura Sironi, Emanuela Jacchetti, Davide Panzeri, Donato Inverso, Rebeca Martínez Vázquez, Roberto Osellame, Maddalena Collini, Giulio Cerullo, Giuseppe Chirico, Manuela Teresa Raimondi, Conci, C, Sironi, L, Jacchetti, E, Panzeri, D, Inverso, D, Martínez Vázquez, R, Osellame, R, Collini, M, Cerullo, G, Chirico, G, Teresa Raimondi, M, Claudio Conci, Laura Sironi, Emanuela Jacchetti, Davide Panzeri, Donato Inverso, Rebeca Martínez Vázquez, Roberto Osellame, Maddalena Collini, Giulio Cerullo, Giuseppe Chirico, and Manuela Teresa Raimondi

Abstract

Tissue histopathology, based on hematoxylin and eosin (H&E) staining of thin tissue slices, is the gold standard for the evaluation of the immune reaction to the implant of a biomaterial. It is based on lengthy and costly procedures that do not allow longitudinal studies. The use of non-linear excitation microscopy in vivo, largely label-free, has the potential to overcome these limitations. With this purpose, we develop and validate an implantable microstructured device for the non-linear excitation microscopy assessment of the immune reaction to an implanted biomaterial label-free. The microstructured device, shaped as a matrix of regular 3D lattices, is obtained by two-photon laser polymerization. It is subsequently implanted in the chorioallantoic membrane (CAM) of embryonated chicken eggs for 7 days to act as an intrinsic 3D reference frame for cell counting and identification. The histological analysis based on H&E images of the tissue sections sampled around the implanted microstructures is compared to non-linear excitation and confocal images to build a cell atlas that correlates the histological observations to the label-free images. In this way, we can quantify the number of cells recruited in the tissue reconstituted in the microstructures and identify granulocytes on label-free images within and outside the microstructures. Collagen and microvessels are also identified by means of second-harmonic generation and autofluorescence imaging. The analysis indicates that the tissue reaction to implanted microstructures is like the one typical of CAM healing after injury, without a massive foreign body reaction. This opens the path to the use of similar microstructures coupled to a biomaterial, to image in vivo the regenerating interface between a tissue and a biomaterial with label-free non-linear excitation microscopy. This promises to be a transformative approach, alternative to conventional histopathology, for the bioengineering and the validation of

Published

2024

38. Probing equilibrium glass flow up to exapoise viscosities

Author

Pogna, E. A. A., Rodríguez-Tinoco, C., Cerullo, G., Ferrante, C., Rodríguez-Viejo, J., and Scopigno, T.

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Physics - Optics

Abstract

Glasses are out-of-equilibrium systems aging under the crystallization threat. During ordinary glass formation, the atomic diffusion slows down rendering its experimental investigation impractically long, to the extent that a timescale divergence is taken for granted by many. We circumvent here these limitations, taking advantage of a wide family of glasses rapidly obtained by physical vapor deposition directly into the solid state, endowed with different "ages" rivaling those reached by standard cooling and waiting for millennia. Isothermally probing the mechanical response of each of these glasses, we infer a correspondence with viscosity along the equilibrium line, up to exapoise values. We find a dependence of the elastic modulus on the glass age, which, traced back to temperature steepness index of the viscosity, tears down one of the cornerstones of several glass transition theories: the dynamical divergence. Critically, our results suggest that the conventional wisdom picture of a glass ceasing to flow at finite temperature could be wrong., Comment: 4 figures and 1 supplementary figure

Published

2015

39. Macrospin Dynamics in Antiferromagnets Triggered by Sub-20 femtosecond Injection of Nanomagnons

Author

Bossini, D., Conte, S. Dal, Hashimoto, Y., Secchi, A., Pisarev, R. V., Rasing, Th., Cerullo, G., and Kimel, A. V.

Subjects

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

Abstract

The understanding of how the sub-nanoscale exchange interaction evolves in macroscale correlations and ordered phases of matter, such as magnetism and superconductivity, requires to bridge the quantum and classical worlds. This monumental challenge has so far only been achieved for systems close to their thermodynamical equilibrium. Here we follow in real time the ultrafast dynamics of the macroscale magnetic order parameter triggered by the impulsive optical generation of spin excitations with the shortest possible nanometer-wavelength and femtosecond-period. Our experiments also disclose a possibility for the coherent control of these femtosecond nanomagnons, which are defined by the exchange energy. These findings open up novel opportunities for fundamental research on the role of short-wavelength spin excitations in magnetism and high-temperature superconductivity, since they provide a macroscopic probe of the femtosecond dynamics of sub-nanometer spin-spin correlations and, ultimately, of the exchange energy. With this approach it becomes possible to trace the dynamics of such short-range magnetic correlations for instance during phase transitions. Moreover, our work suggests that nanospintronics and nanomagnonics can employ phase-controllable spin waves with frequencies in the 20 THz domain.

Published

2015

40. Valley and spin dynamics in monolayer MoS$_{2}$

Author

Conte, S. Dal, Bottegoni, F., Pogna, E. A. A., Ambrogio, S., Bargigia, I., D'Andrea, C., De Fazio, D., Lombardo, A., Bruna, M., Ciccacci, F., Ferrari, A. C., Cerullo, G., and Finazzi, M.

Subjects

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

Abstract

Valleytronics targets the exploitation of the additional degrees of freedom in materials where the energy of the carriers may assume several equal minimum values (valleys) at non-equivalent points of the reciprocal space. In single layers of transition metal dichalcogenides (TMDs) the lack of inversion symmetry, combined with a large spin-orbit interaction, leads to a conduction (valence) band with different spin-polarized minima (maxima) having equal energies. This offers the opportunity to manipulate information at the level of the charge (electrons or holes), spin (up or down) and crystal momentum (valley). Any implementation of these concepts, however, needs to consider the robustness of such degrees of freedom, which are deeply intertwined. Here we address the spin and valley relaxation dynamics of both electrons and holes with a combination of ultrafast optical spectroscopy techniques, and determine the individual characteristic relaxation times of charge, spin and valley in a MoS$_{2}$ monolayer. These results lay the foundations for understanding the mechanisms of spin and valley polarization loss in two-dimensional TMDs: spin/valley polarizations survive almost two-orders of magnitude longer for holes, where spin and valley dynamics are interlocked, than for electrons, where these degrees of freedom are decoupled. This may lead to novel approaches for the integration of materials with large spin-orbit in robust spintronic/valleytronic platforms.

Published

2015

41. Snapshots of the retarded interaction of charge carriers with ultrafast fluctuations in cuprates

Author

Conte, S. Dal, Vidmar, L., Golež, D., Mierzejewski, M., Soavi, G., Peli, S., Banfi, F., Ferrini, G., Comin, R., Ludbrook, B. M., Chauviere, L., Zhigadlo, N. D., Eisaki, H., Greven, M., Lupi, S., Damascelli, A., Brida, D., Capone, M., Bonča, J., Cerullo, G., and Giannetti, C.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons, Physics - Optics

Abstract

One of the pivotal questions in the physics of high-temperature superconductors is whether the low-energy dynamics of the charge carriers is mediated by bosons with a characteristic timescale. This issue has remained elusive since electronic correlations are expected to dramatically speed up the electron-boson scattering processes, confining them to the very femtosecond timescale that is hard to access even with state-of-the-art ultrafast techniques. Here we simultaneously push the time resolution and the frequency range of transient reflectivity measurements up to an unprecedented level that enables us to directly observe the 16 fs build-up of the effective electron-boson interaction in hole-doped copper oxides. This extremely fast timescale is in agreement with numerical calculations based on the t-J model and the repulsive Hubbard model, in which the relaxation of the photo-excited charges is achieved via inelastic scattering with short-range antiferromagnetic excitations., Comment: to appear in Nature Physics

Published

2015

42. Laser microfabrication for optical sensing and imaging in vivo

Author

Bianchini, P, Diaspro, A, Sheppard, CJR, Bouzin, M, Sironi, L, Marini, M, D'Alfonso, L, Collini, M, Chirico, G, Conci, C, Jacchetti, E, Raimondi, M, Nardini, A, Cerullo, G, Martinez Vazquez, R, Osellame, R, Sironi L., Marini M., Bouzin M., D'Alfonso L., Collini M., Chirico G., Conci C., Jacchetti E., Raimondi M. T., Nardini A., Cerullo G., Martinez Vazquez R., Osellame R., Bianchini, P, Diaspro, A, Sheppard, CJR, Bouzin, M, Sironi, L, Marini, M, D'Alfonso, L, Collini, M, Chirico, G, Conci, C, Jacchetti, E, Raimondi, M, Nardini, A, Cerullo, G, Martinez Vazquez, R, Osellame, R, Sironi L., Marini M., Bouzin M., D'Alfonso L., Collini M., Chirico G., Conci C., Jacchetti E., Raimondi M. T., Nardini A., Cerullo G., Martinez Vazquez R., and Osellame R.

Abstract

The possibility to fabricate microstructures to be used in the medical field is a reality. Further steps in this direction consist in the fabrication of active microstructures for implants and/or for cellular treatments. Two major areas of interest will be briefly treated here. The first is the one of stimulus-responsive optical polymers, especially hydrogels, that can be shaped by means of laser 3D printing and ablation. These can be used for thermal stimulation, energy transduction and sensing. The composition of these polymeric blends is an essential parameter to tune their properties as actuators and/or sensing platforms and to determine the elasto-mechanical characteristics of the printed hydrogel. A second field of interest is the microfabrication of rigid microstructures that can stand the tissue-induced stresses in implants. The increasing demand of microdevices for nanomedicine and personalized medicine has fostered the quest for an efficient combination of composite and hybrid photo-responsive materials and digital micro/nano-manufacturing. Existing works have exploited multiphoton laser photo-polymerization to obtain fine 3D microstructures in hydrogels in an additive manufacturing approach or exploited laser ablation of preformed hydrogels to carve 3D cavities. The aim of this report is to provide a short overview of the basics of photo-polymerization induced by two-photon excitation and to discuss two case studies. In the first one, we discuss the most recent and prominent results in the field of multiphoton laser direct writing of biocompatible hydrogels that embed active nanomaterials not interfering with the writing process and endowing the biocompatible microstructures with physically or chemically activable features such as photo-thermal activity, chemical swelling and chemical sensing. In the second case, we outline the fabrication steps and the first tests of a novel chip which aims at enabling longitudinal studies of the reaction to the biomater

Published

2023

43. Two-Photon Polymerization of an In-Vivo Multiphoton Imaging Window

Author

Vazquez, R, Nardini, A, Marini, M, Conci, C, Kariman, B, Bouzin, M, Collini, M, Chirico, G, Raimondi, M, Osellame, R, Cerullo, G, Vazquez R. M., Nardini A., Marini M., Conci C., Kariman B. S., Bouzin M., Collini M., Chirico G., Raimondi M. T., Osellame R., Cerullo G., Vazquez, R, Nardini, A, Marini, M, Conci, C, Kariman, B, Bouzin, M, Collini, M, Chirico, G, Raimondi, M, Osellame, R, Cerullo, G, Vazquez R. M., Nardini A., Marini M., Conci C., Kariman B. S., Bouzin M., Collini M., Chirico G., Raimondi M. T., Osellame R., and Cerullo G.

Abstract

Intravital microscopy windows for in vivo observation of tissue are desirable in many biomedical fields, from immunology to the assessment of the foreign body reaction to biomaterials. Moreover, they allow one to reduce the number of animals required to statistically validate biomaterials if compared with traditional histopathological analyses of animal biopsies [1,2].

Published

2023

44. Micro-Fabricated Optics for Multiphoton Microscopy

Author

Jaworski, M, Marciniak, M, Vazquez, R, Nardini, A, Conci, C, Jacchetti, E, Marini, M, Panzeri, D, Sironi, L, Bouzin, M, Collini, M, Inverso, D, Kariman, B, Kabouraki, E, Farsari, M, Osellame, R, Cerullo, G, Raimondi, M, Chirico, G, Vazquez R. M., Nardini A., Conci C., Jacchetti E., Marini M., Panzeri D., Sironi L., Bouzin M., Collini M., Inverso D., Kariman B. S., Kabouraki E., Farsari M., Osellame R., Cerullo G., Raimondi M. T., Chirico G., Jaworski, M, Marciniak, M, Vazquez, R, Nardini, A, Conci, C, Jacchetti, E, Marini, M, Panzeri, D, Sironi, L, Bouzin, M, Collini, M, Inverso, D, Kariman, B, Kabouraki, E, Farsari, M, Osellame, R, Cerullo, G, Raimondi, M, Chirico, G, Vazquez R. M., Nardini A., Conci C., Jacchetti E., Marini M., Panzeri D., Sironi L., Bouzin M., Collini M., Inverso D., Kariman B. S., Kabouraki E., Farsari M., Osellame R., Cerullo G., Raimondi M. T., and Chirico G.

Abstract

We report new methods of 2 photon polymerization of microlenses with high numerical aperture, large diameter and good optical quality. We characterize the aberrations of these lenses that, coupled to raster scanning optical microscopes, allow two-photon excitation imaging of cells. In-vivo non-linear imaging will be also discussed, opening the possibility to use these micro-lenses in implants for the continuous inspection of biological dynamics in vivo.

Published

2023

45. Microlenses Fabricated by Two‐Photon Laser Polymerization for Cell Imaging with Non‐Linear Excitation Microscopy

Author

Marini, M, Nardini, A, Martínez Vázquez, R, Conci, C, Bouzin, M, Collini, M, Osellame, R, Cerullo, G, Kariman, B, Farsari, M, Kabouraki, E, Raimondi, M, Chirico, G, Marini, M., Nardini, A., Martínez Vázquez, R., Conci, C., Bouzin, M., Collini, M., Osellame, R., Cerullo, G., Kariman, B. S., Farsari, M., Kabouraki, E., Raimondi, M. T., Chirico, G., Marini, M, Nardini, A, Martínez Vázquez, R, Conci, C, Bouzin, M, Collini, M, Osellame, R, Cerullo, G, Kariman, B, Farsari, M, Kabouraki, E, Raimondi, M, Chirico, G, Marini, M., Nardini, A., Martínez Vázquez, R., Conci, C., Bouzin, M., Collini, M., Osellame, R., Cerullo, G., Kariman, B. S., Farsari, M., Kabouraki, E., Raimondi, M. T., and Chirico, G.

Abstract

Non-linear excitation microscopy offers several advantages for in-vivo imaging compared to conventional confocal techniques. However, tissue penetration can still be an issue due to scattering and spherical aberrations induced on focused beams by the tissue. The use of low numerical aperture objectives to pass through the outer layers of the skin, together with high dioptric power microlenses implanted in-vivo close to the observation volume, can be beneficial to the reduction of optical aberrations. Here, Fibroblast cell culture plano-convex microlenses to be used for non-linear imaging of biological tissue are developed and tested. The microlenses can be used as single lenses or multiplexed in an array. A thorough test of the lenses wavefront is reported together with the modulation transfer function and wavefront profile. Magnified fluorescence images can be retrieved through the microlenses coupled to commercial confocal and two-photon excitation scanning microscopes. The signal-to-noise ratio of the images is not substantially affected by the use of the microlenses and the magnification can be adjusted by changing the relative position of the microlens array to the microscope objective and the immersion medium. These results are opening the way to the application of implanted micro-optics for optical in-vivo inspection of biological processes.

Published

2023

46. Two-photon laser polymerized microlenses for non-linear excitation microscopy of biological samples

Author

Ferraro, P, Psaltis, D, Grilli, S, Nardini, A, Vazquez, R, Marini, M, Conci, C, Bouzin, M, Collini, M, Osellame, R, Cerullo, G, Kariman, B, Farsari, M, Kabouraki, E, Chirico, G, Raimondi, M, Nardini A., Vazquez R. M., Marini M., Conci C., Bouzin M., Collini M., Osellame R., Cerullo G., Kariman B. S., Farsari M., Kabouraki E., Chirico G., Raimondi M. T., Ferraro, P, Psaltis, D, Grilli, S, Nardini, A, Vazquez, R, Marini, M, Conci, C, Bouzin, M, Collini, M, Osellame, R, Cerullo, G, Kariman, B, Farsari, M, Kabouraki, E, Chirico, G, Raimondi, M, Nardini A., Vazquez R. M., Marini M., Conci C., Bouzin M., Collini M., Osellame R., Cerullo G., Kariman B. S., Farsari M., Kabouraki E., Chirico G., and Raimondi M. T.

Abstract

We report new methods of 2 photon polymerization of microlenses with high numerical aperture, large diameter and good optical quality. We characterize the aberrations of these lenses that, coupled to raster scanning optical microscopes, allow two-photon excitation imaging of cells. In-vivo non-linear imaging will be also discussed, opening the possibility to use these micro-lenses in implants for the continuous inspection of biological dynamics in vivo.

Published

2023

47. Ultrafast collinear scattering and carrier multiplication in graphene

Author

Brida, D., Tomadin, A., Manzoni, C., Kim, Y. J., Lombardo, A., Milana, S., Nair, R. R., Novoselov, K. S., Ferrari, A. C., Cerullo, G., and Polini, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Graphene is emerging as a viable alternative to conventional optoelectronic, plasmonic, and nanophotonic materials. The interaction of light with carriers creates an out-of-equilibrium distribution, which relaxes on an ultrafast timescale to a hot Fermi-Dirac distribution, that subsequently cools via phonon emission. Here we combine pump-probe spectroscopy, featuring extreme temporal resolution and broad spectral coverage, with a microscopic theory based on the quantum Boltzmann equation, to investigate electron-electron collisions in graphene during the very early stages of relaxation. We identify the fundamental physical mechanisms controlling the ultrafast dynamics in graphene, in particular the significant role of ultrafast collinear scattering, enabling Auger processes, including charge multiplication, key to improving photovoltage generation and photodetectors., Comment: 11 pages, 5 figures

Published

2012

48. Strain-induced enhancement of the electron energy relaxation in strongly correlated superconductors

Author

Gadermaier, C., Kabanov, V. V., Alexandrov, A. S., Stojchevska, L., Mertelj, T., Manzoni, C., Cerullo, G., Zhigadlo, N. D., Karpinski, J., Cai, Y. Q., Yao, X., Toda, Y., Oda, M., Sugai, S., and Mihailovic, D.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

We use femtosecond optical spectroscopy to systematically measure the primary energy relaxation rate k1 of photoexcited carriers in cuprate and pnictide superconductors. We find that k1 increases monotonically with increased negative strain in the crystallographic a-axis. Generally, the Bardeen-Shockley deformation potential theorem and, specifically, pressure-induced Raman shifts reported in the literature suggest that increased negative strain enhances electron-phonon coupling, which implies that the observed direct correspondence between a and k1 is consistent with the canonical assignment of k1 to the electron-phonon interaction. The well-known non-monotonic dependence of the superconducting critical temperature Tc on the a-axis strain is also reflected in a systematic dependence Tc on k1, with a distinct maximum at intermediate values (~16 ps-1 at room temperature). The empirical non-monotonic systematic variation of Tc with the strength of the electron-phonon interaction provides us with unique insight into the role of electron-phonon interaction in relation to the mechanism of high-Tc superconductivity as a crossover phenomenon., Comment: manuscript as accepted in PRX, main paper (20 pages, 3 figures) plus supplementary material (25 pages, 19 figures)

Published

2012

49. Dynamics of four-photon photoluminescence in gold nanoantennas

Author

Biagioni, P., Brida, D., Huang, J. -S., Kern, J., Duò, L., Hecht, B., Finazzi, M., and Cerullo, G.

Subjects

Physics - Optics

Abstract

Two-pulse correlation is employed to investigate the temporal dynamics of both two-photon photoluminescence (2PPL) and four-photon photoluminescence (4PPL) in resonant and nonresonant nanoantennas excited at a wavelength of 800 nm. Our data are consistent with the same two-step model being the cause of both 4PPL and 2PPL, implying that the first excitation step in 4PPL is a three-photon sp->sp direct interband transition. Considering energy and parity conservation, we also explain why 4PPL behavior is favored over three-and five-photon photoluminescence in the power range below the damage threshold of our antennas. Since sizeable 4PPL requires larger peak intensities of the local field, we are able to select either 2PPL or 4PPL in the same gold nanoantennas by choosing a suitable laser pulse duration. We thus provide a first consistent model for the understanding of multiphoton photoluminescence generation in gold nanoantennas, opening new perspectives for applications ranging from the characterization of plasmonic resonances to biomedical imaging.

Published

2011

50. Quantum interference between charge excitation paths in a solid state Mott insulator

Author

Wall, S., Brida, D., Clark, S. R., Ehrke, H. P., Jaksch, D., Ardavan, A., Bonora, S., Uemura, H., Takahashi, Y., Hasegawa, T., Okamoto, H., Cerullo, G., and Cavalleri, A.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The competition between electron localization and de-localization in Mott insulators underpins the physics of strongly-correlated electron systems. Photo-excitation, which re-distributes charge between sites, can control this many-body process on the ultrafast timescale. To date, time-resolved studies have been performed in solids in which other degrees of freedom, such as lattice, spin, or orbital excitations come into play. However, the underlying quantum dynamics of bare electronic excitations has remained out of reach. Quantum many-body dynamics have only been detected in the controlled environment of optical lattices where the dynamics are slower and lattice excitations are absent. By using nearly-single-cycle near-IR pulses, we have measured coherent electronic excitations in the organic salt ET-F2TCNQ, a prototypical one-dimensional Mott Insulator. After photo-excitation, a new resonance appears on the low-energy side of the Mott gap, which oscillates at 25 THz. Time-dependent simulations of the Mott-Hubbard Hamiltonian reproduce the oscillations, showing that electronic delocalization occurs through quantum interference between bound and ionized holon-doublon pairs., Comment: 4 figures and supplementary information

Published

2009